Lenel OnGuard Hardware Installation Manual

Table of Contents

Quick Links

Download this manual

7.3

Hardware Installation Guide

Table of Contents

Summary of Contents for Lenel OnGuard

Page 1 Hardware Installation Guide...
Page 2 This warranty is limited to the repair or replacement of the defective unit. In no event shall Lenel be liable for loss of use or consequential damages of any kind, however occasioned. There are no expressed warranties other than those set forth herein. Warranty expressly excludes third party additions, deletions and/or upgrades to this product, including those contained herein.
Page 3: Table Of Contents
Hardware Installation Guide Table of Contents Hardware Installation Guidelines ........17 1. Inputs, Outputs and Interface Signals ..........19 1.1 Power Inputs ....................... 19 1.2 Alarm Inputs ....................... 20 1.3 Reader Inputs/Outputs ..................20 1.4 Relay Outputs ..................... 20 1.5 RS-485 Communication Overview ..............20 1.6 RS-232 Interfaces ....................
Page 4 Table of Contents 8.1 Interfaces ......................61 8.2 The Intelligent System Controller Board ............. 61 9. Installation .................... 63 9.1 Wiring ......................... 63 10. Configuration ..................69 10.1 Setting DIP Switches ..................69 10.2 Installing Jumpers ..................... 71 11. Maintenance ..................72 11.1 Verification ......................
Page 5 Hardware Installation Guide 20.2 Installing Jumpers ................... 107 21. Maintenance ..................111 21.1 Verification ...................... 111 21.2 Replace Memory Backup Battery ..............111 22. Specifications ................... 112 LNL-2210 Intelligent Single Door Controller ..... 113 23. Overview of the LNL-2210 ............... 115 23.1 The LNL-2210 Board ..................
Page 6 Table of Contents 29.7 Configuration ....................159 29.8 Initial IP Addressing Mode ................161 29.9 Embedded Web Server .................. 161 30. Maintenance ..................164 30.1 Verification ...................... 164 30.2 Replace Memory Backup Battery ..............166 31. Specifications ................... 167 LNL-3300 Intelligent System Controller ......169 32.
Page 7 Hardware Installation Guide 37.5 Relay Circuit Wiring ..................195 37.6 Memory Backup Battery ................. 197 37.7 Configuration ....................197 37.8 Initial IP Addressing Mode ................198 37.9 Embedded Web Server .................. 199 38. Maintenance ..................203 38.1 Verification ...................... 203 38.2 Replace Memory Backup Battery ..............
Page 8 Table of Contents 43.2 Elevator Control ....................272 44. Configuration ................... 273 44.1 Setting DIP Switches ..................273 44.2 Installing Jumpers ................... 276 45. Specifications ................... 278 LNL-1100-U Input Control Module ........279 46. Overview of the LNL-1100-U Board ..........281 46.1 Package Contents ..................
Page 9 Hardware Installation Guide 55. Specifications ................... 313 LNL-1200-U Output Control Module ........ 315 56. Overview of the LNL-1200-U Board ..........317 56.1 Package Contents ..................317 57. Installation ..................318 58. Configuration ................... 319 58.1 Setting DIP Switches ..................319 58.2 Installing Jumpers ...................
Page 10 Table of Contents LNL-1300e Single Door IP Interface Module ....353 66. Overview of the LNL-1300e ............. 355 66.1 The LNL-1300e IP Interface Board ..............355 67. Installation ..................357 67.1 Wiring and Setup .................... 357 67.2 Recommended Settings for PoE ..............368 67.3 Install Jumpers ....................
Page 11 Hardware Installation Guide 78.7 External (Cabinet) Tamper ................399 78.8 Power and Communications ................399 78.9 UL Listed Installations ..................400 79. Specifications ................... 401 LNL-1320 Dual Reader Interface Module ......403 80. Overview of the LNL-1320 ............... 405 80.1 Interfaces ......................405 80.2 The Dual Reader Interface Module (Series 2) ..........
Page 12 Table of Contents 89. Specifications ................... 449 LNL-8000 Star Multiplexer ..........451 90. Overview of the LNL-8000 Board ............ 453 90.1 Interfaces ......................453 90.2 The Star Multiplexer Board ................454 91. Installation ..................455 91.1 Wiring ......................455 91.2 Wiring and Termination .................. 457 92.
Page 13 100.2 DIP Switch/Jumper Setting ................482 100.3 Keypad Data and Tamper Monitor Signaling ..........483 100.4 TTL Interface ....................483 100.5 OnGuard Configuration ................485 100.6 Grounding the Reader .................. 485 100.7 Reader Verification ..................485 100.8 Status Indicators ................... 486 100.9 Maintenance ....................
Page 14 Table of Contents Lenel OpenCard Readers ..........535 104. Lenel OpenCard Readers .............. 537 104.1 OpenCard ISO-X Readers ................537 104.2 OpenCard XF1050-K ..................540 104.3 OpenCard XF1500 ..................542 BlueDiamond Mobile Readers ......... 545 105. BlueDiamond Mobile Readers ............547 105.1 Readers ......................
Page 15 115.3 4G Configuration in SecureAdmin ..............609 115.4 4G Reader Interface Connections ..............612 115.5 Wiring 4G Verification Readers ..............613 115.6 4G Reader Configuration in OnGuard ............617 115.7 Enrollment Configuration ................619 115.8 Encoding Configuration ................620 116. Bioscrypt 3G Series Readers ............621 116.1 V-Pass FX and V-StationA ................
Page 16 121.4 DIP Switches ....................683 121.5 Jumpers ......................684 121.6 Command Keypad Configuration ..............684 121.7 Status Display ....................685 121.8 OnGuard Configuration ................685 121.9 Command Programming ................686 121.10 Command Keypad Behavior ............... 687 121.11 Specifications ..................... 689 Index ........................
Page 17: Hardware Installation Guidelines
HARDWARE INSTALLATION GUIDELINES...
Page 19: Inputs, Outputs And Interface Signals
1.1.1 AC Power Some OnGuard hardware products can use an AC power source. The AC power wiring to power supplies consists of the AC LINE (L), AC NEUTRAL (N), and SAFETY GROUND (G). These lines from the AC power source to the power input terminals must not be interchanged.
Page 20: Alarm Inputs
500 feet. Relay Outputs Some Lenel hardware products provide form C relay contact outputs. These are dry contacts that are capable of switching signals as well as higher current loads. However, once they are used to switch current (for example, a door strike), they can not be used reliably to switch small signals (for example, dialer input.)
Page 21 Hardware Installation Guide uses a balanced differential transmitter/receiver to reject common mode noise. The following table is a comparison of interfaces commonly used in access/alarm systems. RS-485 RS-232C Modem 20mA Loop Mode of Differential DC Single-ended DC Differential AC Single-ended Operation: coupled coupled...
Page 22 Hardware Installation Guidelines Cable Cross Reference Table Purpose Cable Gauge Cond. Descrip- Belden Tappan General West type tion number number Cable Penn number number RS-485, Non- Overall 9841 L19827 C0841A D4851 2-wire plenum shield RS-485, Plenum Overall 82841, M19899, n/a, 2-wire shield 89841...
Page 23: Interfaces
This is true for most devices that are used for Host to ISC communications, but any device that has been approved by Lenel will indicate how termination should be configured for proper operation in its documentation. Refer to the specific device diagrams being used in the following sections of this hardware manual.
Page 24: System Wiring And Other Considerations
Hardware Installation Guidelines System Wiring and Other Considerations Proper installation is essential to the safe and reliable operation of the OnGuard system. Improper or incorrect wiring will lead to unreliable operation or damage to system components. When system components are powered by different power sources, great care must be exercised in planning and wiring the system.
Page 25 Hardware Installation Guide When choosing a power supply be sure never max out the current load of the supply. Always use a 25% overage factor when sizing your supply as a safety operation. Always use an isolated, non-switching, regulated power supply. 2.1.4 Power Requirements Table Device...
Page 26 Hardware Installation Guidelines Device Power Required LNL-1100-U Note: For UL installations, refer to section UL Listed Installations page 296 for this device. 12 to 24 VDC ± 10% 12 VDC @ 300 mA nominal 24 VDC @ 150 mA nominal 12 to 24 VDC ±...
Page 27 Hardware Installation Guide Device Power Required LNL-1320-U Note: For UL installations, refer to section UL Listed Installations page 447 for this device. 12 to 24 VDC ± 10% 12 VDC @ 1200 mA (includes reader current) nominal 24 VDC @ 600 mA (includes reader current) nominal LNL-2005W 12 VDC (10.2 to 13.8 VDC), 50 mA LNL-2010W...
Page 28 6121 10-16 VDC, 100-350 mA @ 12 VDC 6131 10-16 VDC, 72-244 mA @ 12 VDC 6125A 5-12 VDC, 70-120 mA @ 12 VDC Lenel OpenCard LNL-XF1100D 6-16 VDC, 95-254 mA LNL-XF2100D 8-16 VDC, 95-218 mA LNL-XF2110D 8-16 VDC, 120-215 mA Typical door strike power is estimated at 24 VDC, 300 mA, consult manufacturer specifications for actual values.
Page 29: Mounting
(UL approved). LNL-CTX-6 Hardware enclosure (18 x 24 x 4.5 inches [457.2 x 609.6 x 114.3 mm]) with lock and tamper switch support up to six Lenel access hardware modules (UL approved). ABT-12 Battery Kit, 12 VDC, 12AH Battery (PS-12120).
Page 30 Hardware Installation Guidelines LNL-CTX 12.5" 12.5" Power Supply Hardware Hardware Standoffs Standoffs Optional Battery 1.25" 0.875" 5.50" 5.50" LNL-CTX-6 18.0000 0.9375 8.2500 3.5625 3.7500 0.1869 0.1869 0.1869 0.3750 0.3750 0.3750 1.0000 3.7500 5.5000 5.5000 6.5000 6.5000 2.0000 2.0000 Power Supply Cabinet Lock 24.0000 1.5000...
Page 31 Hardware Installation Guide For smaller modules, only four of the mounting holes are used, the last two holes need support standoffs which come installed from the factory. The exception is the single reader interface module — up to eight (8) units can be mounted in any standard 2-gang or 3-gang junction enclosure.
Page 32 Hardware Installation Guidelines LNL-CTX knockout location drawing 6.0" 1.0" 1/2" and 3/4 knockout location drawing 1.0" 1.5" 2.2.1 LNL-AL400ULX Installation The LNL-AL400ULX should be installed in accordance with article 760 of the National Electrical Code and NFPA70 as well as all applicable local codes. Mount the enclosure in desired location.
Page 33 Hardware Installation Guide Connect unswitched AC power (120 VAC/60 Hz) to terminals marked L, G, N, dedicated to the Burglar Alarm/Access Control Subsystem. Input 120 VAC, 60 Hz, 1.45 amp. DC Output, Battery & AC Supervision Circuit (power limited) + INPUT --- + OUT2--- + OUT1--- To Battery in CTX...
Page 34 Hardware Installation Guidelines Wire routing note: UL two panel installation instructions for LNL-CTX enclosures To install multiple Lenel hardware panels into a single enclosure, the following guidelines must be used for certified UL installations. • All wire connections that cross over the hinge side of the door must be wire wrapped or tie wrapped together.
Page 35 Connect cabinet tamper switch to cabinet tamper circuit on the Lenel access hardware. Wire routing note: UL six panel installation instructions for LNL-CTX enclosures To install multiple Lenel hardware panels into a single enclosure, the following guidelines must be used for certified UL installations.
Page 36: Ground Wiring
Hardware Installation Guidelines 2.2.4 Cabinet Tamper Cabinet tamper for all enclosures must be connected and programmed for UL installations. Ground Wiring Each hardware product must be grounded to provide ESD protection, personnel safety, and signal reference for devices which communicate with each other. Grounding provides a good shield against external transients.
Page 37: Alarm Input Wiring
Hardware Installation Guide Alarm Input Wiring All alarm inputs require twisted pair wires. An end-of-line (EOL) resistor terminator is required for each supervised alarm input. Both supervised and unsupervised alarm inputs can support single or multiple contacts per loop. Connect normally closed (NC) contacts in series and normally open (NO) contacts in parallel.
Page 38 Hardware Installation Guidelines DEPENDENT devices and the receive lines of the MASTER device are connected to the transmit lines of the DEPENDENT devices. Observe the + and the - of each pair (NOTE: only applies to 4-wire RS-485 wiring). Refer to the following diagrams for RS-485 Signal Ground and Termination. RS-485 Multi-drop Wiring and EOL Termination RS-485 Multi-drop Wiring and EOL Termination T+ T- SG...
Page 39 Hardware Installation Guide RS-485 Multi-drop Wiring and EOL Termination: ISC and LNL-500B RS-485 Multi-drop Wiring and EOL Termination ISC and Biometric Gateway Mid RS-485 = On Board Termination T+ T- SG = Indicates RS-485 in and out or less than 10 foot drop Shield Earth Ground, one point only per ISC...
Page 40: Rs-232 Communication Wiring
Hardware Installation Guidelines Multiple Power Supplies on a Single ISC Multiple Power Supplies on Single ISC 110 VAC Source 12 VDC Line - Black Power Supply Neutral - White DC+ DC- DC+ DC- Ground - Green Earth Ground Must connect DC- when using multiple power supplies on a...
Page 41: Relay Contact Protection
MATERIAL: STAINLESS STEEL, TYPE 304-2B, 18GA NOTES: UNLESS OTHERWISE SPECIFIED Relay Contact Protection The relays used by OnGuard hardware products have a contact life in excess of 500,000 operations at full rating. Lighter loads, and appropriate contact protection, extend relay life. revision 7 —...
Page 42 Hardware Installation Guidelines 2.8.1 DC Inductive Load Contacts for DC inductive loads can be effectively protected using clamp diodes. Select diodes with reverse breakdown voltage 10 times the circuit voltage. 2.8.2 AC Inductive Loads Contacts for AC inductive loads can be protected using metal-oxide varistors (MOVs.) MOVs are effective when the load voltage is 100V to 200V.
Page 43: System Turn-Up Considerations
Hardware Installation Guide System Turn-Up Considerations A system should never be wired up and powered up all at once. For successful system turn-up, the following step-by-step procedures should be performed. Make sure that no power is applied to any system device. Check all wiring and device switch settings.
Page 44: Ground Potential Difference Checks Before Connecting
Hardware Installation Guidelines Ground Potential Difference Checks Before Connecting Before a device can be connected to the RS-485 communication line, it must be checked for ground fault. Uncorrected ground fault can damage all devices connected to the RS-485 communication line. To check if there is ground fault for a new unit, follow the steps below.
Page 45: Maintenance
To use wireless readers, the LNL-500W requires firmware version 1.10. The most current version of the firmware is shipped with your OnGuard software and was installed during the initial software installation. Each subsequent software release you receive will also include the most current version of the firmware.
Page 46: Firmware Updates
Select the Download Firmware choice from the popup menu OnGuard will initiate the firmware update then perform a full download to the access panel and to all devices connected to it. You must update each access panel in the system. Although it is not necessary to shutdown the application to perform the updates, note that the selected access panel is placed in a degraded off-line mode during the process.
Page 47: Ul/Ulc Certified Installations
Equipment must be installed in a temperature controlled environment, maintained between 13 - 35°C (55 - 95°F) by the HVAC system. 24 hours of standby must be provided for the HVAC system. HVAC rated modules were not evaluated by UL for Lenel OnGuard UL1076 product Listing. revision 7 —...
Page 48 All OnGuard system solutions that are to be UL1076 compliant systems must also meet the requirements specified in Section 25A of the UL1076 (Proprietary Burglar Alarm Units and Systems Standard for Safety).
Page 49: Power
Alarm = 6.0 amps Typical Combinations for UL Installations The following combinations must be used in a UL type installation with OnGuard software versions 7.0.xxx, 7.1.xxx, 7.2.xxx, or 7.3.xxx which are approved for use. For UL certification, a UL Listed power supply, either LNL-AL400ULX or LNL-AL600ULX-4CB6 with additional hardware mounted in LNL-CTX or LNL-CTX-6 enclosures, must be used.
Page 50 Hardware Installation Guidelines Intelligent System Controller Combinations Any individual board would be supported (LNL-500, LNL-1000, LNL-2000, LNL-3300, LNL-2210, LNL-2220, LNL-4420) as well as any combination of the following boards within a single enclosure. LNL-500, 1000, 2000, 3300, 2210, 2220 or 4420 Intelligent System Controllers LNL-1001-MK or LNL-1003-MK or LNL-1007MK (2000 only) Memory Expansion Modules LNL-1100 Alarm Input Control Module LNL-500, 1000, 2000, 3300, 2210, 2220 or 4420 Intelligent System Controllers...
Page 51 For UL installations, you must have a tamper switch connected from the electrical box cover to LNL-2210 tamper circuit. UL Evaluated Readers and Card Formats The following readers have been evaluated by UL for use with the OnGuard system. revision 7 —...
Page 52 HID Edge devices 82000, 82120, 82125 (evaluated for access control applications only; to be installed within the protected premises). • Lenel OpenCard XF1050D, XF1500, XF2100D, XF2110D • LNL-CK (UL1076 - suitable for remote arming). This device is compatible with the LNL-2220/ LNL-3300 controllers only.
Page 53: Ul/Ulc Requirements
Hardware Installation Guide From the Access Control menu, select Local I/O. On the Local I/O Function Lists form, create a Local I/O function for the Alarm Mask Group Mask/ Unmask group created in step 4. From the Access Control menu, select Groups. On the Mask Groups form, create an Intrusion Mask group for the desired alarm points.
Page 54: Can/Ulc-S319-05 Requirements
ILS locks CAN/ULC-S319-05 Requirements • Only OnGuard 7.0 (7.0.xxx), OnGuard 7.1 (7.1.xxx), OnGuard 7.2 (7.2.xxx), and OnGuard 7.3 (7.3.xxx) Monitoring Software was evaluated for use. • Portal locking devices must be ULC or cUL Listed, and be constructed so that they do not interfere with egress, with their locking action capable of being released when emergency egress is required.
Page 55: En Certified Readers
Hardware Installation Guide EN Certified Readers The following readers are EN Security Grade 3 approved (Environmental Class III, EN50131-1, -3, EN50133-1) for use with the OnGuard system: • AWID Sentinel Prox KP-6840GRMP • Barantec Keypad LNL-826S121NN • Guardall G-Prox II 111-8267P •...
Page 56: Troubleshooting
Hardware Installation Guidelines Troubleshooting System Problem: Possible Causes: Software Connection Error in Alarm TCP/IP Connection Errors – TCP/IP must be configured on Monitoring all workstations running Alarm Monitoring. Use a static IP address, not DHCP. The Access Control Driver may not be running, or was started improperly.
Page 57 Hardware Installation Guide System Problem: Possible Causes: Entry denied on valid badges Panel memory in the software configuration must match the physical memory on the board. If unsure of panel memory, use “display panel capacity” in the Alarm Monitoring options menu to verify proper configuration.
Page 58 Hardware Installation Guidelines 58 — revision 7...
Page 59: Intelligent System Controller
LNL-500 INTELLIGENT SYSTEM CONTROLLER...
Page 61: Overview Of The Lnl-500
Hardware Installation Guide Overview of the LNL-500 This installation guide is intended for use by technicians who will be installing and maintaining the Intelligent System Controller (LNL-500). The ISC provides real time processing for the I/O interfaces to which it is connected. It holds the database for the subsystem configuration and cardholders, the event log buffer in battery-backed memory.
Page 62 LNL-500 Intelligent System Controller (1) power-in input, eight (8) DIP switches, and eleven (11) jumpers. It also contains a set of three (3) status LEDs and one (1) memory backup (3 volt lithium) battery. LNL-500 Board FOR ETHERNET APPLICATION: LANTRONIX COBOX MICRO RICHCO PLASTICS STANDOFF TR1+ .50 (12.7)
Page 63: Installation
Hardware Installation Guide Installation To install the ISC, perform the installation procedures described in the following sections, in the order in which they are presented. Wire the unsupervised alarm inputs for power fault and cabinet tamper monitoring. Wire the upstream host communication. Wire the downstream device communication.
Page 64 LNL-500 Intelligent System Controller Direct-connect RS-232 cables should be no longer than 50 feet. Leased lines or fiber optics can also be used. For RS-485 communication, the following type of RS-485 cable is required: 24 AWG (minimum) twisted pair (with shields). Either 2-wire or 4-wire RS-485 cable configuration can be used. The RS-485 cable should be no longer than 4000 feet (1219 m), 120 ohms maximum (Belden 9842 4-wire or 9841 2-wire, plenum cabling Belden 88102, West Penn, or equivalent.) The drop cables (to readers and other devices) should be kept as short as possible, no longer than 10 feet.
Page 65 Hardware Installation Guide Belden Wire Specifications Trade Number Number Nominal Shield Nominal Nominal Capacitance UL NEC Type of Pairs D.C. R. Impedance pF/feet pF/meter Conductor (Ohms) Certification 88102 24.0 ohms/M 15.5 ohms/M 12.95 NEC CMP CSA 78.7 ohms/ 50.9 ohms/km Notes: If RS-485 communication is used, an RS-232 to RS-485 converter is required at the host workstation.
Page 66 LNL-500 Intelligent System Controller Note: To connect the ISC to Rocket Port via 2-wire RS-485, the toggle RTS low checkbox should be checked in the Rocket Port settings. 2-Wire RS-485 from Host 2-WIRE MULTIDROP RS-485 FROM HOST (Maximum of 8 control panels) TR1+ TR1- R1 +...
Page 67 Hardware Installation Guide Downstream Device Communication Wiring (Ports 2-3) Ports 2 - 3 RS-485 TR2 + TR2 + TR2 - TR2 - TR3 + TR3 + TR3 - TR3 - GND TR- TR+ GND T- Downstream Device Earth Ground 2-WIRE 4-WIRE RS-485 Communication Wiring RS-485 CABLE, 100 Ohm IMPEDANCE...
Page 68 LNL-500 Intelligent System Controller To configure as two 4-wire RS-485 ports, follow the 4-wire diagram: Port 2/3: (Transmit) (Receive) TR2+, TR2- TR3+, TR3- Notes: The ISC can be located anywhere along the RS-485 line. Install an RS-485 terminator for each end-of-line device. 9.1.4 Power The ISC accepts either a 12 VDC or 12 VAC ±...
Page 69: Configuration
Hardware Installation Guide Configuration The ISC board contains 8 DIP switches and 12 jumpers that must be configured appropriately for your system. 10.1 Setting DIP Switches DIP Switches (illustrated: default address of 0, CTS enabled, baud rate = 38400) The following chart describes the use of each DIP switch. DIP SWITCH(ES) USED TO CONFIGURE: 1, 2, 3, 4...
Page 70 LNL-500 Intelligent System Controller 10.1.2 Communication Handshake Status To configure the communication handshake status, set DIP switch 5 according to the following table. Leave this feature set to ON for Lantronix, dial-up, and RS-232, and OFF for RS-485 communication. HANDSHAKE DIP SWITCH STATUS Transmit enabled by CTS...
Page 71: Installing Jumpers
This is true for most devices that are used for Host to ISC communications, but any device that has been approved by Lenel will indicate how termination should be configured for proper operation in its documentation. 10.2.2 RS-485 Cable Termination from ISC to Downstream Modules Termination of this section of the RS-485 bus always remains the same.
Page 72: Maintenance
LNL-500 Intelligent System Controller Maintenance Refer to Firmware Updates in the Hardware Installation Guidelines section for instructions for downloading firmware. 11.1 Verification The ISC board contains three Status LEDs (LED A, LED B, LED C) that can be used to verify correct installation after power up.
Page 73: Specifications
Hardware Installation Guide Specifications The LNL-500 is for use in low voltage, class 2 circuits only. • Primary Power: (DC or AC) DC input: 12 VDC ± 10%. 250 mA AC input: 12 VAC ± 15%. 400 mA RMS • Memory and Clock Backup: 3 V lithium, type BR2325 •...
Page 74 LNL-500 Intelligent System Controller 74 — revision 7...
Page 75: Lnl-1000 Intelligent System Controller
LNL-1000 INTELLIGENT SYSTEM CONTROLLER...
Page 77: Overview Of The Lnl-1000
Hardware Installation Guide Overview of the LNL-1000 This installation guide is intended for use by technicians who will be installing and maintaining the Intelligent System Controller. The Intelligent System Controller (ISC) serves as the predominant access control engine. The ISC provides power, performance, and flexibility for the most demanding applications.
Page 78: The Isc Board
LNL-1000 Intelligent System Controller 13.2 The ISC Board The ISC board contains the following components: two (2) unsupervised alarm inputs, one (1) RS-232 or RS-485 interface, four (4) RS-485 interfaces (which can consist of four 2-wire, two 4-wire, or one 4-wire and two 2-wire interfaces), one (1) power-in input, eight (8) DIP switches, and sixteen (16) jumpers.
Page 79: Installation
Hardware Installation Guide Installation To install the ISC, perform the installation procedures described in the following sections, in the order in which they are presented. Wire the unsupervised alarm inputs for power fault and cabinet tamper monitoring. Wire the upstream host communication. Wire the downstream device communication.
Page 80 LNL-1000 Intelligent System Controller Direct-connect RS-232 cables should be no longer than 50 feet. Leased lines or fiber optics can also be used. For RS-485 communication, the following type of RS-485 cable is required: 24 AWG (minimum) twisted pair (with shields.) Either 2-wire or 4-wire RS-485 cable configuration can be used. The RS-485 cable should be no longer than 4000 feet (1219 m), 100 ohms maximum (Belden 9842 4-wire or 9841 2-wire, plenum cabling Belden 88102, West Penn, or equivalent.) The drop cables (to readers and other devices) should be kept as short as possible, no longer than 10 feet.
Page 81 Hardware Installation Guide Belden Wire Specifications Trade Number Numbe Nominal Shield Nominal Nominal UL NEC Type r of D.C. R. Impedance Capacitance Pairs Conductor (Ohms) pF/feet Certification meter 88102 24.0 ohms/M 15.5 ohms/M 12.95 NEC CMP CSA 78.7 ohms/ 50.9 ohms/km Notes: If RS-485 communication is used, an RS-232 to RS-485 converter is required at the host workstation.
Page 82 LNL-1000 Intelligent System Controller 9-pin connector 25 – pin connector RXD/TR1- pin 3 pin 2 RTS/R1+ not used not used CTS/R1- pin 7 pin 4 pin 5 pin 7 Jumper together 4, 6 & 8 5,6 & 20 Note: To connect the ISC to Rocket Port via 2-wire RS-485, the toggle RTS low checkbox should be checked in the Rocket Port settings.
Page 83 Hardware Installation Guide 14.1.3 Downstream Device Communication The ISC can be configured to communicate downstream with up to 16 input/output devices, using Port 2, Port 3, Port 4, and Port 5. Each of these ports can be wired only as an RS-485 interface, for multi-drop communication on a single bus of up to 4000 feet.
Page 84 LNL-1000 Intelligent System Controller RS-485 Communication Wiring RS-485 CABLE, 100 Ohm IMPEDANCE BELDEN 9842 OR EQUIVALENT TO PREVIOUS UNIT TO NEXT UNIT OR TERMINATOR OR TERMINATOR KEEP DOWN LEAD SHORT (10 FEET MAX.) Reader Interface Module To configure all four downstream ISC ports as 2-wire RS-485, follow the 2-wire diagram and repeat on each set of three terminators, TRX+, TRX-, GND.
Page 85 Hardware Installation Guide 14.1.4 Power The ISC accepts either a 12 VDC or 12 VAC ± 15% power source for its power input. The power source should be located as close to the ISC as possible. Wire the power input with 18 AWG (minimum) twisted pair cable. For AC power sources, the following lines are required: AC Line (L), AC Neutral (N).
Page 86: Configuration
LNL-1000 Intelligent System Controller Configuration The ISC board contains 8 DIP switches and 16 jumpers that must be configured appropriately for your system. 15.1 Setting DIP Switches DIP Switches (illustrated: default address of 0, CTS enabled, baud rate = 38400) The following chart describes the use of each DIP switch.
Page 87 Hardware Installation Guide 15.1.2 Communication Handshake Status To configure the communication handshake status, set DIP switch 5 according to the following table. Leave this feature set to ON for Lantronix, dial-up, and RS-232, and OFF for RS-485 communication. HANDSHAKE DIP SWITCH STATUS Transmit enabled by CTS (default)
Page 88: Installing Jumpers
LNL-1000 Intelligent System Controller 15.2 Installing Jumpers The following diagram describes the use of each jumper on the ISC board. The jumper is indicated by brackets [ ]. The default shipping position is shown below. [J9] Control for Port 1, RS-232 or RS-485 [J14] Control for Port 1, 2-wire or 4-wire [J7, J8]...
Page 89 Hardware Installation Guide 15.2.1 Memory Expansion Board (OPTIONAL) The Memory Expansion card for the ISC processor allows for additional memory to be added when the database requirement exceeds the capacity of the base memory on the ISC processor. The Memory card accommodates 3 banks of low power static RAMs for up to a total of 3 MB.
Page 90 This is true for most devices that are used for Host to ISC communications, but any device that has been approved by Lenel will indicate how termination should be configured for proper operation in its documentation. 15.2.3 RS-485 Cable Termination from ISC to Downstream Modules Termination of this section of the RS-485 bus always remains the same.
Page 91: Maintenance
Hardware Installation Guide Maintenance Refer to Firmware Updates in the Hardware Installation Guidelines section for instructions for downloading firmware. 16.1 Verification The ISC board contains three Status LEDs (LED A, LED B, LED C) that can be used to verify correct installation after power up.
Page 92: Specifications
LNL-1000 Intelligent System Controller Specifications The ISC is for use in low voltage, class 2 circuits only. • Primary Power: (DC or AC) DC input: 12 VDC ± 15%. 350mA AC input: 12 VAC ± 15%. 600mA RMS • Memory and Clock Backup: 3 V lithium, type BR2325 •...
Page 93: Lnl-2000 Intelligent System Controller
LNL-2000 INTELLIGENT SYSTEM CONTROLLER...
Page 95: Overview Of The Lnl-2000
18.1 Interfaces The ISC interfaces upstream with the Access Control software on a host system and downstream with the following Lenel field hardware components. LNL-2000 Communications Overview Dual Path Access...
Page 96: The Lnl-2000 Board
LNL-2000 Intelligent System Controller 18.2 The LNL-2000 Board The ISC board contains the following components: two (2) unsupervised alarm inputs, two (2) RS-232 or RS-485 interface, four (4) RS-485 interfaces (which can consist of four 2-wire, two 4-wire, or one 4-wire and two 2-wire interfaces), one (1) power-in input, eight (8) DIP switches, and twenty-three (23) jumpers.
Page 97: Installation
Hardware Installation Guide Installation To install the ISC, perform the installation procedures described in the following sections, in the order in which they are presented. Wire the unsupervised alarm inputs for power fault and cabinet tamper monitoring. Wire the upstream host communication. Wire the downstream device communication.
Page 98 LNL-2000 Intelligent System Controller Port 6 may be set up as RS-232 interface or a RS-485 interface. RS-485 interface may be 2-wire or 4-wire type. Direct-connect RS-232 cables should be no longer than 50 feet. Leased lines or fiber optics can also be used. RS-232 Communications The RS-232 communications interface is for short distance wiring or point to point communications.
Page 99 Hardware Installation Guide Each component provided has an on-board termination. It is up to the installer to determine which device is at the end of the communication line. Belden Wire Specifications Trade Number Numbe Nominal Shield Nominal Nominal UL NEC Type r of D.C.
Page 100 Ports 1 and 6-wiring configuration. This configuration will work for Direct connect (RS-232) and Lantronix Ethernet network communications. With direct connect and with Lantronix, DIP Switch 5 needs to be ON using connection cables provided by Lenel. 9-pin connector 25-pin connector...
Page 101 Hardware Installation Guide Panel 1 Panel 2 Jumper Setting Jumper Setting ON 485 pins 1 & 2 ON 485 pins 1 & 2 J9, J11 Termination ON J9, J11 Termination ON 19.1.3 Downstream Device Communication The ISC can be configured to communicate downstream with up to 16 input/output devices, using Port 2, Port 3, Port 4, and Port 5.
Page 102 LNL-2000 Intelligent System Controller RS-485 Communication Wiring RS-485 CABLE, 100 Ohm IMPEDANCE BELDEN 9842 OR EQUIVALENT TO PREVIOUS UNIT TO NEXT UNIT OR TERMINATOR OR TERMINATOR KEEP DOWN LEAD SHORT (10 FEET MAX.) Reader Interface Module To configure all four downstream ISC ports as 2-wire RS-485, follow the 2-wire diagram and repeat on each set of three terminators, TRX+, TRX-, GND.
Page 103 Hardware Installation Guide Notes: The ISC can be located anywhere along the RS-485 line. Install an RS-485 terminator for each end-of-line device. 19.1.4 Power The ISC accepts either 12 VDC or 12 VAC. • Locate power source as closed to the unit as possible. •...
Page 104: Configuration
LNL-2000 Intelligent System Controller Configuration The ISC board contains 8 DIP switches and 23 jumpers that must be configured appropriately for your system. 20.1 Setting DIP Switches DIP Switches (default) The following chart describes the use of each DIP Switch DIP SWITCH(ES) USED TO CONFIGURE: 1, 2, 3...
Page 105 The 115,200 baud rate is supported for use with a Lantronix device. If using a direct connection to the host workstation, refer to the OnGuard 7.3 Release Notes for supported operating systems. In order to communicate with an ISC at 115,200 bps, an extra wire is required in the RS-232 cable, connected to RTS/R1+.
Page 106 LNL-2000 Intelligent System Controller For a 25- pin cable, • Jumper pins 6 and 20 together. • Connect pin 5 to RTS/R1+ on the LNL-2000. 20.1.4 Communication Password Status DIP switch 8 controls the utilization of encryption. The ISC supports encryption with use of AES firmware. The controller must have a 256 KB chip. If you wish to use this feature and have a controller with a 128 KB chip, it must be upgraded.
Page 107: Installing Jumpers
Hardware Installation Guide 20.2 Installing Jumpers The following diagram describes the use of each jumper on the ISC board. The jumper is indicated by brackets [ ]. The default shipping position is shown. [J5] Control for Port 1, RS-232/Lantronix MSS-LITE or RS-485 [J8] Control for Port 1, 2-wire or 4-wire [J4, J6, J7, J10]...
Page 108 LNL-2000 Intelligent System Controller 20.2.1 RAM Chip Size The LNL-2000 comes with permanently mounted 1 MB RAM installed. 20.2.2 Memory Expansion Board (Optional) The Memory Expansion card allows for additional memory to be added when the database requirement exceeds the capacity of the base memory on the ISC. The Memory card accommodates 3 banks of low power static RAMs for up to a total of 3 Megabytes.
Page 109 This is true for most devices that are used for Host to ISC communications, but any device that has been approved by Lenel will indicate how termination should be configured for proper operation in its documentation. 20.2.4 RS-485 Cable Termination from ISC to Downstream Modules Termination of this section of the RS-485 bus always remains the same.
Page 110 LNL-2000 Intelligent System Controller Typical Downstream Communication Configuration (note where EOL terminators are required) 32 Downstream Intelligent System Controller Downstream Communications Devices  Four 2-wire ports Total  Two 4-wire ports RS-485  Combination 2 and 4 wire ports Multi-drop 2 or 4 wire Single Reader Dual Reader...
Page 111: Maintenance
Hardware Installation Guide Maintenance Refer to Firmware Updates in the Hardware Installation Guidelines section for instructions for downloading firmware. 21.1 Verification The board contains three Status LEDs (LED A, LED B, LED C) that can be used to verify correct installation and power up.
Page 112: Specifications
LNL-2000 Intelligent System Controller Specifications **The LNL-2000 is for use in low voltage, class 2 circuits only. • Primary Power: (DC or AC) DC input: 12 VDC + 10%, 400 mA (550 mA with NIC) recommended AC input: 12 VAC + 15%, 650 mA RMS (800 mA RMS with NIC) •...
Page 113: Lnl-2210 Intelligent Single Door Controller
LNL-2210 INTELLIGENT SINGLE DOOR CONTROLLER...
Page 115: Overview Of The Lnl-2210
This can be accomplished by bringing the panel online with the OnGuard Communication Server. Alternatively, either keep the board powered up when transferring it to or from the communication bus lines or use a different controller such as the LNL-2220 that does have a real-time clock.
Page 116 LNL-2210 Intelligent Single Door Controller The LNL-2210 Board PoE/12VDC POWER SELECTOR JUMPER (J3) 5.40 [137.16] 2.55 [64.77] 2.55 [64.77] .15 [3.81] .20 [5.08] TAMPER SWITCH CONNECTION (J7) .20 [5.08] DIP SWITCHES STATUS LEDs ETHERNET RESET SWITCH CONNECTOR (J6) RELAY K2 LED RELAY K1 LED SOLDER SIDE 116 —...
Page 117: Default Login Security Enhancements
Overview With firmware version 1.194 or later, security enhancements were made regarding the default login account. These enhancements restrict the conditions in which the default login account is enabled, exposing the Lenel controllers to unauthorized access. Since the credentials (user name and password) for default login account are well-known and are the same on all of the controllers, it is important to reduce the possibility that the default login account is left enabled on controllers at customer sites.
Page 118 LNL-2210 Intelligent Single Door Controller • When attempting to log out or apply settings to the controller, two checks are now made: If the DIP switches are set to the normal operating mode If at least one user-defined account has been created If either check fails, an appropriate error message appears.
Page 119 Hardware Installation Guide Login Failed: Login Time Window Expired The No User-defined Accounts screen appears when you successfully log into the controller, but no user- defined accounts are detected. No User-defined Accounts revision 7 —...
Page 120 LNL-2210 Intelligent Single Door Controller When logging out, if either logout check (DIP switch settings or user-defined account) fails, the Configuration Manager screen appears. Configuration Manager If either, or both, condition exists, you must acknowledge the appropriate warning by checking the box next to I understand and wish to proceed before the Yes button under Do you wish to proceed? is enabled.
Page 121: Installation
Hardware Installation Guide Installation To install the intelligent single door controller, perform the installation procedures described in the following sections, in the order in which they are presented. Wire the device for communication. Wire readers. Wire the input circuit. Wire the relay circuit. Supply power to the controller.
Page 122 Refer to the reader manufacturer specifications for cabling requirements. In the 2-wire LED mode, the Buzzer output is used to drive the second LED. Reader port configuration is set via the OnGuard software. 122 —...
Page 123 Hardware Installation Guide Reader 1 wiring RED (1) BRN (4) ORG (5) CLK/D1 WHT (3) DAT/D0 GRN (2) BLK (6) FIRST READER PORT DATA1/DATA0 OR CLOCK/DATA Reader 2 wiring with optional wiring to reader port 1 VO (12VDC) FIRST READER PORT CLK/D1 DAT/D0 BRN (4)
Page 124 LNL-2210 Intelligent Single Door Controller Important: If the power requirements exceed the power output limit of either reader port, an external power supply should be used. Reader 1 - Downstream devices (RS-485) VO (12 VDC) FIRST READER PORT DOWNSTREAM DEVICE DOWNSTREAM DEVICE FOR EXAMPLE: FOR EXAMPLE:...
Page 125 Hardware Installation Guide Reader 1 - OSDP protocol devices (RS-485) VO (12 VDC) TR + TR – CLK/D1 DAT/D0 Command Keypad Command Keypad (Reader 1) (Reader 2) Address 0 Address 1 9600 baud 9600 baud Terminate only the first and last module on the RS-485 multi-drop communication bus. Each OSDP device must be configured with a unique communication address.
Page 126 LNL-2210 Intelligent Single Door Controller Typical Unsupervised F/2F Reader When the "F/2F Format" Output type is configured in System Administration, then door monitor contact and REX are terminated on the LNL-2210 inputs. See the reader manufacturer documentation for the proper connection terminals.
Page 127 Hardware Installation Guide Unsupervised F/2F Wiring (Reader Port 2) Unsupervised F/2F Wiring (Reader Port 2) Callouts Callout Description Unsupervised F/2F reader TB3 and TB4 on LNL-2210 TB3-1: LED terminal to Reader DO (GREEN LED) connection TB3-3: Reader Data 1 connection TB4-1: +12 VDC connections TB4-2: Ground connection Typical Supervised F/2F Reader Edge Inputs...
Page 128 LNL-2210 Intelligent Single Door Controller Supervised 4-State F/2F Reader Edge Wiring (Reader Port 1) Supervised 4-State F/2F Reader Edge Wiring (Reader Port 1) Callouts Callout Description Supervised F/2F reader TB2 on LNL-2210 TB2-1: +12 VDC connections For Supervised F/2F readers: Install jumper between D1 and LED terminals. TB2-3: Buzzer terminal to Reader DO (GREEN LED) connection TB2-4: Reader Data 1 connection TB2-6: Ground connection...
Page 129 Hardware Installation Guide Supervised F/2F Wiring (Reader Port 2) Supervised F/2F Wiring (Reader Port 2) Callouts Callout Description Supervised F/2F reader TB3 and TB4 on LNL-2210 For Supervised F/2F readers: Install jumper between D1 and LED terminals. TB4-1: +12 VDC connections TB3-2: Buzzer terminal to Reader DO (GREEN LED) connection TB3-3: Reader Data 1 connection TB4-2: Ground connection...
Page 130 LNL-2210 Intelligent Single Door Controller Supervised Board Edge Wiring (Reader Port 1) Supervised Board Edge Wiring (Reader Port 1) Callouts Callout Description Unsupervised F/2F reader TB2 on LNL-2210 TB2-1: +12 VDC connections For Supervised F/2F readers: Install jumper between D1 and LED terminals. TB2-3: Buzzer terminal to Reader DO (GREEN LED) connection TB2-4: Reader Data 1 connection Door TB2-6: Ground connection...
Page 131 Hardware Installation Guide The input circuit wiring configurations shown are supported but may not be typical: Standard Supervised Circuit, 1K,1% Normally Open Contact 1K,1% Standard Supervised Circuit, 1K,1% Normally Closed Contact 1K,1% Unsupervised Circuit, Normally Closed Contact Unsupervised Circuit, Normally Open Contact 24.1.5 Relay Circuit Wiring Two (2) relays are provided for controlling door lock mechanisms or alarm signaling.
Page 132 LNL-2210 Intelligent Single Door Controller 12 VDC POWER SUPPLY DC STRIKE FUSE DIODE • Diode Selection: Diode current rating: 1x strike current. Diode breakdown voltage 4x strike voltage. For 12 VDC or 24 VDC strike, diode 1N4002 (100V/1A) typical. TRANSFORMER AC STRIKE FUSE •...
Page 133: Memory Backup Battery
Hardware Installation Guide • Or power can be supplied by a local UL 294 or UL 603 Listed power supply, or the LNL-AL400ULX or LNL-AL600ULX-4CB6 Power Supply/Charger (12 VDC). Connect power with a minimum of 18 AWG wire at TB4-3 and TB4-4. For UL compliance: •...
Page 134: Setting Dip Switches
LNL-2210 Intelligent Single Door Controller 24.4 Setting Dip Switches The switches on S1 DIP switch configure the operating mode of the processor. DIP switches are read on power-up except where noted. Pressing switch S2 causes the board to reset. Switch Selection: When SW1 is on, use the default login user name and password.
Page 135: Embedded Web Server
Hardware Installation Guide 24.6 Embedded Web Server Instead of using DIP switches or jumpers to define communication and addressing, the LNL-2210 can be configured through the web interface. 24.6.1 Logging in for the First Time There is one pre-defined user always available by turning DIP switch SW1 ON after power up. When logging on for the first time, since no other users are defined yet, the default user name and password are required for configuring this board.
Page 136 LNL-2210 Intelligent Single Door Controller Click [Accept]. To view information, click [Device Info]. You may view the time and product ID, as well as properties that have been configured, such as firmware version, serial number, device name, DIP switches, etc. For users configuration, click [Users].
Page 137: Additional Mounting Information
Hardware Installation Guide Characters " , \, &, = and % are invalid characters and cannot be used for passwords. Specify the Session Timer (5 to 60 minutes). Click [Save]. You may disable the web server by selecting the check box. When this option is selected and SW1 is off, all ports except for the host communication port will be disabled.
Page 138 LNL-2210 Intelligent Single Door Controller Note: The controller mounting plate requires a separate grounding conductor because the plate does not make positive contact with the earth-grounded main enclosure (J-Box). Mounting plate dimensions Ø0.16 [Ø4.0] Ø0.16 [Ø4.0] 3-GANG MGT HOLES 1300 MGT HOLES 2.35 [59.7] 3.30 [83.8] 3.63 [92.1]...
Page 139: Maintenance
Hardware Installation Guide Maintenance Refer to Firmware Updates in the Hardware Installation Guidelines section for instructions for downloading firmware. 25.1 Status LEDs Power-up: All LEDs OFF. Initialization: LEDs 1, 2, 3, 4, 5, 6, and 7 are sequenced during initialization. LEDs 1, 3, and 4 are turned ON for approximately four seconds after the hardware initialization has completed, then the application code is initialized.
Page 140: Ul Listed Installations
LNL-2210 Intelligent Single Door Controller UL Listed Installations For UL installations, the following must be observed: • All field wiring terminals are suitable for single wire only. • RS-485 is “Not Evaluated by UL” and therefore cannot be used in UL installations. •...
Page 141: Specification
Hardware Installation Guide Specification The interface is for use in low voltage, Class 2 circuits only, and it is for use with UL Listed access control or burglar alarm power limited power supplies. The installation of this device must comply with all local fire and electrical codes.
Page 142 LNL-2210 Intelligent Single Door Controller Note: For UL installations, refer to the UL Listed Installations on page 140. • Mechanical: Dimensions: 5.5 x 2.75 x 0.96 in. (140 x 70 x 24 mm) Weight: 3.8 oz. (106.35 g) nominal, board only, 4.7 oz. (133.28 g) with bracket •...
Page 143: Lnl-2220 Intelligent Dual Reader Controller
LNL-2220 INTELLIGENT DUAL READER CONTROLLER...
Page 145: Overview Of The Lnl-2220
Hardware Installation Guide Overview of the LNL-2220 This installation guide is intended for use by technicians who will be installing and maintaining the LNL-2220 Intelligent Dual Reader Controller (IDRC). The IDRC provides a single board solution to control two doors, or a single door in paired mode. It holds the database for the hardware configuration, and card holder database in nonvolatile memory.
Page 146: The Idrc Board
LNL-2220 Intelligent Dual Reader Controller 28.2 The IDRC Board The IDRC board contains the following components: one (1) host Ethernet interface, one (1) RS-485 interface, one (1) power-in input, two (2) unsupervised alarm inputs, eight (8) unsupervised/supervised inputs, two (2) reader interfaces, four (4) output relays, four (4) DIP switches, and eight (8) jumpers. It also contains a set of 22 status LEDs and one (1) memory backup (3 volt lithium) battery.
Page 147: Default Settings
With firmware version 1.194 or later, security enhancements were made regarding the default login account. These enhancements restrict the conditions in which the default login account is enabled, exposing the Lenel controllers to unauthorized access. For more information, refer to Default Login Security Enhancementson page 117.
Page 148: Installation
LNL-2220 Intelligent Dual Reader Controller Installation To install the IDRC, perform the installation procedures described in the following sections, in the order in which they are presented. Wire the device for communication. Wire readers, if applicable. Wire the input circuit. Wire the relay circuit.
Page 149 Hardware Installation Guide Connection Input 1 IN 1 Door 1 door contact Input 2 IN 2 Door 1 REx Input 3 IN 3 Door 1 Aux 1 Input 4 IN 4 Door 1 Aux 2 Input 5 IN 5 Door 2 door contact Input 6 IN 6 Door 2 REx...
Page 150: Communication Wiring
LNL-2220 Intelligent Dual Reader Controller Connection TB11 Out 3 NO: Normally open contact Door 2 strike C: Common NC: Normally closed contact Out 4 NO: Normally open contact Door 2 Aux C: Common NC: Normally closed contact 29.2 Communication Wiring The controller communicates to the host via the onboard 10-BaseT/100Base-TX Ethernet interface (port 0) or RS-232 interface (port 1).
Page 151: Reader Wiring
Hardware Installation Guide 29.3 Reader Wiring Each reader port supports wiegand, magnetic stripe, F/2F, and 2-wire RS-485 electrical interfaces. Voltage at the reader port (VO) is passed-through from the input voltage of the controller (TB1-VIN) and is current limited to 150mA for each reader port. Readers that require different voltage or have high current requirements should be powered separately.
Page 152 LNL-2220 Intelligent Dual Reader Controller Unsupervised F/2F Reader Wiring Unsupervised F/2F Reader Wiring Callouts Callout Description Unsupervised F/2F reader TB8 or TB9 on LNL-2220 TB8-1: Ground connection TB8-3: Reader Data 1 connection TB8-5: LED terminal to Reader DO (GREEN LED) connection TB8-6: +12 VDC connections Typical Supervised F/2F Reader Edge Inputs Inputs for the door position monitor and REX switches are wired directly to the F/2F reader, and can be...
Page 153 Hardware Installation Guide Supervised 4-State F/2F Reader Edge Wiring Supervised 4-State F/2F Reader Edge Wiring Callouts Callout Description Supervised F/2F reader TB8 or TB9 on LNL-2220 TB8-1: Ground connection TB8-3: Reader Data 1 connection TB8-4: Buzzer terminal to Reader DO (GREEN LED connection For Supervised F/2F readers: Install jumper between D1 and LED terminals.
Page 154 LNL-2220 Intelligent Dual Reader Controller Supervised Board Edge Wiring Supervised Board Edge Wiring Callouts Callout Description Unsupervised F/2F reader TB8 or TB9 on LNL-2220 TB8-1: Ground connection TB8-3: Reader Data 1 connection Door TB8-4: Buzzer terminal to Reader DO (GREEN LED) connection For Supervised F/2F readers: Install jumper between D1 and LED terminals.
Page 155 Hardware Installation Guide Wiring for OSDP readers TB8 OR TB9 GROUND (Pin 1) DATA 0 (Pin 2) DAT/D0 DATA 1 (Pin 3) CLK/D1 OSDP VO (Pin 6) READER PORT RS-485 MODE 2-WIRE RS-485 9600 BAUD ADDRESS 0 TYPICAL SOFTWARE SETTINGS Reader Type: IDRC ONBOARD READER1 (OSDP PROTOCOL) Keypad: EIGHT-BIT OUTPUT KEYPAD LED Mode: OSDP Reader or OSDP LCD Reader...
Page 156: Input Circuit Wiring
LNL-2220 Intelligent Dual Reader Controller 29.3.4 Bioscrypt Readers The Bioscrypt V-Flex, V-Smart, and V-Station can be connected to the IDRC according to the following diagram. Power Ground (11) Power Power In (8-12VDC 400 mA) (13) Supply IDRC Reader Port Wiegand Ground (1) Wiegand D0 Out (2) DATA/D0 Wiegand D1 Out (3)
Page 157: Relay Circuit Wiring
Hardware Installation Guide A supervised input circuit requires two resistors be added to the circuit to facilitate proper reporting. The standard supervised circuit requires 1K Ohm, 1% resistors and should be located as close to the sensor as possible. Custom EOL resistances may be configured via the host software. Terminal Blocks TB4 Through TB7 Standard Supervised Circuit,...
Page 158 LNL-2220 Intelligent Dual Reader Controller Wire should be of sufficient gauge to avoid voltage loss. – + TB10 or TB11 • Diode Selection: Diode current rating: 1x strike current. Diode breakdown voltage 4x strike voltage. For 12 VDC or 24 VDC strike, diode 1N4002 (100V/1A) typical. TB10 or TB11 •...
Page 159: Memory Backup Battery
Hardware Installation Guide Wiring for power, power fault, and cabinet tampering 12 to 24 VDC (wire power with stranded twisted pair, 18 AWG) CABINET TAMPER POWER FAULT 29.6 Memory Backup Battery Remove the factory-installed plastic safety strip from the memory backup battery. This plastic strip prevents the battery from being effectively seated.
Page 160 LNL-2220 Intelligent Dual Reader Controller Power up the board or press the reset button. While LEDs D1, D2 and D3, D4 light up as alternating pairs (duration of about 10 seconds), drop SW1 to off. While the memory is being cleared, LED D2 blinks quickly or remains on. Do nothing to the board while this is occurring.
Page 161: Initial Ip Addressing Mode
Hardware Installation Guide 29.8 Initial IP Addressing Mode Set the board for the desired initial IP addressing mode. The board can be initially configured using a fixed static IP address or an IP address automatically assigned by a DHCP server. •...
Page 162 LNL-2220 Intelligent Dual Reader Controller The Home page indicates the type of device and has a Notes field. You may type in a description here. Click [Save Notes]. To configure network settings, click [Network]. • If you are using DHCP, specify a host name. By default, the host name consists of “MAC” followed by the numbers of the device MAC address.
Page 163 Hardware Installation Guide Access View allowed Edit allowed Apply Setting page Level 2: No Level 2: No Level 3: No Level 3: No For pages that cannot be viewed, the message is displayed when users attempt to access the page: “This page is unavailable due to one of the following reasons: your user level is not authorized to view this page, or another level 1 user is logged in at this time.”...
Page 164: Maintenance
LNL-2220 Intelligent Dual Reader Controller Maintenance Refer to Firmware Updates in the Hardware Installation Guidelines section for instructions for downloading firmware. 30.1 Verification Power-up: All LEDs OFF. Initialization: LEDs are sequenced during initialization. The following chart describes the purpose of each LED on the IDRC board. Initialization: LED 1 LED 2...
Page 165 Hardware Installation Guide Run time: Description PFL: power fail R1: reader port 1: Clock/Data mode: Flashes when data is received, either input Data 0/Data 1 mode: Flashes when data is received, either input RS-485 mode: Flashes when transmitting data R2: reader port 2 (same behavior as R1 LED) Input status: IN1 Input in inactive state: off (briefly flashes ON every three seconds) Input in active state: ON (briefly flashes off every three seconds)
Page 166: Replace Memory Backup Battery
LNL-2220 Intelligent Dual Reader Controller 30.2 Replace Memory Backup Battery The event log buffer and the real time clock are backed up by a 3V lithium battery. Without power being applied to the LNL-2220, the battery will retain events and transactions for 3 months. This battery should be replaced annually to insure that proper backup functionally is maintained.
Page 167: Specifications
Hardware Installation Guide Specifications The IDRC is for use with UL Listed access control power limited power supplies. • Primary Power: 12 to 24 VDC ±10%, 500mA maximum (plus reader current) 12 VDC @ 250mA (plus reader current) nominal 24 VDC @ 150mA (plus reader current) nominal •...
Page 168 LNL-2220 Intelligent Dual Reader Controller WEEE Note: These specifications are subject to change without notice. 168 — revision 7...
Page 169: Lnl-3300 Intelligent System Controller
LNL-3300 INTELLIGENT SYSTEM CONTROLLER...
Page 171: Overview Of The Lnl-3300
Hardware Installation Guide Overview of the LNL-3300 This installation guide is intended for use by technicians who will be installing and maintaining the Intelligent System Controller. The LNL-3300 provides the real time processing for the I/O interfaces connected to it. The database for the subsystem configuration and card holders are stored in flash memory.
Page 172: Default Settings
LNL-3300 Intelligent System Controller The ISC Board BR/CR2330 32.3 Default Settings Each board ships with the following default configuration. • All DIP switches are off. • IP Addressing: DHCP • DNS Name: “MAC” followed by the 12-character MAC address. • Device address: 0.
Page 173: Default Login Security Enhancements
With firmware version 1.194 or later, security enhancements were made regarding the default login account. These enhancements restrict the conditions in which the default login account is enabled, exposing the Lenel controllers to unauthorized access. For more information, refer to Default Login Security Enhancementson page 117.
Page 174: Installation
LNL-3300 Intelligent System Controller Installation To install the ISC, perform the installation procedures described in the following sections, in the order in which they are presented. Wire the device for communication. Supply power to the controller and wire the unsupervised alarm inputs for power fault and cabinet tamper monitoring.
Page 175: Power And Alarm Inputs
Hardware Installation Guide Wiring ports 2 and 3 TR2+ TR2+ TR2- TR2- TR3+ TR3+ TR3- TR3- Earth Earth PORT 2 PORT 3 Ground Ground 2-WIRE RS-485 2-WIRE RS-485 Wire with 24 AWG, stranded 33.2 Power and Alarm Inputs The LNL-3300 accepts 12 to 24 VDC for power. Locate power source as close to the unit as possible. Connect power with minimum of 18 AWG wires.
Page 176 LNL-3300 Intelligent System Controller Some switch settings behave differently at power up than they do after initialization. Keep this in mind when changing settings. Switch Selection: When SW1 is on, use the default login user name and password. (This can be changed without resetting the board.) User name: admin Password: password...
Page 177: Initial Ip Addressing Mode
Hardware Installation Guide Jumpers Set at Description Factory use only Port 2 RS-485 EOL terminator is off. Port 2 RS-485 terminator is ON. Port 3 RS-485 EOL terminator is off. Port 3 RS-485 terminator is ON. Connector for Lantronix CoBox-micro connection - port 1 J7, J8, J9 Port 1 is RS-232 Port 1 is RS-485...
Page 178: Embedded Web Server
LNL-3300 Intelligent System Controller Note: Ensure that DIP switch 1 is off and DIP switch 2 is ON before rebooting to keep board in default static IP address mode. 33.6 Embedded Web Server Instead of using DIP switches or jumpers to define communication and addressing, the LNL-3300 can be configured through the web interface.
Page 179 Hardware Installation Guide – Connection Type: Choose IP Server, Serial-RS232, or Serial-modem, Serial-RS485 (LNL-3300 only) and Serial-Adapter (LNL-3300 only). Currently the IP Client connection type is not supported. – Data Security: The controller is capable of Password/AES encryption. – Port Number (default 3001) Must match setting in the access control software. When using an IP Server connection, the controller may be configured to allow all IP addresses or only authorized IP addresses.
Page 180 LNL-3300 Intelligent System Controller – High - The minimum password length is eight characters. Three of the password strength criteria must be met. Additionally, strong passwords are checked to make sure that they are not based on the user name. Password strength criteria: –...
Page 181: Maintenance
Hardware Installation Guide Maintenance Refer to Firmware Updates in the Hardware Installation Guidelines section for instructions for downloading firmware. 34.1 Verification The ISC board contains six status LEDs that can be used to verify correct installation after power up. The following chart describes the purpose of each LED on the ISC board. Initialization: LED 1 LED 2...
Page 182: Replace Memory Backup Battery
LNL-3300 Intelligent System Controller Run time: Description Onboard Ethernet speed: off = 10 Mb/S, ON = 100 Mb/S Off = no onboard Ethernet activity, ON = Ethernet activity (yellow LED) Off = no link, ON = good link (green LED) When the controller is reading the database, LEDs 1-4 will simultaneously flash once every two seconds.
Page 183: Specifications
Hardware Installation Guide Specifications ** The ISC is for use with UL Listed access control power limited power supplies. Primary Power: 12 to 24 VDC ±10%, 300 mA maximum • 12 VDC @ 240mA (325mA with CoBox-Micro) nominal 24 VDC @ 135mA (175mA with CoBox-Micro) nominal •...
Page 184 LNL-3300 Intelligent System Controller 184 — revision 7...
Page 185: Lnl-4420 Intelligent Dual Reader Controller
LNL-4420 INTELLIGENT DUAL READER CONTROLLER...
Page 187: Overview Of The Lnl-4420
The Intelligent Dual Reader Controller (IDRC) board provides decision making, event reporting, and database storage for the Lenel hardware platform. An on-board dual reader interface provides control for up to two single reader doors. The controller communicates with OnGuard via the on-board 10-BaseT/ 100Base-TX Ethernet port.
Page 188: The Idrc Board
LNL-4420 Intelligent Dual Reader Controller 36.2 The IDRC Board The IDRC board contains the following components: one (1) host Ethernet interface, one (1) RS-485 interface, one (1) power-in input, two (2) unsupervised alarm inputs, eight (8) unsupervised/supervised inputs, two (2) reader interfaces, four (4) output relays, four (4) DIP switches, and eight (8) jumpers. It also contains a set of 22 status LEDs and one (1) memory backup (3 volt lithium) battery.
Page 189: Default Settings
Hardware Installation Guide 36.3 Default Settings Each board ships with the following default configuration. • All DIP switches are off. • IP Addressing: DHCP • DNS Name: “MAC” followed by the 12-character MAC address. • Device address: 0. This must match the setting in System Administration for successful IP or serial communications •...
Page 190: Installation
LNL-4420 Intelligent Dual Reader Controller Installation To install the IDRC, perform the installation procedures described in the following sections, in the order in which they are presented. Wire the device for communication. Wire readers, if applicable. Wire the input circuit. Wire the relay circuit.
Page 191 Hardware Installation Guide Connection TB10 Out 1 NO: Normally open contact Door 1 strike C: Common NC: Normally closed contact Out 2 NO: Normally open contact Door 1 Aux C: Common NC: Normally closed contact TB11 Out 3 NO: Normally open contact Door 2 strike C: Common NC: Normally closed contact...
Page 192: Communication Wiring
LNL-4420 Intelligent Dual Reader Controller Connection Input 3 Input 4 Input 5 Input 6 Input 7 Input 8 37.2 Communication Wiring The controller communicates to the host via the on-board 10-BaseT/100Base-TX Ethernet interface (port 0). The downstream communication ports (TB2 for port 1 and TB3 for port 2) are a 2-wire RS-485 interfaces which can be used to connect additional I/O panels.
Page 193: Reader Wiring
Hardware Installation Guide Important: Install the termination jumper ONLY on the panel at each end of the RS-485 bus. Failure to do so will compromise the proper operation of the communication channel! 37.3 Reader Wiring Each reader port supports Wiegand, magnetic stripe, and 2-wire RS-485 electrical interfaces. Power to the reader is selectable: 12 VDC (VIN must be greater than 20 VDC), or power is passed-through (PASS) from the input voltage of the LNL-4420 (TB1-VIN), and is current-limited to 150 mA for each reader port.
Page 194: Input Circuit Wiring
LNL-4420 Intelligent Dual Reader Controller Wiring for OSDP readers TB8 OR TB9 GROUND (Pin 1) DATA 0 (Pin 2) DAT/D0 DATA 1 (Pin 3) CLK/D1 OSDP VO (Pin 6) READER PORT RS-485 MODE 2-WIRE RS-485 9600 BAUD ADDRESS 0 TYPICAL SOFTWARE SETTINGS Reader Type: IDRC ONBOARD READER1 (OSDP PROTOCOL) Keypad: EIGHT-BIT OUTPUT KEYPAD LED Mode: OSDP Reader or OSDP LCD Reader...
Page 195: Relay Circuit Wiring
Hardware Installation Guide A supervised input circuit requires two resistors be added to the circuit to facilitate proper reporting. The standard supervised circuit requires 1K Ohm, 1% resistors and should be located as close to the sensor as possible. Custom EOL resistances may be configured via the host software. Terminal Blocks TB4 Through TB7 Standard Supervised Circuit,...
Page 196 LNL-4420 Intelligent Dual Reader Controller • Diode Selection: Diode current rating: 1x strike current. Diode breakdown voltage 4x strike voltage. For 12 VDC or 24 VDC strike, diode 1N4002 (100V/1A) typical. TB10 or TB11 • MOV Selection: Clamp voltage: 1.5x VAC RMS. For 24 VAC strike, Panasonic ERZC07DK470 typical.
Page 197: Memory Backup Battery
When powering up the board with both SW1 and SW2 set to on for 10 seconds, the default communication setting for Lenel's OEM code is DHCP enabled. By default this switch is off and SSL is enabled. Turn SW3 ON to disable SSL settings.
Page 198: Initial Ip Addressing Mode
LNL-4420 Intelligent Dual Reader Controller Once at the login screen, turn off SW2 and turn on SW1 to enable the default login. After power up or board reset, the board will not respond to web communications request for about 15 seconds.
Page 199: Embedded Web Server
With firmware version 1.194 or later, security enhancements were made regarding the default login account. These enhancements restrict the conditions in which the default login account is enabled, exposing the Lenel controllers to unauthorized access. For more information, refer to Default Login Security Enhancements on page 117.
Page 200 LNL-4420 Intelligent Dual Reader Controller Configure the following under Primary Host Port: – Connection Type: Choose IP Server, Serial-RS232, or Serial-modem. Currently, the IP Client connection type is not supported. Serial-RS485 and Serial-Adapter are only available for use with the LNL-3300. –...
Page 201 10. When you have completed configuring the device, click [Apply Settings], [Apply Settings, Reboot], and then [Log Out]. 37.9.3 Auxiliary Authentication Module Web Configuration After you configure the Auxiliary Authentication Module in OnGuard, this configuration requires additional panel configuration on the panel web page. Prerequisites: •...
Page 202 LNL-4420 Intelligent Dual Reader Controller To configure the connection settings to the pivCLASS PACS service, click [pivCLASS-Embedded- Auth]. The pivCLASS Embedded Authentication settings page is displayed. Configure the server address, server port address, and enable encryption communication, if required. For more information, refer to the "FIPS 201 Credentials Folder" in the System Administration User Guide.
Page 203: Maintenance
Hardware Installation Guide Maintenance Refer to Firmware Updates in the Hardware Installation Guidelines section for instructions for downloading firmware. 38.1 Verification Power-up: All LEDs OFF. Initialization: LEDs are sequenced during initialization. Running: After initialization is complete, the LEDs have the following meanings: At power up, LEDs 2-6 are turned ON then OFF in sequence.
Page 204: Replace Memory Backup Battery
LNL-4420 Intelligent Dual Reader Controller Run time Description IN6 input status. See Note. IN7 input status. See Note. IN8 input status. See Note. Relay K1: ON = Energized (Reader 1 Strike) Relay K1: ON = Energized (Reader 1 Aux output 1) Relay K1: ON = Energized (Reader 2 Strike) Relay K1: ON = Energized (Reader 2 Aux output 1) Note:...
Page 205: Ul 294 Installations
Hardware Installation Guide UL 294 Installations For UL294 installations, the LNL-4420 has been evaluated to the following: Model Destructive Line Security Endurance Standby Attack (Encryption) Power LNL-4420 revision 7 —...
Page 206: Specifications
LNL-4420 Intelligent Dual Reader Controller Specifications The LNL-4420 is for use in low voltage, class 2 circuits only. • Primary Power: 12 to 24 VDC ±10%, 500mA maximum (plus reader current) 12 VDC @ 250mA (plus reader current) nominal 24 VDC @ 150mA (plus reader current) nominal •...
Page 207 Hardware Installation Guide WEEE Note: These specifications are subject to change without notice. revision 7 —...
Page 208 LNL-4420 Intelligent Dual Reader Controller 208 — revision 7...
Page 209: Isc Communications
COMMUNICATIONS...
Page 211: Isc Communication
Hardware Installation Guide ISC Communication The following information can be used to configure communication for Lenel controllers unless otherwise stated. 41.1 LAN Connections For LAN panels, any baud rate set on an ISC (primary path port 1 via DIP switches 6 and 7) will work as long as the baud rate on the Lantronix box is set to match (via the “change speed”...
Page 212: Lnl-Ethlan (Mss1/Mss100 Ethernet Controller)
ISC Communications The latest version of EZWebCon can be downloaded from the Lantronix website (www.lantronix.com). For detailed information, refer to the Lantronix documentation. 41.2 LNL-ETHLAN (MSS1/MSS100 Ethernet Controller) This procedure can also be used for the MSS-VIA network adapter. This Ethernet controller is a network device, and not a part of the UL certification. This device must have transient protection.
Page 213 Hardware Installation Guide If it appears that nothing changes after pressing the <Enter> key, it is possible that the Lantronix MSS1 or MSS100 device was already configured once. If this occurs, you need to press the <Enter> key before the phrase, “Load Completed-Boot in Progress” appears. If this still does not allow you to enter into the command mode, you may also telnet into the Lantronix device.
Page 214 ISC Communications 41.2.3 Configuring the ETHLAN Any additional changes specific to the hardware that the Lantronix box is connecting to should be made now. These may include, but are not limited to, baud rate, parity, stop bit, byte size, and flow control. Make sure the device is powered, completely booted, and connected to the network.
Page 215: Lnl-Ethlan-Micr (Micro Serial Server)
Hardware Installation Guide 12. For flow control, type: change flow control [FLOW CONTROL] and press <Enter>, where [FLOW CONTROL] = xonoff, ctsrts, slowcts, or none. 13. Type change dedicated tcp port=3001 and press <Enter>. 14. (Optional) If you are going to connect to the device from across subnets or routers, you will need to program the subnet mask and gateway.
Page 216 BOOTP and RARP are disabled using commands when configuring the device for use. DHCP is disabled when the device is shipped from Lenel. However, if an NVR reset is performed on the device, DHCP, BOOTP, and RARP will all be re-enabled and if there is a DHCP server on the network the unit will obtain an IP address automatically and you will not be able to use the ARP command for programming.
Page 217: Cobox Micro 100
Hardware Installation Guide Richco plastic P/N LMSP-7-01 Standoffs for ETHLAN LITE to ISC INSERT STANDOFFS HERE DO NOT DISPOSE [Qty 3] 41.4 CoBox Micro 100 The CoBox Micro 100 device plugs directly into the LNL-2000 or the LNL-500 ISC. Jumper J13 must be in the OFF position for the device to communicate on the LNL-500 and jumper J26 must be in the OFF position for the device to communicate with the LNL-2000.
Page 218 For more information, refer to the CoBox Micro 100 documentation. Note: Lenel recommends that you increase the security by enabling enhanced passwords. This allows for a maximum of 16 characters in the password. After the Server configuration is complete, choose option 1 for Channel 1 configuration. Make the...
Page 219 Hardware Installation Guide 12. Disconnect Time = 00:00 13. Send Char 1 = 00 14. Send Char 2 = 00 When these changes have been made, type ‘9’ at the main screen to save the changes and exit. The changes will be stored in the CoBox Micro 100 and the connection will be terminated.
Page 220 ISC Communications 220 — revision 7...
Page 221 Hardware Installation Guide 41.4.2 Security Enhancements Past installations may have contained vulnerabilities which could lead to unauthorized access to the CoBox Micro 100. The recommended security settings are not necessary for the unit to work correctly; however, they are highly recommended to bridge any security gaps left open from previous installations. In order to configure the security settings, telnet into the unit to access the setup options: telnet <IP Address>...
Page 222 ISC Communications After the firmware upgrade has been completed, disable port 77FE to prevent unauthorized access to this device. Otherwise, the device should show up in DeviceInstaller. To upgrade the firmware: Select the device. The line will be highlighted. Click [Upgrade]. The Device Upgrade Wizard will appear.
Page 223: Cobox Token Ring Serial Server (Lnl-Cobox-201Tr)
A PC is needed to configure the CoBox Token Ring Serial Server. The machine must have the following installed: • Token Ring Network Interface Card (NIC) • OnGuard Software • HyperTerminal Software To Configure the CoBox Token Ring Serial Server (part # LNL-COBOX-TR201): Step 1: Establish Serial Communication with CoBox With the power OFF to the CoBox device and the network disconnected, establish a serial connection from the CoBox to the PC’s Serial Communication Port, for example, using HyperTerminal.
Page 224 ISC Communications Select Direct Connect and choose the COM port to which the cable is connected on the computer. Change the Communication settings to: 9600 Baud, 8 data bits, 1 stop bit, and No Parity. Once in Terminal mode, hold down the <x> key on the keyboard and plug in power to the CoBox device.
Page 225 Hardware Installation Guide 11. You now need to enter a subnet mask. You CANNOT enter a number here as you are used to, you must use the following table to determine what to type into this field. 255.255.255.252 255.255.252.0 255.252.0.0 255.255.255.248 255.255.248.0 255.248.0.0...
Page 226 ISC Communications You will now be back at the setup screen. Type 2 and then press the <Enter> key to enter the serial port setup menu. For each item, enter the following value. Item Value Baud rate 38400 I/F mode Flow control Port # 03001...
Page 227 Hardware Installation Guide ISC to Lantronix CoBox Token Ring Serial Server Configuration 15V Power Supply CoBox Token Ring Serial Server (COBOX-TR201) TOKEN RING NETWORK CH 2 9-pin female Jumper together 4, 6 & 8 Intelligent System Controller TR1+ TR1- not used TR2+ TR2- TR3+...
Page 228: Lantronix Cobox-Dr
ISC Communications 41.6 Lantronix CoBox-DR The ISC can alternatively be connected to the Lantronix CoBox-DR unit. Use the following information to set up the CoBox-DR unit and the ISC. 41.6.1 DSTni-Xpress DR RS-232 Configuration for the ISC Connection to the ISC can either be through screw terminals or RJ-45 serial port. Pin 3 Pin 4 485 232...
Page 229: Lantronix Securebox Sds1100/1101
Hardware Installation Guide To configure the server and channel 1, refer to the following screen shots. Information is available for hexidecimal values. See Commonly Used Valueson page 241. Server configuration Channel 1 configuration 41.7 Lantronix SecureBox SDS1100/1101 Connect the SDS device with an ISC. revision 7 —...
Page 230 ISC Communications SDS1100 to ISC, 2-wire RS-485 To LAN 9-30VDC 10/100 Ports 1 & 6 Wiring Configuration 25-Pin Connector TXD/TR1+ Pin 14 and 21 RXD/TR1- Pin 15 and 22 RTS/R1+ Not Used Lantronix CTS/R1- Not Used Pin 7 25 -Pin Fem ale Serial Connector ISC: Communications Interface Type = RS-485 RS-485 Type = 2-W ire RS-485...
Page 231 Hardware Installation Guide SDS1100 to ISC, 4-wire RS-485 To LAN 9-30VDC 10/100 Ports 1 & 6 Wiring Configuration 25-Pin Connector TXD/TR1+ Pin 2 RXD/TR1- Pin 3 RTS/R1+ Not Used CTS/R1- Pins 4 & 5 Pin 7 Lantronix Jumper Together 6,8 & 20 25 -Pin Female Serial Connector ISC: Communications Interface Type = RS-232...
Page 232 These instructions also apply for the CoBox-FL, with the exception of encryption. Encryption is not available on the CoBox-FL. Encryption using the Lantronix SDS is supported only for third-party devices, and not Lenel access panels. Ensure that encryption is turned off for use with Lenel access panels.
Page 233 Hardware Installation Guide Server configuration IP Address. If DHCP is not used to assign IP addresses, enter the IP address manually. The IP address must be set to a unique value in the network. Enter each octet and press <Enter> between each section.
Page 234: Lantronix Uds-10/Uds100/Uds200/Uds1100
ISC Communications Flow. Flow control sets the local handshaking method for stopping serial input/output. The default setting is 00. See Common Flow Control Valueson page 241. Port No. The port number setting represents the source port number in TCP connections. It is the number that identifies the channel for remote initiating connections.
Page 235 Hardware Installation Guide Hold down the <X> key on your keyboard and plug the power back into the UDS device. This will allow you to enter the setup mode on the ETHLAN. At this point, type <Enter>, and follow the onscreen instructions for programming. When prompted for a password, please use UDS and press <Enter>.
Page 236 ISC Communications Step 3: Configure the UDS ETHLAN Make sure that the device is powered up, completely booted, and connected to the Network. Start Telnet. From the connect menu, connect to the device using the IP address, Port address of 9999, and terminal type of VT100.
Page 237 Hardware Installation Guide 41.8.1 Wiring Configuration for Custom DB25 Serial Cable The cable for the UDS must be a straight through cable. The Other LANTRONIX devices, such as the MSS- 100, require a null cable for serial communication to the ISC. The cable is also different because the MSS- 100 uses a serial cable with a female DB25 connector.
Page 238 ISC Communications To LAN Configuring UDS-10 to ISC 4-Wire (232) 10 Base T 6 VDC Lantronix ISC: Communications Interface Type = RS-232 25-Pin Female Serial Connector RS-232 Type = 4-Wire RS-232 (Refer to ISC documentation for more information ) Pin 2 TX D 485 232 TR1+...
Page 239 Hardware Installation Guide Unit Setup (RS-232 4-wire) As of March 2004, the current firmware version is 4.5. Connect to the unit via Telnet through port 9999. The Channel 1 configuration is shown below. Wiring for RS-485 2-wire Ports 1 and 6 wiring configuration for 2-wire (RS-485) 25-pin connector TXD/TR1+ Pins 14 and 21...
Page 240 ISC Communications To LAN Configuring UDS -10 to ISC 2-Wire (485) 10 Base T 6vdc ISC: Lantronix Communications Interface Type = RS-485 RS-485 Type = 2-Wire RS-485 25-Pin Female Serial Connector (Refer to ISC documentation for more information ) Pin 14 & 21 485 232 TX D TR1+...
Page 241: Commonly Used Values
Hardware Installation Guide Unit Setup (RS-485 2-wire) As of March 2004, the current firmware version is 4.5. Connect to the unit via Telnet through port 9999. The Channel 1 configuration is shown below. 41.9 Commonly Used Values Interface (I/F) mode is a bit-coded byte entered in hexadecimal notation, as is flow control. Common I/F Mode Values I/F Mode Description...
Page 242: Lnl-Ic108A/Ic109A Rs-232 To Rs-485 Converter (4-Wire)
ISC Communications 41.10 LNL-IC108A/IC109A RS-232 to RS-485 Converter (4-wire) Black Box Settings: Jumpers: W5 - should be on B-C to set RTS/CTS/CD Black Box IC108A W8 - should be on A-B to set 4-wire Black Box IC109A W9 - should be on D to set ON W15 - should be on A-B to set RTS/CD Enabled W16 - should be on A to set 0 ms Turn Around Delay W17 - should be on E to set 0.15 ms Driver Enable Hold...
Page 243: Lnl-Ic108A/Ic109A Rs-232 To Rs-485 Converter (2-Wire)
Hardware Installation Guide 41.11 LNL-IC108A/IC109A RS-232 to RS-485 Converter (2-Wire) Black Box Settings: Jumpers: W5 - should be on A-B to set RTS/CTS W8 - should be on B-C to set 2-wire Black Box IC108A W9 - should be on C to set 0-msec Black Box IC109A W15 - should be on B-C to set DATA Enabled W16 - should be on B to set 0.1 msec Turn Around Delay (This may...
Page 244: Configuring Two Lnl-838A Rs-232 To Rs-485 Converters
ISC Communications 41.12 Configuring Two LNL-838A RS-232 to RS-485 Converters Use the following information to set up black boxes LNL-838A (LD485A). 41.12.1 Black Box Settings for 2-wire RS-485 Configuration Jumpers W5 should be on A-B to set RTS/CTS. W8 should be on B-C to set 2-wire W9 should be on C to set 0-msec W15 should be on B-C to set DATA Enabled W16 should be on B to set 0.1 msec Turn Around Delay.
Page 245 Hardware Installation Guide 2-wire RS-485 Black Box LD485A Black Box LD485A A B C D A B C 17VAC BIAS TERM. BIAS TERM. XW1B XW1A XW1B XW1A 25-Pin Serial Connector 25-Pin Serial Connector ISC panels can be multidropped on the RS-485 line using this configuration.
Page 246 ISC Communications 41.12.3 Black Box Settings for 4-wire RS-485 Jumpers W5 should be on A-B to set RTS/CTS. W8 should be on B-C to set 4-wire W9 should be on C to set 0-msec W15 should be on B-C to set DATA Enabled W16 should be on B to set 0.1 msec Turn Around Delay.
Page 247: Dial-Up Configuration For The Isc
Hardware Installation Guide 4-wire RS-485 Configuration Black Box LD485A Black Box LD485A A B C D A B C BIAS TERM. 17VAC BIAS TERM. XW1B XW1A XW1B XW1A 25-Pin Serial Connector 25-Pin Serial Connector ISC panels can be multidropped on the RS-485 line using this configuration.
Page 248 ISC Communications Dial-Up Configuration 9Vac (1000mA) Power Supply Modem Configuration: 8 Data, 1 Stop, No Parity US Robotics Sportster US Robotics Sportster 56Kbps Modem 56Kbps Modem 9Vac (1000mA) Power Supply 25 Pin Male Connector 25 Pin Female Connector 25 Pin Male Connector Modem-controller cable, part #HOC-56KEXT Standard Modem Cables...
Page 249 Hardware Installation Guide The US Robotics Sportster 56Kbps modems (LNL-56KEXT) have eight DIP switches which need to be configured. They are located on the back of the modem. DIP SWITCH SETTINGS Position Definition Switch Data Terminal Ready normal DOWN Data Terminal Ready Override Verbal result codes DOWN Numeric result codes...
Page 250 ISC Communications The Sportster modem also has a row of indicator lights in the front: ARQ/FAX Error control Clear to send Terminal ready Send Data Received Data Carrier Detect Auto Answer 41.13.1 Courier 3Com U.S. Robotics 56K (external) Modem Features of this modem include: •...
Page 251: Securcomm Uniflex Dc336 Modems (12 Vdc)
Hardware Installation Guide Enter the following commands: AT&F0<Enter> AT+PIG=1+PMH=1+PQC=3<Enter> ATY0X4T&A3&B1&H1&R2&W0<Enter> Exit the terminal program. 41.14 Securcomm Uniflex DC336 Modems (12 VDC) The Securcomm Uniflex DC336 modem (LNL-DC336) is the recommended modem for (ISC) dial-up configurations for the ISC end. Refer to the following diagram for wiring the modem and panel. revision 7 —...
Page 252 ISC Communications Securcomm Uniflex DC336 Modem Two-pin jumper- ON: Dumb mode operation OFF: Smart mode (default) 25-pin female RS-232 connector (Back panel of modem) Power switch 25 Pin Male Connector VAC/VDC - connector accepts a 12 VDC power source RJ-11 connector (at least 300 mA) Modem-controller cable, part #HOC-56KEXT...
Page 253: Comtrol Rocketport Hub Si
Use a jumper to connect the two pins for dumb mode. For smart mode, leave them off (unconnected). The default setting for Lenel hardware is smart mode. When the modem is in dumb mode, it operates as though it has no command mode.
Page 254 ISC Communications 41.15.1 RocketPort Hub Settings Note: These settings can be modified in Device Manager. Port RS Mode = RS-485 Override and Lock Baud Rate To = None Timeout on transmit data on port close = 1 sec. Inactive Timeout Period = 120 sec. Map 2 stop bits to 1 = Off Wait on physical transmission before completing write = Off Emulate modem hardware RING signal = Off...
Page 255 Hardware Installation Guide TR 1+ R XD AC D C TR 1- R TS R 1+ C TS G N D R 1- G N D G N D TR 2+ I N 2 TR 2- G N D I N 1 G N D TR 3+ TR 3-...
Page 256: Jumper Settings
ISC Communications ISC Settings Jumper Settings LNL-500 LNL-1000 LNL-2000 Jumper 1 Jumper 2 512 K Jumper 3 512 K Jumper 4 512 K Jumper 5 Jumper 6 not used Jumper 7 Jumper 8 Jumper 9 Jumper 10 Jumper 11 Jumper 12 Jumper 13 Jumper 14 Jumper 15...
Page 257 Hardware Installation Guide DIP Switch Settings DIP switch LNL-500 LNL-1000 LNL-2000 Address Baud 38400 38400 38400 41.15.3 RocketPort Driver Be sure to install the driver for the RocketPort Si Hub from Comtrol. When finished, you will need to restart the computer. 41.15.4 Configuring the RocketPort Hub Configure the RocketPort...
Page 258: Ifs Single/Multi-Mode Duplex Data Transmitters Receivers (Dfdmm001-Tx And 7Dfdmm001-Rx)
IFS Single/Multi-mode Duplex Data Transmitters Receivers (DFDMM001-TX and 7DFDMM001-RX) Note: These configuration instructions are for use with the OnGuard software. For detailed installation and configuration information, refer to the Single Multi-Mode Duplex Data Transmitters Receivers Installation Guide which is included with the device.
Page 259: Safety Instructions
The DFDMM001-TX and DFDMM001-RX are both needed, since they work as a pair, connecting upstream to a Lenel Access or Security Series controller. Up to eight (8) devices can be connected downstream. They can be connected downstream with the LNL-1100, 1100-U, 1200, 1200-U, 1300, 1300-U, 1320, 1320-U, NGP-1100, 1100-U, 1208, 1200-U, 1300-U, 1320, or 1320-U.
Page 260 ISC Communications WARNING: Do not disconnect the fiber optic connector while the unit is powered up. Exposure to Class I invisible optical radiation is possible when the internal fiber optic connector is disconnected while the unit is powered up. Caution: Any access to the controls, adjustments, or performing operations, which are other than those specified, may result in hazardous radiation exposure.
Page 261: Led Indicators
Hardware Installation Guide 41.16.3 DIP Switch Settings and Connections Model Mode DIP switches Terminal Upstream Port DFDMM001-TX 2-wire RS-485 SW 3 ON, SW 1, 2, 4 off DFDMM001-RX 2-wire RS-485 SW 3 ON, SW 1, 2, 4 off 41.16.4 LED Indicators DFDMM001-TX Indicator Color...
Page 262 ISC Communications 41.16.5 Fiber Connection Note: Earlier versions of these part numbers may be marked with the GE Security logo. When using existing equipment, ensure the part numbers and revisions match as above to ensure proper support. 262 — revision 7...
Page 263: Lnl-1100 Input Control Module
LNL-1100 INPUT CONTROL MODULE...
Page 265: Overview Of The Lnl-1100
Hardware Installation Guide Overview of the LNL-1100 The Input Control Module (ICM) provides the access control system with high-speed acknowledgment of critical alarm points in monitored areas. It has sixteen configurable input control points and two output control relays. The ICM supports normally open, normally closed, supervised and non-supervised circuits. The input circuits are scanned at a rate of sixty (60) times per second, with a debounce timing of 64 mS.
Page 266: The Input Control Module (Series 2)
LNL-1100 Input Control Module 42.2 The Input Control Module (Series 2) The series 2 Input Control Module board contains the following components: sixteen (16) software configurable alarm inputs, two (2) non-supervised alarm inputs, two (2) alarm output relays, one (1) RS-485 interface, one (1) power input, eight (8) DIP switches, jumpers, and status LEDs.
Page 267 Hardware Installation Guide Run time: After the above sequence, the LEDs have the following meanings: A LED: Heartbeat and On-Line Status: • Off-line: 1 second rate, 20% ON • On-line: 1 second rate, 80% ON B LED: Communication Port Status: •...
Page 268: Installation
LNL-1100 Input Control Module Installation To install the Input Control Module, perform the installation procedures described in the following sections, in the order in which they are presented. 43.1 Wiring Wire the non-supervised alarm inputs for power fault and cabinet tamper monitoring. Wire the software configurable alarm inputs.
Page 269 Hardware Installation Guide These alarm inputs are connected using Inputs 1-16. Wire the Inputs 1-16 contacts using twisted pair cable, 30 ohms maximum, 24 AWG minimum. The gauge of the wire may vary, depending on distance and line resistance. Each input that is configured as a supervised alarm must also be terminated with two (2) 1000-ohm resistors (1% tolerance - 0.25 watt.
Page 270 LNL-1100 Input Control Module LNL-1100 series 2 upstream controller communication wiring: 2-wire (port 1) RS-485 2-WIRE COMMUNICATIONS TR + TR - T- SG Wire with 24 AWG stranded Earth Ground twisted pair with shield 43.1.4 Relay Outputs Two form-C contact relays are provided for controlling door strikes or other devices. Load switching can cause abnormal contact wear and premature contact failure.
Page 271 Hardware Installation Guide Use sufficiently large gauge of wires for the load current as to avoid voltage loss. 12 VDC DC STRIKE DIODE 1N4002 (100 V/1A) TYPICAL DIODE CURRENT RATING > 1X STRIKE CURRENT DIODE BREAK DOW N VOLTAGE > 4X STRIKE VOLTAGE AC STRIKE XFMR FOR 24 VAC STRIKE, PANASONIC ERZ-C 07 DK470...
Page 272: Elevator Control
43.2 Elevator Control OnGuard hardware is capable of supporting elevator control for up to 128 floors. An elevator reader has an input/output module that controls the access to floors via an elevator. The application software must be configured for elevator control. This can be done on the Elevator Hardware tab in the Readers window of the System Administration software.
Page 273: Configuration
Device communication address (0 - 31) 6, 7 Communication baud rate Downstream encryption (available with OnGuard 2009 or later) 44.1.1 Device Address To configure the device communication address, set DIP switches 1, 2, 3, 4, and 5 according to the following table.
Page 274 LNL-1100 Input Control Module ADDRESS DIP SWITCH 44.1.2 Communication Baud Rate To configure the communication baud rate, set DIP switches 6 and 7 according to the following table. BAUD RATE: DIP SWITCH 38,400 bps 19,200 bps 274 — revision 7...
Page 275 BAUD RATE: DIP SWITCH 9600 bps 11,5200 bps Currently, OnGuard only supports a baud rate of 38400 bps, so be sure to set both DIP switches 6 and 7 to the ON position. 44.1.3 Communication Password Status DIP switch 8 controls the utilization of encryption.
Page 276: Installing Jumpers
LNL-1100 Input Control Module 44.2 Installing Jumpers The following diagram describes the use of each jumper on the board. The jumper is indicated by brackets [ ]. The default shipping position is shown below. TB 5 I1 0 I1 0 TB 2 TB 6 I1 1...
Page 277 Hardware Installation Guide EOL Termination 32 Downstream Devices Total Intelligent System Controller Downstream Communications • Four 2-wire ports • Two 4-wire ports Termination • Combination 2 and 4 wire ports RS-485 Required Multi-drop 2 or 4 wire Single Reader Dual Reader Interface Module Interface Module Input/Output...
Page 278: Specifications
LNL-1100 Input Control Module Specifications **The LNL-1100 series 2 is for use in low voltage, class 2 circuits only. These specifications are subject to change without notice. • Primary power: 12 to 24 VDC + 10%, 350mA maximum 12 VDC @ 300 mA nominal 24 VDC @ 220 mA nominal •...
Page 279: Lnl-1100-U Input Control Module
LNL-1100-U INPUT CONTROL MODULE...
Page 281: Overview Of The Lnl-1100-U Board
Hardware Installation Guide Overview of the LNL-1100-U Board The Input Control Module (ICM) board contains the following components: sixteen (16) software configurable alarm inputs, two (2) unsupervised alarm inputs, two (2) alarm output relays, one (1) RS-485 interface, power input, DIP switches, and jumpers. ICM board (Dimensions are in inches [mm]) 46.1 Package Contents...
Page 282: Installation
LNL-1100-U Input Control Module Installation To install the Input Control Module (ICM), perform the installation procedures described in the following sections, in the order in which they are presented. Set baud rate (SW1), address (SW2), and LED control switches. Install jumpers. Mount the board in the enclosure.
Page 283: Configuration
Hardware Installation Guide Configuration The Input Control Module board contains two (2) 8-position DIP switches that are user-selectable to control addressing, baud rate, and other user functions, and one (1) RS-485 termination jumper used to configure the system. 48.1 Setting DIP Switches ICM dip switches 48.1.1 Communication Baud Rate (SW1)
Page 284 LNL-1100-U Input Control Module LED Mode SW1 switch 5 is used for LED control. It is read at boot time. If you make a change to this setting, be sure to restart. Note: The status LEDs only function when the cabinet tamper switch is open (cabinet door is open). When the cabinet tamper switch is closed (cabinet door is closed), the status LEDs are off.
Page 285: Installing Jumpers
Hardware Installation Guide Address SW2 switch 48.2 Installing Jumpers Jumper configuration Host Communications: Jumper J22 pins 1 and 2 for RS-485 communications termination. Install jumper on the last ICM on the communications line for proper termination of the communications bus. (For more information, refer to the ICM upstream wiring diagram on page 293.)
Page 286: Status Leds
LNL-1100-U Input Control Module 48.3 Status LEDs Note: The status LEDs only function when the cabinet tamper switch is open (cabinet door is open). When the cabinet tamper switch is closed (cabinet door is closed), the status LEDs are off. 48.3.1 LED Table for Series 2 LNL-1100 Mode When switch 5 is in the ON position, the LEDs behave like the series 2 LNL-1100.
Page 287 Hardware Installation Guide CPU status LED D79 possible module error conditions for LED Normal and Series 2 modes. Error condition Flashing Description pattern No valid application firmware 3 Red, The module is not operational. Firmware must be 2 Green loaded using a console, e.g. HyperTerminal with Xmodem.
Page 288: Mounting
LNL-1100-U Input Control Module Mounting The ICM can be mounted in the LNL-AL400ULX or LNL-AL600ULX-4CB6 and the LNL-CTX or LNL-CTX6 enclosure using the Universal Mounting Plate (UMP) LNL-CONV-U1. Mounting the ICM in the LNL-AL400ULX and LNL-CTX 288 — revision 7...
Page 289 Hardware Installation Guide Mounting the ICM in the LNL-AL600ULX-4CB6 or LNL-CTX6 revision 7 —...
Page 290: Wiring
LNL-1100-U Input Control Module Wiring Wire inputs I1 through I16 (J9 - J16) using a twisted pair cable, 30 ohms maximum, 24 AWG minimum. Note: For UL installations, refer to section UL Listed Installations on page 296. ICM input wiring Note: For termination resistor values, refer to the Input Resistor Table...
Page 291: Unsupervised Alarm Inputs: Power Fail And External (Cabinet) Tamper
Hardware Installation Guide Each input that is configured as a supervised alarm must also be terminated with two (2) 1K (1000) ohm resistors (1% tolerance - 1/4 (0.25) watt. N/O and N/C alarms are terminated identically). Resistors are provided with the module. Install the resistors as close to input device as possible.
Page 292: Upstream Controller Communication
LNL-1100-U Input Control Module Unsupervised Alarm Input Wiring (Power Fail and External Tamper contacts) 50.3 Upstream Controller Communication The ICM uses Port 1 to communicate to the Intelligent System Controller. Port 1 is a 2-wire RS-485 interface, that requires the following type of RS-485 cable: 24 AWG (minimum) twisted pair (with shields).
Page 293: Control Output Wiring
Hardware Installation Guide ICM upstream wiring To enable RS-485 termination, install jumper on pin header J22 (on the last unit on the communication line). Notes: The (EIA) Electronic Industries Association standard defines RS-485 as an electrical interface for multi-port communications on a bus transmission line. It allows for high-speed data transfer over extended distances (4000 feet [1219m]).
Page 294: Elevator Control
50.5 Elevator Control OnGuard hardware is capable of supporting elevator control for up to 128 floors. An elevator reader has an input/output module that controls the access to floors via an elevator. The OnGuard software must be configured for elevator control. This can be done from System Administration by selecting the Elevator check box on the General tab in the Readers and Doors form.
Page 295: Power And Communications
Hardware Installation Guide Note: In order for this check box to be available, the access panel to which this reader module is connected must have Elevator support enabled on the Options tab. With elevator control on the LNL-1300 reader, door strike and contact are not available, and REX (Request to EXit) is disabled.
Page 296: Ul Listed Installations
LNL-1100-U Input Control Module Wire the Power In input with 18 AWG (minimum) twisted pair cable. Power Source Requirements Current DC power source Isolated, non-switching, regulated DC power 300mA for 12VDC 150mA for 24VDC Note: Be sure to observe polarity. Power source wiring 50.7 UL Listed Installations...
Page 297: Specifications
Hardware Installation Guide Specifications Note: For UL installation, refer to section UL Listed Installations on page 296. The LNL-1100-U is for connection to low voltage, class 2 power-limited circuits only. These specifications are subject to change without notice. • Primary power: 12 to 24 VDC + 10% 12 VDC @ 300 mA nominal 24 VDC @ 150 mA nominal 12.3 BTU/hour...
Page 298 LNL-1100-U Input Control Module 298 — revision 7...
Page 299: Lnl-1200 Output Control Module
LNL-1200 OUTPUT CONTROL MODULE...
Page 301: Overview Of The Lnl-1200
RS-485 communication. Each OCM is an individually addressed device, with a maximum of sixteen OCMs on each ISC. The OCM, like most other Lenel hardware products, can be powered by 12 to 24 VDC power. Dedicated tamper and power failure input contacts are included with every OCM.
Page 302: The Output Control Module (Series 2)
LNL-1200 Output Control Module 52.2 The Output Control Module (Series 2) The LNL-1200 series 2 board contains the following components: sixteen (16) alarm output relays with sixteen (16) corresponding status LEDs, two (2) unsupervised alarm inputs, one (1) RS-485 interface, one (1) power input, eight (8) DIP switches, and jumpers.
Page 303 Hardware Installation Guide 52.2.1 Status LEDs The series 2 Output Control Module contains a total of 20 LEDs to verify correct installation after power up. Power-up: All LED’s OFF. Initialization: Once power is applied, initialization of the module begins. The A LED is turned on at the beginning of initialization. If the application program cannot be run, the A LED will flash at a rapid rate.
Page 304: Installation
LNL-1200 Output Control Module Installation To install the Output Control Module, perform the installation procedures described in the following sections, in the order in which they are presented. 53.1 Wiring Wire the unsupervised alarm inputs for power fault and cabinet tamper monitoring. Wire the upstream host communication.
Page 305 Hardware Installation Guide The RS-485 communication is asynchronous, half-duplex, using 1 start bit, 8 data bits, 1 stop bit. LNL-1200 series 2 upstream controller communication wiring: 2-wire (port 1) RS-485 2-WIRE COMMUNICATIONS TR + TR - T- SG Wire with 24 AWG stranded Earth Ground twisted pair with shield...
Page 306: Elevator Control
. 53.2 Elevator Control OnGuard hardware is capable of supporting elevator control for up to 128 floors. An elevator reader has an input/output module that controls the access to floors via an elevator. 306 —...
Page 307 Hardware Installation Guide The application software must be configured for elevator control. This can be done on the Elevator Hardware tab in the Readers window of the System Administration software. The “Elevator” box should be checked. The reader’s type, name, port, address, access panel, can all be defined here. With elevator control on the LNL-1300 reader, door strike and contact are not available, and REX (Request to EXit) has been disabled.
Page 308: Configuration
Device communication address (0 - 31) 6, 7 Communication baud rate Downstream encryption (available with OnGuard 2009 or later) 54.1.1 Device Address To configure the device communication address, set DIP switches 1, 2, 3, 4, and 5 according to the following table.
Page 309 Hardware Installation Guide ADDRESS DIP SWITCH 54.1.2 Communication Baud Rate To configure the communication baud rate, set DIP switches 6 and 7 according to the following table. BAUD RATE: DIP SWITCH 38,400 bps (default) 19,200 bps revision 7 —...
Page 310 BAUD RATE: DIP SWITCH 9600 bps 115,200 bps Currently, OnGuard only supports a baud rate of 38400 bps, so be sure to set both DIP switches 6 and 7 to the ON position. 54.1.3 Communication Password Status DIP switch 8 controls the utilization of encryption.
Page 311: Installing Jumpers
Hardware Installation Guide 54.2 Installing Jumpers The following diagram describes the use of each jumper on the board. The jumper is indicated by brackets [ ]. The default shipping position is shown below. O UT 9 O UT 1 O UT 10 O UT 2 O UT 11 O UT 3...
Page 312 LNL-1200 Output Control Module EOL Termination Downstream Communications 32 Downstream • Four 2-wire ports Devices • Two 4-wire ports Intelligent System Controller • Combination 2 and 4 wire ports Total RS-485 Multi-drop 2 or 4 wire Dual Reader Single Reader Interface Module Interface Module Input/Output...
Page 313: Specifications
Hardware Installation Guide Specifications ** The LNL-1200 series 2 is for use in low voltage, class 2 circuits only. These specifications are subject to change without notice. • Primary Power: 12 to 24 VDC ± 10%, 1100mA maximum 12 VDC @ 850mA nominal 24 VDC @ 450mA nominal •...
Page 314 LNL-1200 Output Control Module 314 — revision 7...
Page 315: Lnl-1200-Uoutput Control Module
LNL-1200-U OUTPUT CONTROL MODULE...
Page 317: Overview Of The Lnl-1200-U Board
Hardware Installation Guide Overview of the LNL-1200-U Board The Output Control Module (OCM) board contains the following components: sixteen (16) alarm output relays with sixteen (16) corresponding status LEDs, two (2) unsupervised alarm inputs, one (1) RS-485 interface, power input, two (2) DIP switches, and jumpers. OCM board (Dimensions are in inches [mm]) 56.1 Package Contents...
Page 318: Installation
LNL-1200-U Output Control Module Installation To install the Output Control Module, perform the installation procedures described in the following sections, in the order in which they are presented. Set baud rate (SW1), address (SW2), and LED control switches. Install jumpers. Mount the board into the enclosure.
Page 319: Configuration
Hardware Installation Guide Configuration The Output Control Module board contains two (2) 8-position DIP switches that are user selectable to control addressing, baud rate, and other user functions, and one (1) RS-485 termination jumper used to configure the system. 58.1 Setting DIP Switches 58.1.1 Communication Baud Rate (SW1)
Page 320 LNL-1200-U Output Control Module 58.1.2 Device Address (SW2) Configure the board address using SW2. (Switches 6-8 are not used.) Address SW2 switch 320 — revision 7...
Page 321: Installing Jumpers
Hardware Installation Guide Address SW2 switch 58.2 Installing Jumpers Jumper configuration To enable RS-485 termination, install jumper on pin header J36. For more information, refer to the Upstream Communication section on page 327. Host Communications: Jumper J36 pins 1 & 2 for RS-485 communications. Install the jumper on the last OCM on the communications line.
Page 322: Status Leds
LNL-1200-U Output Control Module 58.3 Status LEDs 58.3.1 LED Table Indication State RS-485 panel communication ON - Yellow Power on ON - Green Relay 1 ON - Green Relay 2 ON - Green Relay 3 ON - Green Relay 4 ON - Green Relay 5 ON - Green...
Page 323 Hardware Installation Guide Error condition Flashing Description pattern Boot loader loading firmware 2 Red, Console boot loader is loading a firmware file. file 2 Green Invalid EFL file 1 Red, The EFL specified to be loaded using the console 2 Green loader is not a valid EFL file.
Page 324: Mounting
LNL-1200-U Output Control Module Mounting The OCM can be mounted in the LNL-AL400ULX or LNL-AL600ULX-4CB6 and the LNL-CTX or LNL-CTX6 enclosure using the Universal Mounting Plate (UMP) LNL-CONV-U1. Mounting the OCM in the LNL-AL400ULX and LNL-CTX 324 — revision 7...
Page 325 Hardware Installation Guide Mounting the OCM in the LNL-AL600ULX-4CB6 or LNL-CTX6 revision 7 —...
Page 326: Wiring
LNL-1200-U Output Control Module Wiring For UL installations, refer to section UL Listed Installations on page 331. 60.1 Unsupervised Alarm Inputs: Power Fail and External (Cabinet) Tamper The Output Control Module features two (2) unsupervised alarm inputs that can be used for power fail and external (cabinet) tamper monitoring.
Page 327: Upstream Communication
Hardware Installation Guide Note: Input Status LEDs will be off when the tamper device is in the closed position or the jumper is installed. 60.2 Upstream Communication The OCM uses Port 1 to communicate to the Intelligent System Controller. Port 1 is a 2-wire RS-485 interface, that requires the following type of RS-485 cable: 24 AWG (minimum) twisted pair (with shields).
Page 328: Relay Outputs
LNL-1200-U Output Control Module reflection and external noise coupling. Each component provided has an on-board terminator. The installer should determine which device is at the end of the communication line. 60.3 Relay Outputs The Output Control Module contains sixteen (16) form-C dry-contact relay outputs, Relay 1 through 16 (K1-K11 &...
Page 329: Elevator Control
60.4 Elevator Control OnGuard hardware is capable of supporting elevator control for up to 128 floors. An elevator reader has an input/output module that controls the access to floors via an elevator. The OnGuard software must be configured for elevator control. This can be done from System Administration by selecting the Elevator check box on the General tab in the Readers and Doors form.
Page 330: Power And Communications
LNL-1200-U Output Control Module Overview of Elevator Control Access Control System Intelligent System Controller Maximum: 4000 feet (1219.2 meters) Output Input Control 5 conductors Control Module Module Single Single Reader Reader Single Reader Interface Interface Interface Up to 128 Outputs - Up to 128 Inputs - Module eight Output Control...
Page 331: Ul Listed Installations
Hardware Installation Guide Power source wiring 60.6 UL Listed Installations For UL installations, the following must be observed: • All field wiring terminals are suitable for single wire only. • Use 22 AWG minimum for wiring RS-485. • RS-485 4-wire is “Not Evaluated by UL” and therefore cannot be used in UL Installations. •...
Page 332: Specifications
LNL-1200-U Output Control Module Specifications Note: For UL installations, refer to section UL Listed Installations on page 331. The LNL-1200-U is for connection to low voltage, class 2 power-limited circuits only. These specifications are subject to change without notice. • Primary power: 12 to 24 VDC + 10% 12 VDC @ 805 mA nominal 24 VDC @ 407 mA nominal...
Page 333: Lnl-1300 Single Reader Interface Module
LNL-1300 SINGLE READER INTERFACE MODULE...
Page 335: Overview Of The Lnl-1300
Hardware Installation Guide Overview of the LNL-1300 Lenel offers a Single Reader Interface (SRI) module for business access control solutions. Access control card readers, keypads, or readers with keypads that use standard data1/data0 and clock/data Wiegand communications are supported. Lock/unlock and facility code, off-line access modes are supported on all readers connected to the SRI.
Page 336: The Single Reader Interface Module Board (Series 2)
LNL-1300 Single Reader Interface Module 62.2 The Single Reader Interface Module Board (Series 2) The series 2 Single Reader Interface Module board contains the following components: two (2) supervised alarm inputs, one (1) RS-485 two-wire interface, two (2) relay outputs, one (1) power input, and nine (9) jumpers.
Page 337 Hardware Installation Guide • Offline: 1 second rate, 20% ON • Online: 1 second rate, 80% ON B LED: Communication Port Status: • Indicates communication activity on the communication port. 62.2.2 Series 1 and Series 2 The following tables list the differences between series 1 and series 2 hardware. Single Reader Interface Module Feature Series 1...
Page 338: Installation
LNL-1300 Single Reader Interface Module Installation To install the SRI, perform the installation procedures described in the following sections, in the order in which they are presented. Wire the supervised alarm inputs for door position and REX exit push button monitoring. Wire the upstream host communication.
Page 339 Hardware Installation Guide Door contact and REx are selectable through the access control software (by default, door contact is normally closed and REX is normally open). 63.1.2 Upstream Communication The Single Reader Interface Module uses Port 1 to communicate to the Intelligent System Controller. Port 1 is a 2-wire RS-485 interface, that requires the following type of RS-485 cable: 24 AWG (minimum) twisted pair (with shields).
Page 340 LNL-1300 Single Reader Interface Module Controller Communication TO ADDITIONAL SIO UNITS 1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8 INTERFACE INTERFACE LAST UNIT ON COMMUNICATION LINE – TERMINATOR INSTALLED 63.1.3 Relay Outputs The Single Reader Interface Module contains two (2) form-C dry-contact relay outputs, K1 and K2.
Page 341 Hardware Installation Guide Relay Contact (AC Strike) AC STRIKE XFMR FOR 24 VAC STRIKE, PANASONIC ERZ-C07DK470 MOV SELECTION: CLAMP VOLTAGE > 1.5 X VAC RMS 63.1.4 Downstream Reader Communication The Single Reader Interface Module can communicate downstream with one (1) keypad or card reader. The J1 interface is a six-wire interface that includes a buzzer control wire and an LED control wire.
Page 342 LNL-1300 Single Reader Interface Module Reader/Single Interface Module Downstream Wiring Black - GND Orange - BZR Brown - LED White - CLK/D1 Green - DAT/D0 Red - +12V 63.1.5 F/2F Protocol The LNL-1300 accepts data from readers with F/2F and supervised F/2F signaling and door hardware. Supervised F/2F is available for readers connected to Series 2 LNL-1300 modules with firmware version 1.52.13 or later.
Page 343 Hardware Installation Guide Unsupervised F/2F Reader Wiring Unsupervised F/2F Reader Wiring Callouts Callout Description Unsupervised F/2F reader TB4 on LNL-1300 TB4-1: Ground connection TB4-3: LED terminal to Reader DO (GREEN LED) connection TB4-4: Reader Data 1 connection TB4-6: +12 VDC connections Typical Supervised F/2F Reader Edge Inputs Inputs for the door position monitor and REX switches are wired directly to the F/2F reader, and can be configured for either 2-State or 4-State Supervision: open, closed, short, and cut.
Page 344 LNL-1300 Single Reader Interface Module Supervised 4-State F/2F Reader Edge Wiring Supervised 4-State F/2F Reader Edge Wiring Callouts Callout Description Supervised F/2F reader TB4 on LNL-1300 TB4-1: Ground connection TB4-2: Buzzer terminal to Reader DO (GREEN LED) connection For Supervised F/2F readers: Install jumper between D1 and LED terminals. TB4-4: Reader Data 1 connection TB4-6: +12 VDC connection Normally Closed contact for door monitor switch...
Page 345 Hardware Installation Guide Supervised F/2F Board Edge Wiring Supervised F/2F Board Edge Wiring Callouts Callout Description Supervised F/2F reader TB4 on LNL-1300 TB4-1: Ground connection TB4-2: Buzzer terminal to Reader DO (GREEN LED) connection For Supervised F/2F readers: Install jumper between D1 and LED terminals. TB4-4: Reader Data 1 connection TB4-6: +12 VDC connection 63.1.6...
Page 346: Elevator Control
63.2 Elevator Control OnGuard hardware is capable of supporting elevator control for up to 128 floors. An elevator reader has an input/output module that controls the access to floors via an elevator. The OnGuard software must be configured for elevator control. This can be done from System Administration by selecting the Elevator check box on the General tab in the Readers and Doors form.
Page 347 Hardware Installation Guide Overview of Elevator Control Access Control System Intelligent System Controller Maximum: 4000 feet (1219.2 meters) Output Input Control 5 conductors Control Module Module Single Single Reader Reader Single Reader Interface Interface Interface Up to 128 Outputs - Up to 128 Inputs - Module eight Output Control...
Page 348: Configuration
Device communication address (0 - 31) Communication baud rate (38400, 19200, 9600, or 2400 bps) Downstream encryption (available with OnGuard 2009 or later) The diagram below shows the Jumper(s) configuration for the device communication address, communication baud rate, and RS-485 termination status.
Page 349 Hardware Installation Guide 64.1.1 Device Address To configure the device communication address, set jumpers 1, 2, 3, 4, and 5 according to the following table. ADDRESS JUMPER revision 7 —...
Page 350 38400 bps 19200 bps 9600 bps 2400 bps Currently, OnGuard only supports a baud rate of 38400 bps, so be sure to set both 6 and 7 to the ON position. 64.1.3 Communication Password Status Jumper 8 controls the utilization of encryption.
Page 351 Hardware Installation Guide J3 in ON position (Cabinet Tamper is bypassed) J3 in OFF position (requires wiring) Cabinet T amper Normally open contact 64.1.5 EOL Termination Jumper J4 is used to configure the EOL termination status the Single Reader Interface Module board. There are two possible configuration options that can be used to install this jumper: “On”...
Page 352: Specifications
LNL-1300 Single Reader Interface Module Specifications The LNL-1300 series 2 is for use in low voltage, class 2 circuits only. • Primary power: 12 to 24 VDC + 10%, 150mA maximum (plus reader current) 12 VDC @ 110mA (plus reader current) nominal 24 VDC@ 60mA (plus reader current) nominal •...
Page 353: Lnl-1300E Single Door Ip Interface Module
LNL-1300E SINGLE DOOR IP INTERFACE MODULE...
Page 355: Overview Of The Lnl-1300E
Hardware Installation Guide Overview of the LNL-1300e This reader IP interface provides a network-connected, single door, PoE-based solution using single or paired readers for ingress/egress operation. The first reader port can accommodate a read head that utilizes Wiegand, magnetic stripe, or 2-wire RS-485 electrical signaling standards, one or two wire LED controls, and buzzer control (one-wire LED mode, only).
Page 356 LNL-1300e Single Door IP Interface Module The LNL-1300e board VO LED BZR CLKDATGND VO GND PoE/12 VDC POWER SELECTOR JUMPER ETHERNET RJ45 CONNECTOR RESET SWITCH ACTIVITY (YELLOW) LINK 0.15 [3.81] (GREEN) 2.55 [64.77] 2.55 [64.77] 5.4 [137.16] DIP SWITCH STATUS LEDs STATUS LEDs RLY 2 RLY 1...
Page 357: Installation
Hardware Installation Guide Installation To install the intelligent single door controller, perform the installation procedures described in the following sections, in the order in which they are presented. Wire the device for communication. Wire readers. Wire the input circuit. Wire the relay circuit. Supply power to the controller.
Page 358 LNL-1300e Single Door IP Interface Module Connections TB3-3 Reader 1 Buzzer Output TB3-4 Reader 1 CLK/Data 1/TR+ TB3-5 Reader 1 DAT/Data 0/TR- TB3-6 Reader 1 Ground TB4-1 Reader 2 LED Output TB4-2 Reader 2 Buzzer Output TB4-3 Reader 2 CLK/Data 1 TB4-4 Reader 2 DAT/Data 0 TB5-1...
Page 359 Hardware Installation Guide 67.1.3 Reader Wiring The first reader port supports Wiegand, magnetic stripe, and 2-wire RS-485 electrical interfaces. The second reader port supports Wiegand and magnetic stripe electrical interfaces. Power to the first reader is 12 VDC and is current limited to 150 mA. The second reader may be powered from the auxiliary power output on TB5-1 and TB5-2.
Page 360 LNL-1300e Single Door IP Interface Module Reader 2 wiring with optional wiring to reader port 1 VO (12VDC) FIRST READER PORT CLK/D1 DAT/D0 BRN (4) ORG (5) CLK/D1 WHT (3) DAT/D0 GRN (2) RED (1) BLK (6) SECOND READER PORT DATA1/DATA0 OR CLOCK/DATA Note: For configurations with two readers, the power and ground may be wired to reader port 1.
Page 361 Hardware Installation Guide Unsupervised F/2F Wiring (Reader Port 1) Unsupervised F/2F Wiring (Reader Port 1) Callouts Callout Description Unsupervised F/2F reader TB3 on LNL-1300e TB3-1: +12 VDC connections TB3-2: LED terminal to Reader DO (GREEN LED) connection TB3-4: Reader Data 1 connection TB3-6: Ground connection revision 7 —...
Page 362 LNL-1300e Single Door IP Interface Module Unsupervised F/2F Wiring (Reader Port 2) Unsupervised F/2F Wiring (Reader Port 2) Callouts Callout Description Unsupervised F/2F reader TB4 and TB5 on LNL-1300e TB4-1: LED terminal to Reader DO (GREEN LED) connection TB4-3: Reader Data 1 connection TB5-1: +12 VDC connections TB5-2: Ground connection Typical Supervised F/2F Reader Edge Inputs...
Page 363 Hardware Installation Guide Supervised 4-State F/2F Reader Edge Wiring (Reader Port 1) Supervised 4-State F/2F Reader Edge Wiring (Reader Port 1) Callouts Callout Description Supervised F/2F reader TB3 on LNL-1300e TB3-1: +12 VDC connections For Supervised F/2F readers: Install jumper between D1 and LED terminals. TB3-3: Buzzer terminal to Reader DO (GREEN LED) connection TB3-4: Reader Data 1 connection TB3-6: Ground connection...
Page 364 LNL-1300e Single Door IP Interface Module Supervised F/2F Wiring (Reader Port 2) Supervised F/2F Wiring (Reader Port 2) Callouts Callout Description Supervised F/2F reader TB4 and TB5 on LNL-1300e For Supervised F/2F readers: Install jumper between D1 and LED terminals. TB5-1: +12 VDC connections TB4-2: Buzzer terminal to Reader DO (GREEN LED) connection TB4-3: Reader Data 1 connection...
Page 365 Hardware Installation Guide Supervised Board Edge Wiring (Reader Port 1) Supervised Board Edge Wiring (Reader Port 1) Callouts Callout Description Supervised F/2F reader TB3 on LNL-1300e For Supervised F/2F readers: Install jumper between D1 and LED terminals. TB3-1: +12 VDC connections TB3-3: Buzzer terminal to Reader DO (GREEN LED) connection TB3-4: Reader Data 1 connection TB3-6: Ground connection...
Page 366 LNL-1300e Single Door IP Interface Module The input circuit wiring configurations shown are supported but may not be typical: Standard Supervised Circuit, 1K,1% Normally Open Contact 1K,1% Standard Supervised Circuit, 1K,1% Normally Closed Contact 1K,1% Unsupervised Circuit, Normally Closed Contact Unsupervised Circuit, Normally Open Contact 67.1.6...
Page 367 Hardware Installation Guide DC STRIKE TO DC POWER SOURCE FUSE DIODE • Diode Selection: Diode current rating: 1x strike current. Diode breakdown voltage 4x strike voltage. For 12 VDC or 24 VDC strike, diode 1N4002 (100V/1A) typical. TRANSFORMER AC STRIKE FUSE •...
Page 368: Recommended Settings For Poe
LNL-1300e Single Door IP Interface Module 67.2 Recommended Settings for PoE 67.2.1 Network Speed If the LNL-1300e is PoE-powered, some of the components in the LNL-1300e may cause intermittent communication issues when the device is running at 100 Mb/s, Therefore, it is recommended that the Network switch be configured to 10 Mbps / Half Duplex.
Page 369: Configure Network Address To Lnl- 1300E
Hardware Installation Guide Configure Network Address to LNL- 1300e Two addressing modes are available for the LNL-1300: static IP addresses and public DHCP. 68.1 Set DIP Switches to Addressing Mode The network addressing mode used is determined by the DIP switch setting on the LNL-1300e: Addressing Mode Description Public DHCP Static IP...
Page 370: Using Static Ip Addressing
LNL-1300e Single Door IP Interface Module 68.3 Using Static IP Addressing Setting the DIP switches to “0010” enables communication to the LNL-1300e via the programmed static IP address. The user can then simply address the LNL-1300e by using the static address. 68.3.1 Programming the Static IP Address Setting the DIP switches to “0011”...
Page 371: System Administration Configuration
Hardware Installation Guide Important: 3 digits must be entered in the address field, including leading zeros. When the configuration is complete, click [Assign Static Address]. If the device was assigned correctly, it will display the information in the “Current IP Configuration” and “IP Address Assignment History”...
Page 372: Elevator Control
LNL-1300e Single Door IP Interface Module Elevator Control OnGuard hardware is capable of supporting elevator control for up to 128 floors. An elevator reader has an input/output module that controls the access to floors via an elevator. The OnGuard software must be configured for elevator control. This can be done from System Administration by selecting “LNL-1300 (IP Interface)”...
Page 373: Additional Mounting Information
Hardware Installation Guide Additional Mounting Information Sources for the items shown below: • 3-gang stainless steel blank cover: Leviton part number 84033-40. Available from Graybar, part number 88158404 • Magnetic switch set: G.R.I. part number: 505 Side view OPTIONAL BLANK COVER W/SCREWS MAGNETIC TAMPER SWITCH...
Page 374 LNL-1300e Single Door IP Interface Module Mounting plate dimensions Ø0.16 [Ø4.0] Ø0.16 [Ø4.0] 3-GANG MGT HOLES MR50 MGT HOLES 2.35 [59.7] 3.30 [83.8] 3.63 [92.1] 3.63 [92.1] 3.85 [97.8] 5.50 [139.7] 374 — revision 7...
Page 375: Maintenance
Hardware Installation Guide Maintenance Refer to Firmware Updates in the Hardware Installation Guidelines section for instructions for downloading firmware. 71.1 Status LEDs At power up, LEDs 2-6 are turned ON, and then off in sequence. After the power up sequence has completed successfully, the LNL-1300e goes to the “Waiting for IP Address”...
Page 376 LNL-1300e Single Door IP Interface Module Note: If input IN1, IN2, or IN3 is defined, every three seconds the LED is pulsed to its opposite state for 0.1 second, otherwise, the LED is OFF. 376 — revision 7...
Page 377: Ul Listed Installations
Hardware Installation Guide UL Listed Installations For UL installations per U294, the following must be observed: • RS-485 is “Not Evaluated by UL” and therefore cannot be used in UL installations. • Each field-wiring terminal is suitable for single conductor (wire) only. For detailed mounting instructions, refer to the Hardware Installation Guide (DOC-600).
Page 378: Specification
LNL-1300e Single Door IP Interface Module Specification The interface is for use in low voltage, Class 2 circuits only. • Power Input: PoE powered at 12.95 watts, compliant to IEEE 802.3af or 12 VDC ± 10%, 900 mA maximum power supply •...
Page 379 Hardware Installation Guide FCC Part 15 CE marking RoHS compliant WEEE Note: These specifications are subject to change without notice. revision 7 —...
Page 380 LNL-1300e Single Door IP Interface Module 380 — revision 7...
Page 381: Lnl-1300-Usingle Door Controller Module
LNL-1300-U SINGLE DOOR CONTROLLER MODULE...
Page 383: Overview Of The Lnl-1300-U Board
Hardware Installation Guide Overview of the LNL-1300-U Board The LNL-1300-U provides a solution for interfacing to a Wiegand/ RS-485 type reader and door hardware. It can accept data from a reader with clock/data, wiegand signaling or 2-wire RS-485 (OSDP), and provides a tri-stated LED control and buzzer control.
Page 384: Installation
LNL-1300-U Single Door Controller Module Installation To install the SDC, perform the installation procedures described in the following sections, in the order in which they are presented. Set baud rate (SW1), address (SW2), and LED control switches. Install jumpers. Mount the board into the enclosure. Note: The LNL-CONV-4 Universal Mounting Plate is required when installing the board into a CTX enclosure.
Page 385: Configuration
Hardware Installation Guide Configuration The Single Reader SDC Interface Module board contains two (2) 8-position DIP switches that are user- selectable to control addressing, baud rate, and other functions, and four jumpers used to configure your system. 76.1 Setting DIP Switches SDC dip switches 76.1.1 Communication Baud Rate (SW1)
Page 386 LNL-1300-U Single Door Controller Module Note: For OSDP, set the baud rate to 9600 bps. If you are not using OSDP readers, SW1 switch 3 & 4 do not need to be set as indicated here. LED Mode SW1 switch 5 is used for LED control. It is read at boot time. If you make a change to this setting, be sure to restart the module.
Page 387 Hardware Installation Guide Address SW2 switch revision 7 —...
Page 388: Installing Jumpers
LNL-1300-U Single Door Controller Module 76.2 Installing Jumpers .Jumper configuration Host communications: • Jumper J22 pins 1 & 2 for RS-485 reader communications. Install the jumper on last the SDC on the communications line. Reader output voltage selection: • Jumper J12 pins 1 & 2 for +12VDC readers •...
Page 389: Status Leds
Hardware Installation Guide 76.3 Status LEDs Note: The status LEDs only function when the cabinet tamper switch is open (cabinet door is open). When the cabinet tamper switch is closed (cabinet door is closed), the status LEDs are off. 76.3.1 LED Table for Series 2 LNL-1300 Mode When switch 5 is in the ON position, the LEDs behave like the series 2 LNL-1300.
Page 390 LNL-1300-U Single Door Controller Module Indication State External (cabinet) tamper Open ON - Red Power fail ON - Red CPU status LED D45 possible module error conditions for LED Normal and Series 2 modes: Error condition Flashing Description pattern No valid application 3 Red, The module is not operational.
Page 391: Mounting
Hardware Installation Guide Mounting The SDC can be mounted in the LNL-AL400ULX or LNL-AL600ULX-4CB6 and the LNL-CTX or LNL-CTX6 enclosure using the Universal Mounting Plate (UMP) LNL-CONV-U2. The universal mounting plate can hold up to two (2) LNL-1300-U modules. Mounting the SDC in the LNL-AL400ULX and LNL-CTX revision 7 —...
Page 392 LNL-1300-U Single Door Controller Module Mounting the SDC in the LNL-AL600ULX-4CB6 or LNL-CTX6 392 — revision 7...
Page 393: Wiring
Hardware Installation Guide Wiring For UL installations, refer to section UL Listed Installations on page 400. 78.1 Supervised (Software Configurable) Alarm Inputs Wire the I1 and I2 inputs across pins 1 & 2 and 3 & 4 of J15 using a twisted pair cable, 30 ohms maximum. Terminate each of these inputs with two (2) 1k (1000) ohm resistors (1% tolerance - 0.25 watt).
Page 394: Upstream Communication
LNL-1300-U Single Door Controller Module Input Resistor Table Alarm Zone Contact NC Alarm Zone Contact NO 1K ± 10% Normal 2K ± 10% 2K ± 10% Alarm 1K ± 10% Fault - Line Short 0 - 50 0 - 50 ∞...
Page 395: Relay Outputs
Hardware Installation Guide Notes: The (EIA) Electronic Industries Association standard defines RS-485 as an electrical interface for multi-port communications on a bus transmission line. It allows for high-speed data transfer over extended distances (4000 feet [1219 m]). The RS-485 interface uses a balance of differential transmitter/receiver to reject common mode noise.
Page 396: Downstream Reader Communication
LNL-1300-U Single Door Controller Module Relay Contact (AC Strike) SDC AUX relay wiring 78.4 Downstream Reader Communication The Single Reader SDC Interface Module can communicate downstream with one (1) card reader. The interface is six wire that includes buzzer and LED control. The LED and buzzer are both open collector types switching (sinking) 10mA maximum.
Page 397: Open Supervised Device Protocol
Hardware Installation Guide Reader power: Voltage 12 VDC +/-10% (optional 5 VDC +/-5% jumper selectable, current 400 mA maximum to 50°C, derate to 300 mA for 70°C). Reader wiring 78.5 Open Supervised Device Protocol Open Supervised Device Protocol (OSDP) uses bi-directional communications between readers and the reader interface, providing constant monitoring of reader health, improved control of reader operation and configuration in real-time, and additional communications capabilities over a single connection, including LCD reader display control.
Page 398: Elevator Control
78.6 Elevator Control OnGuard hardware is capable of supporting elevator control for up to 128 floors. An elevator reader has an input/output module that controls the access to floors via an elevator. The OnGuard software must be configured for elevator control. This can be done from System Administration by selecting the Elevator check box on the General tab in the Readers and Doors form.
Page 399: External (Cabinet) Tamper
Hardware Installation Guide 78.7 External (Cabinet) Tamper An external cabinet tamper (EXTMP) is configured by connecting a tamper device across pins 3 & 4 of J18 on the SDC. If not used, a jumper must be installed across pins 3 & 4 of J18. Note: Power fail is not supported on the SDC;...
Page 400: Ul Listed Installations
LNL-1300-U Single Door Controller Module Power source wiring Notes: Be sure to observe polarity. Do not use an AC transformer to directly power the Single Reader SDC Interface Module. 78.9 UL Listed Installations For UL Installations, the following must be observed: •...
Page 401: Specifications
Hardware Installation Guide Specifications Note: For UL installations, refer to section UL Listed Installations on page 400. The LNL-1300-U is for connection to low voltage, class 2 power-limited circuits only. These specifications are subject to change without notice. • Primary power: 12 to 24 VDC + 10% 12 VDC @ 700 mA (includes reader current) nominal 24 VDC@ 350 mA (includes reader current) nominal...
Page 402 LNL-1300-U Single Door Controller Module ETL 294, s319 UL294, 1076 C-Tick N22193 CE marking RoHS Environmental class: Indoor dry WEEE 402 — revision 7...
Page 403: Lnl-1320 Dual Reader Interface Module
LNL-1320 DUAL READER INTERFACE MODULE...
Page 405: Overview Of The Lnl-1320
Hardware Installation Guide Overview of the LNL-1320 Lenel offers a Dual Reader Interface (DRI) module for business access control solutions. Up to 64 access control card readers, keypads, or readers with keypads that use standard data1/data0 and clock/data Wiegand communications are supported. Lock/unlock and facility code, off-line access modes are supported on all readers connected to the DRI.
Page 406: The Dual Reader Interface Module (Series 2)
LNL-1320 Dual Reader Interface Module 80.2 The Dual Reader Interface Module (Series 2) The series 2 Dual Reader Interface Module board contains the following components: eight (8) supervised/ non-supervised alarm inputs, one (1) RS-485 interface, two (2) reader interfaces, six (6) relay outputs, one (1) power input, one (1) cabinet tamper, jumpers and eight (8) DIP switches.
Page 407 Hardware Installation Guide 80.2.1 Status LEDs The series 2 Dual Reader Interface Module board contains LEDs that can be used to verify correct installation after power up. The A LED is turned on at the beginning of initialization. If the application program cannot be run, the A LED will flash at a rapid rate.
Page 408 LNL-1320 Dual Reader Interface Module • Data 0/Data 1 Mode: Flashes when data is received, either input. • RS-485 Mode: Flashes when transmitting data. LED K1 through K6: Illuminates when output relay RLY 1 (K1) through RLY 6 (K6) is energized. 80.2.2 Series 1 and Series 2 The following tables list the differences between series 1 and series 2 hardware.
Page 409: Installation
Hardware Installation Guide Installation To install the Dual Reader Interface Module, perform the installation procedures described in the following sections, in the order in which they are presented. Wire the supervised alarm inputs. Wire the upstream host communication. Wire the relay outputs. Wire the downstream TTL interface for the keypads and/or card readers.
Page 410 LNL-1320 Dual Reader Interface Module Inputs 1-4 are for Door #1, Inputs 5-8 for Door #2 DRI Alarm Input Contact Wiring Door 1 Door Contact In 1 Door 1 REX In 2 Door 1 Aux 1 In 3 Door 1 Aux 2 In 4 Door 2 Door Contact In 5...
Page 411 Hardware Installation Guide Alarm Contact Wiring S upervised 1K, 1% 1K, 1% 1K, 1% 1K, 1% Unsupervised 81.1.2 Upstream Communication The Dual Reader Interface Module uses Port 1 to communicate to the Intelligent System Controller. Port 1 is a 2-wire RS-485 interface that requires the following type of RS-485 cable: 24 AWG (minimum) twisted pair (with shields).
Page 412 LNL-1320 Dual Reader Interface Module The RS-485 communication is asynchronous, half-duplex, using 1 start bit, 8 data bits, 1 stop bit. 81.1.3 Control Output Wiring Six form-C contact relays are provided for controlling door strikes or other devices. Load switching can cause abnormal contact wear and premature contact failure.
Page 413 Hardware Installation Guide Relay Outputs DRI Alarm Output Contact Wiri Door 1 Strike RLY 1 Relay RLY 2 Door 1 Aux 1 Door 1 Aux 2 RLY 3 Door 2 Strike RLY 4 Relay RLY 5 Door 2 Aux 1 RLY 6 Door 2 Aux 2 81.1.4...
Page 414 LNL-1320 Dual Reader Interface Module Typical Reader Wiring RED (1) BRN (4) ORG (5) WHT (3) D1/CLK GRN (2) D0/DAT BLK (6) All readers that have a buzzer will beep during pre-alarm when in extended held open mode. This includes primary and alternate readers.
Page 415 Hardware Installation Guide Unsupervised F/2F Reader Wiring Callouts Callout Description TB8 or TB9 on LNL-1320 Unsupervised F/2F reader TB8-1: +12 VDC connections TB8-2: LED terminal to Reader DO (GREEN LED) connection TB8-4: Reader Data 1 connection TB8-6: Ground connection Typical Supervised F/2F Reader Edge Inputs Inputs for the door position monitor and REX switches are wired directly to the F/2F reader, and can be configured for either 2-State or 4-State Supervision: open, closed, short, and cut.
Page 416 LNL-1320 Dual Reader Interface Module Supervised 4-State F/2F Reader Edge Wiring Callouts Callout Description TB8 or TB9 on LNL-1320 Supervised F/2F reader TB8-1: +12 VDC connection For Supervised F/2F readers: Install jumper between D1 and LED terminals. TB8-3: Buzzer terminal to Reader DO (GREEN LED) connection TB8-4: Reader Data 1 connection TB8-6: Ground connection Normally Closed contact for door monitor switch...
Page 417 Hardware Installation Guide Supervised Board Edge Wiring Callouts Callout Description TB8 or TB9 on LNL-1320 Supervised F/2F reader TB8-1: +12 VDC connection For Supervised F/2F readers: Install jumper between D1 and LED terminals. TB8-3: Buzzer terminal to Reader DO (GREEN LED) connection TB8-4: Reader Data 1 connection TB8-6: Ground connection 81.1.6...
Page 418 LNL-1320 Dual Reader Interface Module Wire the BA and CT inputs using twisted pair cable, 30 ohms maximum (No EOL resistors are required). CABINET IN 9 TAMPER POWER FAULT IN 10 The (EIA) Electronic Industries Association standard defines RS-485 as an electrical interface for multi-port communications on a bus transmission line.
Page 419: Elevator Control
Hardware Installation Guide Supply Power to the Interface 12 to 24 VDC 81.2 Elevator Control Currently, elevator control is supported for up to six floors on the Dual Reader Interface Module. Access Control System Intelligent System Controller Maximum: 500 feet Dual Reader 6 conductors Interface...
Page 420 LNL-1320 Dual Reader Interface Module Contact Wiring for Elevator Control DRI Alarm Input Contact Wiring DRI Alarm Output Contact Wiring Floor Output 1 Reader Aux 1 In 1 RLY 1 Reader Aux 2 In 2 RLY 2 Floor Output 2 Reserved for Future Use In 3 Floor Output 3...
Page 421: Configuration
Device communication address (0 - 31) 6, 7 Communication baud rate Downstream encryption (available with OnGuard 2009 or later) 82.1.1 Device Address To configure the device communication address, set DIP switches 1, 2, 3, 4, and 5 according to the following table.
Page 422 LNL-1320 Dual Reader Interface Module ADDRESS DIP SWITCH 422 — revision 7...
Page 423 38400 bps 19200 bps 9600 bps 115,200 bps Currently, OnGuard only supports a baud rate of 38400 bps, so be sure to set both DIP switches 6 and 7 to the ON position. 82.1.3 Communication Password Status DIP switch 8 controls the utilization of encryption.
Page 424: Installing Jumpers
LNL-1320 Dual Reader Interface Module 82.2 Installing Jumpers The following diagram describes the use of each jumper on the board. The jumper is indicated by brackets [ ]. The default shipping position is shown below. [J2] Reader power : 12V = 24 VDC reduced to 12 VDC at reader ports .
Page 425: Specifications
Hardware Installation Guide Specifications **The DRI is for use in low voltage, class 2 circuits only. These specifications are subject to change without notice. • Power: 12 to 24 VDC + 10%, 550mA maximum (plus reader current) 12 VDC @ 450mA(plus reader current) nominal 24 VDC @ 270mA (plus reader current) nominal •...
Page 426 LNL-1320 Dual Reader Interface Module 426 — revision 7...
Page 427: Lnl-1320-U Dual Door Controller Module
LNL-1320-U DUAL DOOR CONTROLLER MODULE...
Page 429: Overview Of The Lnl-1320-U Board
Hardware Installation Guide Overview of the LNL-1320-U Board The Dual Door Controller (DDC) provides a solution for interfacing to Wiegand Data1/Data0 and Magnetic Clock/Data readers or keypads (4/8 bit), and door hardware. It can accept data from a reader with clock/data, Wiegand signaling, or 2-wire RS-485 (OSDP), and provides a tri-stated LED control and buzzer control.
Page 430: Installation
LNL-1320-U Dual Door Controller Module Installation To install the Dual Door Controller (DDC), perform the installation procedures described in the following sections, in the order in which they are presented. Set baud rate, address, and LED control switches. Install jumpers. Mount the board in the enclosure.
Page 431: Configuration
Hardware Installation Guide Configuration The Dual Door Controller (DDC) Interface Module board contains two (2) 8-position DIP switches that are user-selectable to control addressing, baud rate, and other functions, and seven (7) jumpers used to configure your system. 86.1 Setting DIP Switches DDC dip switches 86.1.1 Communication Baud Rate (SW1)
Page 432 LNL-1320-U Dual Door Controller Module Baud rate SW1 switch for host SW1 switch for OSDP readers (Aux ports) 9600 bps 19200 bps 38400 bps For OSDP, set the baud rate to 9600 bps. LED Mode SW1 switch 5 is used for LED control. It is read at boot time. If you make a change to this setting, be sure to restart.
Page 433 Hardware Installation Guide Address SW2 switch revision 7 —...
Page 434: Installing Jumpers
LNL-1320-U Dual Door Controller Module 86.2 Installing Jumpers Jumper configuration Host Communications • Jumper J33 pins 1 & 2 for RS-485 communications termination. Install jumper on the last DDC unit on the communications line for proper termination of the communications bus. For more information, refer to the DDC upstream communicationdiagram on page 442.
Page 435: Status Leds
Hardware Installation Guide • Jumper J17 pins 1 & 2 for +12VDC readers • Jumper J17 pins 2 & 3 for +5VDC readers Reader 1 RS-485 termination: • Jumper J29 pins 1 & 2 for RS-485 reader communications. Important: Do NOT install the jumper for Wiegand/Clock & Data/F2F Reader Communications.
Page 436 LNL-1320-U Dual Door Controller Module 86.3.1 LED Table for Series 2 LNL-1320 Mode When switch 5 is in the ON position, the LEDs behave like the series 2 LNL-1320. Indication State Power-up Initialization Flashing After initialization Offline: 1 second rate, 20% ON Online: 1 second rate, 80% ON...
Page 437 Hardware Installation Guide Indication State Unsupervised I1-I8 D69, D70-D74, Closed ON - Red, D76-D78 Open - Off CPU status Offline: 1 second rate, 20% ON Online: 1 second rate, 80% ON Flashing Green - Badge Read External (cabinet) Open ON - Red tamper Power fail ON - Red...
Page 438 LNL-1320-U Dual Door Controller Module Error condition Flashing pattern Description No valid backup firmware 3 Green, The firmware flash contains 2 copies of the copy 1 Red application firmware. The backup copy is not valid so the primary copy will be loaded into the backup copy.
Page 439: Mounting
Hardware Installation Guide Mounting The DDC can be mounted in the LNL-AL400ULX or LNL-AL600ULX-4CB6 and the LNL-CTX or LNL-CTX6 enclosure using the Universal Mounting Plate (UMP) LNL-CONV-U1. Mounting the DDC in the LNL-AL400ULX and LNL-CTX revision 7 —...
Page 440 LNL-1320-U Dual Door Controller Module Mounting the DDC in the LNL-AL600ULX-4CB6 or LNL-CTX6 440 — revision 7...
Page 441: Wiring
Hardware Installation Guide Wiring Note: For UL installations, refer to section UL Listed Installations on page 447. Wire inputs I1 through I8 (J19 - J22) using a twisted pair cable, 30 ohms maximum, 24 AWG minimum. 88.1 Supervised (Software Configurable) Alarm Inputs DDC input wiring Note: For termination resistor values, refer to the...
Page 442: Upstream Communication
LNL-1320-U Dual Door Controller Module Install the resistors (provided with the module) as close to input device as possible. For cable length limitations, refer to the Specifications section. Input Resistor Table Alarm Zone Contact NC Alarm Zone Contact NO 1K ± 10% Normal 2K ±...
Page 443: Control Output Wiring
Hardware Installation Guide To enable RS-485 termination, install jumper on pin header J33 (on the last unit on the communications line). Notes: The (EIA) Electronic Industries Association standard defines RS-485 as an electrical interface for multi-port communications on a bus transmission line. It allows for high-speed data transfer over extended distances (4000 feet [1219m]).
Page 444: Downstream Reader Communication
LNL-1320-U Dual Door Controller Module Relay contact (AC strike) DDC AUX relay wiring 88.4 Downstream Reader Communication The DDC can communicate to two (2) card readers. The interface is six-wire that includes buzzer and LED control. The LED and buzzer are both open collector type switching (sinking) 10mA maximum. Note: The LNL-1320-U does not support Bioscrypt readers or the LNL-CK keypad.
Page 445: Open Supervised Device Protocol
Hardware Installation Guide Reader power: Voltage 12 VDC +/-10% (optional 5 VDC +/-5% jumper selectable, current 400 mA maximum to 50°C, derate to 300 mA for 70°C) DDC reader wiring 88.5 Open Supervised Device Protocol Open Supervised Device Protocol (OSDP) uses bi-directional communications between readers and the reader interface, providing constant monitoring of reader health, improved control of reader operation and configuration in real-time, and additional communications capabilities over a single connection, including LCD reader display control.
Page 446: Unsupervised Alarm Inputs: Power Fail And External (Cabinet) Tamper
LNL-1320-U Dual Door Controller Module Wiring for OSDP readers 88.6 Unsupervised Alarm Inputs: Power Fail and External (Cabinet) Tamper The Dual Door Controller (DDC) features two (2) unsupervised alarm inputs that can be used for power fault and external (cabinet) tamper monitoring. These inputs are connected using the PFL (power fail) and EXTMP (external cabinet tamper) contact terminals located on the Dual Door Controller.
Page 447: Power And Communications
Hardware Installation Guide Note: Input status LEDs will be off when the tamper device is in the closed position or the jumper is installed. External (cabinet) tamper: Configure by connecting a tamper device across pins 3 & 4 of J27 on the DDC. If not used, a jumper must be installed across pins 3 &...
Page 448 LNL-1320-U Dual Door Controller Module • Use 22 AWG minimum for wiring of RS-485, Inputs I1-I8, and reader data. • Input I2 “Do not supervise for UL” and therefore cannot be used for UL installations. • RS-485, clock & data reader communications “Not Evaluated by UL” and therefore cannot be used in UL installations.
Page 449: Specifications
Hardware Installation Guide Specifications Note: For UL installations, refer to section UL Listed Installations on page 447. The LNL-1320 is for connection to low voltage, class 2 power-limited circuits only. These specifications are subject to change without notice. • Primary power: 12 to 24 VDC + 10% 12 VDC @ 1200 mA (includes reader current) nominal 24 VDC @ 600 mA (includes reader current) nominal 49.1 BTU/hour...
Page 450 LNL-1320-U Dual Door Controller Module ETL294, s319 UL294, 1076 C-Tick N22193 CE marking RoHS Environmental class: Indoor dry WEEE 450 — revision 7...
Page 451: Lnl-8000 Star Multiplexer
LNL-8000 STAR MULTIPLEXER...
Page 453: Overview Of The Lnl-8000 Board
Hardware Installation Guide Overview of the LNL-8000 Board The Star Multiplexer was designed to implement star topology on a single downstream port (ports 2 through 5) of the Intelligent System Controller, to eight RS-485 (2-wire) ports or four RS-485 (4-wire) channels. The Star Multiplexer requires 12 VDC for power.
Page 454: The Star Multiplexer Board
LNL-8000 Star Multiplexer 90.2 The Star Multiplexer Board The Star Multiplexer board contains the following components: one (1) power input, one (1) host communication RS-232/RS-485 input, eight (8) RS-485 (2-wire) Star Legs or four (4) RS-485 (4-wire), one (1) communication speed DIP Switch four-position selector and seventeen (17) jumpers. Star Multiplexer Board T R + T XD...
Page 455: Installation
Hardware Installation Guide Installation To install the Star Multiplexer, perform the installation procedures described in the following sections, in the order in which they are presented. Then be sure to configure the board in the access control system. 91.1 Wiring Wire the upstream host communication.
Page 456 LNL-8000 Star Multiplexer The main run RS-485 cable should be no longer than 4000 feet (1219 m), 120 ohms maximum (Belden 9842 for 4-wire or Belden 9841 for 2-wire, or plenum cabling Belden 88102, West Penn, or equivalent). The drop cables (to readers and other devices) should be kept as short as possible, no longer than 10 feet.
Page 457: Wiring And Termination
Hardware Installation Guide 91.2 Wiring and Termination When wiring the Star Multiplexer(s) downstream from a controller, follow these guidelines for termination: • Termination is not required on the intelligent system controller. • Termination is not required on the Star Multiplexer input (port 1). •...
Page 458: Configuration
38400 bps fast turn (365 µs) 38400 bps fast turn (365 µs) Currently, OnGuard only supports 38400 bps. Set the communication speed DIP switches in the 38400 bps positions. When connecting the star multiplexer directly to a host computer for multi-drop configuration, set DIP switches 2 and 3 to ON, and DIP switches 1 and 4 to OFF.
Page 459: Installing Jumpers
Hardware Installation Guide 92.2 Installing Jumpers The following diagram describes the use of each jumper on the board. The default shipping position is shown below. [JP2] OFF: Port 1 RS-485 EOL termination is not on ON: Port 1 RS-485 EOL termination is on [JP1, JP6, JP5, JP7] Control for Port 1, RS-232 or RS-485 TR +...
Page 460: Specifications
LNL-8000 Star Multiplexer Specifications ** The Star Multiplexer is for use in low voltage, class 2 circuits only. • Primary Power: DC input: 12 VDC ± 15%. 250 mA • Interfaces: Port 1: RS-232/RS-485, selectable Ports 3, 5, 7, 9: RS-485, Transmit/Receive Ports 2, 4, 6, 8: RS-485, Transmit/Receive or Receive Only •...
Page 461: Lnl-2005W Magnetic Card Access Reader
LNL-2005W MAGNETIC CARD ACCESS READER...
Page 463: Overview
This installation guide is intended for use by technicians who will be installing and maintaining LNL-2005W Magnetic Card Access Readers. OnGuard Magnetic Card Access Readers are durable, dependable, convenient and competitively priced. The Magnetic Card Access Readers are available in both 5 VDC and 12 VDC models. The reader’s are in fully weatherized metal casing shells, which provide strength and durability.
Page 464: Installation
LNL-2005W Magnetic Card Access Reader Installation This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation.
Page 465 Hardware Installation Guide Do not use sealant to seal reader case to wall. Doing so will trap water in the reader and may cause damage to the reader. KEYPAD CONNECTOR DIELECTRIC GREASE SWITCH SLIDE RJ-11 JACK Be sure to clean the read head(s). The leading cause of accelerated read head wear is contamination in the read head slot.
Page 466: Configuration
LNL-2005W Magnetic Card Access Reader Configuration 96.1 DIP Switch/Jumper Setting All reader models are equipped with DIP switches for configuration/parameter setting. DIP switches are set by moving the slide to on/off position using a small tool (may be made from a paper clip). Remove the top mounting bracket to access the DIP switches.
Page 467 Hardware Installation Guide 96.2.1 Wiring the LNL-1300 From LNL-1300 To LNL-2005W Reader Typical Software Settings Reader Wire Description Keypad = 8-bit Output Terminal Reader Type = Magnetic Black Ground LED Mode = 2-Wire LED Orange Red LED Control Brown Green LED CLK D1 White Data/D1...
Page 468: Grounding The Reader
LNL-2005W Magnetic Card Access Reader 96.2.4 Wiring the LNL-1320-U From LNL-1300-U To LNL-2005W Reader Typical Software Settings Reader Wire Description Keypad = 8-bit Output Terminals Reader Type = Magnetic Black Ground LED Mode = 2-Wire LED DAT D0 Green Data/D0 Control CLK D1 White...
Page 469: Maintenance
Hardware Installation Guide Mode or Status Behavior of LEDs Access Granted Blinking green light, two beeps Access Denied Steady red light, three beeps Waiting for PIN Both green and red lights blink simultaneously at half intervals for ten seconds Waiting for second card Green and red lights blink alternately at half intervals for ten seconds.
Page 470: Specifications
LNL-2005W Magnetic Card Access Reader Specifications The reader is for use in low voltage, class 2 circuits only. Power: Voltage 5 Volt Model: 5.8 VDC (4.9 to 6.4 VDC) 12 Volt Model: 12 VDC (10.2 to 13.8 VDC) Current 80 mA (25 mA typical.) Data output Data 1/0 pair or clock/data Timing - clock/data -...
Page 471: Reader Mounting Dimensions
Hardware Installation Guide 97.1 Reader Mounting Dimensions Optional Wall Plate, WP-10 1.3 (33) 2X 0.18 (4.5) MOU NTING HOLE 1.0 (25) 2.0 (50) DIMENSION: INCH (mm) Fitting Rigid Conduit to Junction Box 2.75 (70) 2X 0.18 (45) 1.4 (35) 1.2 (31) revision 7 —...
Page 472 LNL-2005W Magnetic Card Access Reader 2.3 (57) ½" RIGID CONDUIT WALL OPENING FOR J-BOX 1-GANG 472 — revision 7...
Page 473: Reader Weather Shield
Hardware Installation Guide 97.2 Reader Weather Shield Weather Shield – part number LNL-WS10 EXPOSED EDGES (FRONT AND TOP) MUST BE ROUNDED/SMOOTHED, RADIUS 0.015 TYP. FINISH: CLEAN AND DEBUR. SAND TO BREAK ALL EDGES. BRUSH FINISH TOP/SIDE SURFACES (200 GRIT). GRAIN VERTICAL. MATERIAL: STAINLESS STEEL, TYPE 304-2B, 18GA NOTES: UNLESS OTHERWISE SPECIFIED revision 7 —...
Page 474 LNL-2005W Magnetic Card Access Reader 474 — revision 7...
Page 475: Lnl-2010W/2020W/2020W-Ndk/Ndkv2 Magnetic Card
LNL-2010W/2020W/ 2020W-NDK/NDKV2 MAGNETIC CARD ACCESS READER...
Page 477: Overview
This installation guide is intended for use by technicians who will be installing and maintaining LNL-2010W, LNL-2020W, LNL-2020W-NDK, LNL-2020W-NDKV2 Magnetic Card Access Readers. OnGuard Magnetic Card Access Readers are durable, dependable, convenient and competitively priced. The Magnetic Card Access Readers are available in both 5 VDC and 12 VDC models. The LNL-2010W is magnetic swipe only and the LNL-2020W/NDK/V2 includes a twelve-position keypad.
Page 478: Installation
LNL-2010W/2020W/2020W-NDK/NDKV2 Magnetic Card Access Reader Installation This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation.
Page 479: Weatherproofing The Reader
Hardware Installation Guide ZIF connector. Then, close the slide to engage the contacts. To disconnect the keypad, follow the previously described steps in reverse. 4 3 2 1 4 3 2 1 SLIDE DISENGAGED SLIDE ENGAGED Caution: DO NOT DISCONNECT KEYPAD WITHOUT DISENGAGING THE CONNECTOR! 99.4 Weatherproofing the Reader...
Page 480 LNL-2010W/2020W/2020W-NDK/NDKV2 Magnetic Card Access Reader For heavy traffic areas, extended life read heads are also available from the factory at the time of order which will extend the read head life up to 1 million card swipes. For heavy traffic, outdoor readers should be cleaned at least once per month.
Page 481: Configuration
Hardware Installation Guide Configuration 100.1 Standard Format Code Summary The following formats are supported in standard models. Unless otherwise indicated, the LED input line controls both LEDs (low=green, high=red); the BUZZER input controls the buzzer (low = activate); a good read is signaled by a flash of the green LED; a bad read is signaled by a flash of the red LED and a double beep of the buzzer.
Page 482: Dip Switch/Jumper Setting
LNL-2010W/2020W/2020W-NDK/NDKV2 Magnetic Card Access Reader Format T (factory test) magnetic data output: verify track 2 data and send track 2 data without formatting using clock data signaling. Zero trim, reverse read, bad card filter, and tamper monitor option are enabled. 100.2 DIP Switch/Jumper Setting All readers are equipped with DIP switches for configuration/parameter setting.
Page 483: Keypad Data And Tamper Monitor Signaling
Hardware Installation Guide All other combinations are reserved. ON = switch is set to ON or jumper is uncut. 100.3 Keypad Data and Tamper Monitor Signaling Keypad data and tamper monitor status are transmitted on the data lines as 8-bit blocks. They are encoded and sent using the same signaling method as selected for the card data output (clock/data or data 1/data 0).
Page 484 LNL-2010W/2020W/2020W-NDK/NDKV2 Magnetic Card Access Reader 100.4.1 Wiring the LNL-1300 From LNL-1300 To Lenel Reader Typical Software Settings Reader Wire Description Keypad = 8-bit Output Terminal Reader Type = Magnetic Black Ground LED Mode = 2-Wire LED Orange Red LED Control...
Page 485: Onguard Configuration
Hardware Installation Guide 100.4.4 Wiring the LNL-1320-U From LNL-1300-U To Lenel Reader Typical Software Settings Reader Wire Description Keypad = 8-bit Output Terminals Reader Type = Magnetic Black Ground LED Mode = 2-Wire LED DAT D0 Green Data/D0 Control CLK D1...
Page 486: Status Indicators
LNL-2010W/2020W/2020W-NDK/NDKV2 Magnetic Card Access Reader 100.8 Status Indicators The reader has two blinking LEDs which signify its status: Mode or Status Behavior of LEDs Card and PIN Blinking red light Card Only Blinking red light Card or PIN Blinking red light Cipher Lock Emulation Blinking red light Facility Code...
Page 487: Product Identification
Hardware Installation Guide 100.10 Product Identification Reader product identification is provided on labels. These labels have information on program ID, revision, product ID, supply voltage, and copyright notice. These labels are located on the circuit board and the back of the reader. revision 7 —...
Page 488: Specifications
LNL-2010W/2020W/2020W-NDK/NDKV2 Magnetic Card Access Reader Specifications The reader is for use in low voltage, class 2 circuits only. Power: Voltage 5 Volt Model: 5.8 VDC (4.9 to 6.4 VDC) 12 Volt Model: 12 VDC (10.2 to 13.8 VDC) Current 80mA (25mA typical.) Data output Data 1/0 pair or clock/data Timing - clock/data -...
Page 489: Reader Mounting Dimensions
Hardware Installation Guide 101.1 Reader Mounting Dimensions 1.3 (33) 2X 0.18 (4.5) MOU NTIN G H OLE 1.0 (25) 2.0 (50) DIMEN SION: INC H (mm) Mounting dimensions for the LNL-2020W-NDK 1.25 (31.75) 2X 0.18 (4.5) MOUNTING HOLE 1.0 (25) 2.56 (65) DIMENSION: inch (mm) revision 7 —...
Page 490 LNL-2010W/2020W/2020W-NDK/NDKV2 Magnetic Card Access Reader Optional Wall Plate, WP-10 2.75 (70) 2X 0.18 (45) 1.4 (35) 1.2 (31) Fitting Rigid Conduit to Junction Box 2.3 (57) ½" RIGID CONDUIT WALL OPENING FOR J-BOX 1-GANG 490 — revision 7...
Page 491: Reader Weather Shield
Hardware Installation Guide 101.2 Reader Weather Shield Weather Shield – part # LNL-WS10 EXPOSED EDGES (FRONT AND TOP) MUST BE ROUNDED/SMOOTHED, RADIUS 0.015 TYP. FINISH: CLEAN AND DEBUR. SAND TO BREAK ALL EDGES. BRUSH FINISH TOP/SIDE SURFACES (200 GRIT). GRAIN VERTICAL. MATERIAL: STAINLESS STEEL, TYPE 304-2B, 18GA NOTES: UNLESS OTHERWISE SPECIFIED revision 7 —...
Page 492 LNL-2010W/2020W/2020W-NDK/NDKV2 Magnetic Card Access Reader 492 — revision 7...
Page 493: Lenelprox Readers
LENELPROX READERS...
Page 495: Lenelprox Readers
Hardware Installation Guide LenelProx Readers LenelProx readers are radio-frequency proximity readers (with or without integrated keypads). OnGuard currently supports the following models: • LenelProx LPMM-6800 • LenelProx LPSP-6820 • LenelProx LPKP-6840 • LenelProx LPSR-2400 • LenelProx LPRKP-4600 • LenelProx LPMR-1824 and LPMR-1824 MC •...
Page 496 LenelProx Readers • Do not install the reader in an area where sources of broadband noise may exist. (Examples of broadband noise sources: motors, pumps, generators, AC switching relays, light dimmers, CRTs, induction heater, etc.) • Do not bundle the reader wires together in one conduit with the AC power cables, lock power, and other signal wiring.
Page 497: Lenelprox Lpmm-6800
Hardware Installation Guide For multiple reader installations, it is critical that all readers are connected to a single ground point. Using multiple ground points will create secondary current paths or ground loops that can affect the performance and cause damage to the reader. 102.2.4 Wiring Some of these readers are designed for Wiegand and RS-232 standard communication formats.
Page 498: Reader Interface
Power up the reader. The LED is steady amber (the beeper does not sound). Present any Lenel proximity credential (card, keytag, or wafer) briefly to the reader. This initializes the reader and prepares it for reading cards authorized for the door or gate. The reader sounds a single short beep.
Page 499: Lenelprox Lpsp-6820
Hardware Installation Guide Note: In order to use this feature, the reader must be rev. LB. Previous revisions (C8, D, L, LA) of the LenelProx readers do not have this feature and cannot be upgraded. 10. When installation is complete, insert screw-hole plugs into the screw clearance holes to conceal the screw heads.
Page 500 LenelProx Readers Snap open the reader’s top cover by inserting a screwdriver blade into the slot at the bottom edge of the cover, then twisting the blade gently. Connect the reader to the access control panel according to the following figure(s). Tape or cap the unused wires singly.
Page 501 Power up the reader. The LED is steady amber. (The beeper does not sound.) Present any Lenel proximity credential (card, key tag, or wafer) briefly to the reader. The beeper sounds a single short beep. The LED is steady red to indicate standby mode. This initializes the reader and prepares it for reading cards authorized for this door or gate.
Page 502: Lenelprox Lpkp-6840
10. The LED standby mode may be changed from blinking red to steady red, or from steady red to blinking red, using an LED Mode Changer card, available from Lenel (part # LB-E). Remove power from the reader for a few seconds, then restore power. While the LED is amber, present the LED Mode Changer card to toggle the LED mode at standby.
Page 503 Hardware Installation Guide 102.5.1 Installation Install a single-gang utility box, or drill two no. 27 (0.144 inch) clearance holes for the reader and one hole for the cable, at the desired mounting height. Observe ADA height requirements. Snap open the reader’s top cover by inserting a small screwdriver blade into the slot at the bottom edge of the cover, then twisting the blade gently.
Page 504 LenelProx Readers Wiring the LPKP-6840 and the LNL-1320 From LNL-1320 To LPKP-6840 Reader Typical Software Settings Reader 1 or Reader 2 Pin Wire Color Description • Reader Type = Wiegand/Prox Black Ground • Keypad = 8-Bit Output DAT D0 Green Data 0 •...
Page 505: Operating Modes
11. The LED standby mode may be changed from blinking red to steady red, or from steady red to blinking red, using an LED mode changer card, available from Lenel (part # LB-E). Remove power from the reader for a few seconds, then restore power. While the LED is Amber, present the LED mode changer card to toggle the LED standby mode.
Page 506 LenelProx Readers • PIN-plus-Prox. Enter PIN on keypad first, then present proximity card. • Prox-Only. Present proximity card only. The read cycle is terminated when the controller send out an acknowledgment signal by pulling the LED control line low momentarily. The reader resets and is ready for the next read.
Page 507: Lenelprox Lpsr-2400
Hardware Installation Guide equipment in a residential area is likely to cause harmful interference in which case the user will be required to correct the interference at his own expense. The user are prohibited from making any change or modification to this product. Any modification to this product shall void the user’s authority to operate under FCC Part 15 Subpart A Section 15.21 regulations.
Page 508 LenelProx Readers Clip off the white connector from the end of the reader’s cable. Keep the wires as long as possible. Connect the reader to the access control panel according to the following tables. Connect the yellow wire only if used for Beeper control by the panel. Do not connect the orange, blue and violet wires to anything;...
Page 509 Power up the reader. The LED is steady amber. (The beeper does not sound.) Present any Lenel proximity credential (card, keytag, or wafer) briefly to the reader. The beeper sounds a single short beep. The LED is then steady red to indicate standby mode. The reader is now initialized and prepared to read cards.
Page 510: Lenelprox Lprkp-4600
The LED standby mode may be changed from blinking red to steady red, or from steady red to blinking red, using an LED Mode Changer card, available from Lenel. Remove power from the reader for a few seconds, then restore power. While the LED is amber, present the LED Mode Changer card to toggle the LED mode at standby.
Page 511 Hardware Installation Guide epoxy resin to protect against the environment. The reader may be mounted on a single-gang electrical utility box, or on any surface (wall, cabinet, etc.). 102.7.1 Installation Install a single-gang electric utility box, or drill two no. 27 (0.144 inch) clearance holes for the reader's screws and one hole for the cable, at the desired mounting location.
Page 512 11. Present a valid Lenel proximity credential (card, keytag or wafer) briefly to the reader. This initializes the reader. To read a credential, hold it over the indent in the lower-end of the plastic housing. To enter a keystroke, press the marked key firmly.
Page 513 15. The reader’s LED Standby mode may be changed from blinking-red to steady-red, or from steady-red to blinking-red, using an LED Mode Changer card (Lenel part # LB-E). Remove power for the LPRKP- 4600 for a few seconds, then restore power. While the LED is amber, present the LED Mode Changer card to toggle the LED's Standby mode.
Page 514: Lenelprox Lpmr-1824 And Lpmr-1824 Mc
LenelProx Readers with radio communications. Operation of this equipment in a residential area is likely to cause harmful interference in which case the user will be required to correct the interference at his own expense. The users are prohibited from making any change or modification to this product. Any modification to this product shall void the user's authority to operate under FCC Part 15 Subpart A Section 15.21 regulations.
Page 515 LPMR-1824 reader. When using the LPMR-1824 MC reader, it should be mounted on a metal surface that is larger than the 8 x 8 inch reader housing. Lenel recommends a metal surface of 12 square inches or larger.
Page 516 Do not connect the orange and violet wires to anything. Tape or cap the unused wires singly. Use a Lenel regulated power supply with linear output, between 5 volts (250 mA) and 12 volts DC maximum (600 mA peak). Do not power the LPMR-1824 from the panel’s reader input port. Tie the ground side of all DC power supplies together –...
Page 517 11. The LED standby mode may be changed from blinking red to steady red, or from steady red to blinking red, using an LED Mode Changer card, available from Lenel (part # LB-E). Remove power from the reader for a few seconds, then restore power. While the LED is Amber, present the LED Mode Changer card to toggle the LED mode at standby.
Page 518 Lenel’s proximity readers.) • For best read range, use Lenel’s Prox-Linc CS clamshell cards. For rated read range, use GR or GRMAG cards. KT key tags have read range that is about 75% of the GR cards' range. PW proximity wafers have read range that is about 40% of the GR cards' range.
Page 519 Hardware Installation Guide Present a Lenel card to the reader. The LED will change from red to amber for about 1 second, then back to steady red when the card is removed. Experiment with the maximum distance from the reader at which the card reads. Record the test results.
Page 520: Lenelprox Lplr-911
LPMR-1824 reader. When using the LPMR-1824-MC reader, it should be mounted on a metal surface that is larger than the 8 x 8 inch reader housing. Lenel recommends a metal surface 12 square inches or larger.
Page 521 Hardware Installation Guide • Use Single Point Grounding (Earthing). No ground loops. The LPLR-911 has a uni-directional antenna with an antenna beam width of about 60-70 degrees. The radiation pattern is an oval-shaped beam, which should be aimed toward where the transponders will pass. For best results, the antenna should be mounted on a post, about 6 to 7 feet above pavement, with the antenna angled slightly downward toward a vehicle passing through the drive lane.
Page 522 LenelProx Readers the reader detects and reads the transponder. Optional firmware allows the user to select read repetition rates of about 3 per second, 1 per second, or 1 per 3 seconds. Important: FAILURE TO FOLLOW THE INSTALLATION GUIDE MAY RESULT IN POOR PERFORMANCE OR EVEN CAUSE PERMANENT DAMAGE TO THE READER, THUS VOIDS THE PRODUCT WARRANTY.
Page 523 Hardware Installation Guide Width and height of surveillance zone with WS tag Install the tags on the selected surface, for example, inside vehicle windshields or on the side of bins, pallets, truck trailers, etc. The tags must be firmly attached on the inside of vehicle windshield glass, to assure rated read range.
Page 524 LenelProx Readers Applying the tag: Press the adhesive side of the tag to the mounting surface. Rub the tag lightly so that it is tightly attached to the surface, as flat as possible. This is a one-time application – the tag can not be removed from the surface and re-applied. Securing the tag: When MT tags are installed outdoors, add a bead of silicone adhesive around the entire perimeter of the tag.
Page 525 Hardware Installation Guide Wiring diagram for RS-232 output format Wiring diagram for RS-232 & Wiegand output format Complete the following steps for verification. revision 7 —...
Page 526 LenelProx Readers Connect the LPSP-6820-LR test unit, which is part of the Installation Kit, to the reader cable. Use the wiring list in the Installation Instructions. Apply power to the reader and the test unit, using the plug-in DC power module in the Installation Kit. Use either a WS tag that is attached firmly by its adhesive to a rectangle of windshield glass, or a MT tag for verification.
Page 527 Hardware Installation Guide Operating temperature: -35° to 65°C (-31° to 150°F) Operating humidity: 0 to 95% non-condensing Transmitting frequency: 902 to 928 MHz Voltage: 6.5 VDC to 15 VDC Current requirement: 1.0 A to 0.4 A Output format: Wiegand and RS-232 •...
Page 528 LenelProx Readers 528 — revision 7...
Page 529: Lenel Keypads
LENEL KEYPADS...
Page 531: Lenel Keypads
Hardware Installation Guide Lenel Keypads These keypads are available in two styles: 3 x 4 keypads (part number LNL834S121NN) and 2 x 6 keypads (part number LNL826S121NN). Lenel LNL834S121NN and LNL826S121NN Reader Power Specifications Model Voltage Current LNL834S121NN 12/ 24 V, AC/DC...
Page 532 If connecting two readers to one interface module, make sure that the LED control is connected for only one reader. Both reader LEDs can not be connected at the same time. 103.1.1 Wiring the LNL-1300 From LNL-1300 To Lenel Reader Typical Software Settings • Keypad = 8-bit Output Reader Wire...
Page 533 Hardware Installation Guide 103.1.3 Wiring the LNL-1300-U From LNL-1300-U To Lenel Reader Typical Software Settings Reader Wire Description • Keypad = 8-bit Output Terminals • Reader Type = Black Ground Wiegand/Prox • LED Mode = 2-Wire DAT D0 Green Data/D0...
Page 534 Lenel Keypads 534 — revision 7...
Page 535: Lenel Opencard Readers
LENEL OPENCARD READERS...
Page 537: Lenel Opencard Readers
Hardware Installation Guide Lenel OpenCard Readers Use the following diagrams to wire (single wire LED control) Single/Dual Reader Interface Modules and OpenCard readers. 104.1 OpenCard ISO-X Readers The ISO-X reader model LNL-XF1100D (mullion mount) operates at 6-16 VDC with an average current draw of 95mA.
Page 538 Lenel OpenCard Readers 104.1.1 Wiring the LNL-1300 Wiring From Reader Single Reader Interface Module Black Brown Orange W hite CLK/D1 Green DATA/D0 Drain Tamper Input 1k,1% Tie to Earth Ground TYPICAL SOFTW A RE SETTINGS Reader Type = W IEGAND/PROX...
Page 539 Hardware Installation Guide 104.1.2 Wiring the LNL-1320 Wiring From Reader Dual Reader Interface Module Orange Brow n W hite CLK/D1 Green DATA/D0 Black Drain Tamper Input 1k,1% Tie to Earth Ground TYPICAL SOFTW ARE SETTINGS Reader Type = W IEGAN D/PR OX Keypad = No Keypad /8-bit Output Keypad on XF 2110 Only LED Mode = 2-W IR E LED CONTROL revision 7 —...
Page 540: Opencard Xf1050-K
Lenel OpenCard Readers 104.2 OpenCard XF1050-K OpenCard XF1050-K Reader Power Specifications Model Voltage Current OpenCard XF1050-K 5 to 16 VDC 110 mA average, 160 mA peak 104.2.1 Wiring the LNL-1300 From LNL-1300 To OpenCard XF1050-K Reader Typical Software Settings •...
Page 541 Hardware Installation Guide 104.2.3 Wiring the LNL-1300-U From LNL-1300-U To OpenCard XF1050-K Reader Typical Software Settings Reader Wire Description • Reader Type = Terminals Wiegand/Prox Black Ground • LED Mode = 2-Wire LED Control DAT D0 Green Clock/D0 CLK D1 White Data/D1 LED1...
Page 542: Opencard Xf1500
Lenel OpenCard Readers 104.3 OpenCard XF1500 OpenCard XF1500 Reader Power Specifications Model Voltage Current OpenCard XF1550 5 to 16 VDC 110 mA average, 160 mA peak 104.3.1 Wiring the LNL-1300 From LNL-1300 To OpenCard XF1500 Reader Typical Software Settings •...
Page 543 Hardware Installation Guide 104.3.3 Wiring the LNL-1300-U From LNL-1300-U To OpenCard XF1500 Reader Typical Software Settings Reader Wire Description • Reader Type = Terminals Wiegand/Prox Black Ground • LED Mode = 2-Wire LED Control DAT D0 Green Clock/D0 CLK D1 White Data/D1 LED1...
Page 544 Lenel OpenCard Readers 544 — revision 7...
Page 545: Bluediamond Mobile Readers
BLUEDIAMOND MOBILE READERS...
Page 547: Bluediamond Mobile Readers
The app communicates with a reader via Bluetooth to verify identities. The Bluetooth reader is installed on a door that is configured and controlled by the OnGuard system. The system administrator issues a virtual credential to a cardholder in the system through the Lenel Credential Service.
Page 548: Directkey Toolkit
Before using a reader for verification, the reader must be commissioned first. Performing this commission requires a special installation credential from Lenel. If you are using the DirectKey Toolkit for the first time, you will also need an authorization code.
Page 549: Specifications
Note: Before installing readers, the reader names should be imported using a template. Reader names are not automatically duplicated or synchronized with the OnGuard configuration, so make sure the names match correctly. Using the DirectKey Toolkit, install the reader by choosing its serial number. You will only be able to select a reader that is unassigned.
Page 550 BlueDiamond Mobile Readers 550 — revision 7...
Page 551 Hardware Installation Guide revision 7 —...
Page 552 BlueDiamond Mobile Readers 552 — revision 7...
Page 553 Hardware Installation Guide revision 7 —...
Page 554 BlueDiamond Mobile Readers 554 — revision 7...
Page 555 Hardware Installation Guide revision 7 —...
Page 556 BlueDiamond Mobile Readers 556 — revision 7...
Page 557 Hardware Installation Guide revision 7 —...
Page 558 BlueDiamond Mobile Readers 558 — revision 7...
Page 559 Hardware Installation Guide revision 7 —...
Page 560 BlueDiamond Mobile Readers 560 — revision 7...
Page 561 Hardware Installation Guide revision 7 —...
Page 562 BlueDiamond Mobile Readers 562 — revision 7...
Page 563: Lnl-500B Biometric Reader Interface
LNL-500B BIOMETRIC READER INTERFACE...
Page 565: Overview Of The Lnl-500B
8 or higher. For later builds, the BRI can be used with any address. When configuring the reader in the OnGuard software, a unique reader number will be specified according to the port and address of the BRI. The first reader MUST always be present and be identified as reader number 0.
Page 566: The Biometric Reader Interface Board
LNL-500B Biometric Reader Interface 106.2 The Biometric Reader Interface Board The hardware contains the following components: two (2) unsupervised alarm inputs, one (1) upstream RS- 232 or RS-485 interface, two (2) downstream RS-485 interfaces (which can consist of two 2-wire or one 4- wire interfaces), one (1) 12 VDC or 12 VAC power-in input, eight (8) DIP switches, and eleven (11) jumpers.
Page 567: Installation
Hardware Installation Guide Installation To install the BRI, perform the installation procedures described in the following sections, in the order in which they are presented. Wire the upstream host communication. Wire the power input. Wire the downstream device communication. Cycle power to the device. 107.1 Wiring 107.1.1...
Page 568 LNL-500B Biometric Reader Interface longer than 4000 feet (1219 m), 100 ohms maximum (Belden 9842 4-wire or 9841 2-wire, plenum cabling Belden 88102, West Penn, or equivalent.) The drop cables (to readers and other devices) should be kept as short as possible, no longer than 10 feet. RS-485 Communications The (EIA) Electronic Industries Association standard defines RS-485 as an electrical interface for multiport communications on a bus transmission line.
Page 569 Hardware Installation Guide Upstream Host Communication Wiring (Port 1) TXD/TR1+ RXD/TR1- RTS/R1 + CTS/R1 - 2-WIRE EARTH GROUND PORT 1, CONFIGURED AS RS-485 Wire Configuration – Switch #5 must be off for all panels in this configuration. 107.1.3 Power The BRI accepts either a 12 VDC or 12 VAC ± 15% power source for its power input. The power source should be located as close to the BRI as possible.
Page 570 LNL-500B Biometric Reader Interface For Ports 2-3, the following type of RS-485 cable is required: 24 AWG (minimum) twisted pair (with shields.) The main run RS-485 cable should be no longer than 4000 feet (1219 m), 100 ohms maximum (Belden 9842 4-wire or 9841 2-wire, plenum cabling Belden 88102, West Penn, or equivalent). The 485 device drop cables off the main 485 bus (to readers and other devices) should be kept as short as possible, no longer than 10 feet.
Page 571 Hardware Installation Guide Device Drop Wiring RS-485 CABLE, 120 Ohm IMPEDANCE BELDEN 9842 OR EQUIVALENT TO PREVIOUS UNIT TO NEXT UNIT OR TERMINATED OR TERMINATED DEVICE DROP WIRING KEEP DOWN LEAD SHORT (10 FEET MAX.) TR1+ TR1- ACDC TR2+ TR2- TR3+ TR3- Biometric Reader Interface...
Page 572: Configuration
LNL-500B Biometric Reader Interface Configuration The BRI board contains 8 DIP switches and 11 jumpers that must be configured for your system. 108.1 Setting DIP Switches The following chart describes the use of each DIP switch. DIP SWITCH USED TO CONFIGURE: 1, 2, 3, 4, 5 Interface address 6, 7...
Page 573 Hardware Installation Guide ADDRESS DIP SWITCH 108.1.2 Communication Baud Rate To configure the communication baud rate, set DIP switches 6 and 7 according to the following table. This feature controls the baud rate for upstream communication. BAUD RATE DIP SWITCH 38400 bps 19200 bps 9600 bps...
Page 574: Installing Jumpers
LNL-500B Biometric Reader Interface 108.1.3 Downstream Baud Rate DIP switch 8 controls the downstream baud rate. The setting of DIP switch 8 causes the BRI to behave differently, depending on the type of firmware in use. DIP SWITCH Baud rate HandKey Bioscrypt 19200 bps...
Page 575: Maintenance
Hardware Installation Guide Maintenance 109.1 Verification The BRI board contains three Status LEDs (LED A, LED B, LED C) that can be used to verify correct installation after power up. BRI Status LEDs The following chart describes the purpose of each LED on the BRI board. Purpose This LED blinks rapidly whenever the BRI is powered up and is operating normally.
Page 576: Supported Biometric Readers
LNL-500B Biometric Reader Interface Supported Biometric Readers It is required that biometric readers be linked to a primary reader using OnGuard software. But it is also possible to set up the reader for PIN and biometric verification. If the biometric reader is used without a primary reader, it is still necessary to install a standard reader interface module (LNL-1300 or LNL-1320), even though a primary reader is not being used.
Page 577: Specifications
Hardware Installation Guide Specifications ** The LNL-500B is for use in low voltage, class 2 circuit only. • Primary Power: (DC or AC) DC input: 12 VDC ± 10%. 250 mA AC input: 12 VAC ± 15%. 400 mA RMS •...
Page 578 LNL-500B Biometric Reader Interface 578 — revision 7...
Page 579: Handkey Readers
HANDKEY READERS...
Page 581: Handkey Readers
Hardware Installation Guide HandKey Readers OnGuard supports the HandKey CR, ID3D-R, and HandKey II. The HandKey with iCLASS and MIFARE readers are also supported. 112.1 HandKey CR, II, and ID3D-R The HandKey CR, II, and ID3D-R are hand geometry readers that can be used for identity verification.
Page 582 HandKey Readers HandKey Reader Voltage: 12-24 VDC 50/60 H 1 A max. Controller 64 Readers (maximum) Ports 2-5 500B Eight readers per a biometric reader interface (maximum) 3 Ports Address n denotes termination Dual Reader Address n Handkey Handkey Interface Single Reader Reader...
Page 583 Hardware Installation Guide Pin 3 Rx Data to DB9F pin 2 HandKey (version F3) enrollment unit Note: A custom cable is provided with the HandKey reader that connects the four-pin Molex connector on the left side of the PCB to a DB-9 serial input on the enrollment station. revision 7 —...
Page 584 HandKey Readers Configure the HandKey (II, CR) reader for enrollment To use the reader, certain properties must be configured. Refer to the HandKey Installation Manual for these procedures. For HandKey units (version F1), all five of the DIP switches must be in the OFF position. If you need to reset the default configuration, set DIP switches 4 and 5 to the ON position and power up the unit.
Page 585 Hardware Installation Guide Set the reader mode to remote. If the reader is not already set to remote reader mode, do so. Press the [No] button to move through the menus until SET READER MODE appears on the display. Then press [Yes].
Page 586 HandKey Readers Set the time and date (You will also need to do this for verification readers). Time is kept using a 24 hour clock. The hour is represented by two digits, 00 to 23. The minute is represented by two digits, 00 to 59. The date is also numerical.
Page 587 Hardware Installation Guide 112.1.3 Identity Verification using the HandKey The 500B can be interfaced with the HandKey-II, HandKey-CR, or ID3D-R. Access Control Server / Enrollment Controller WAN / LAN 64 Readers (maximum) Ports 2-5 RS-232 Enrollme One 500 B per Handkey port (2-5) Reader...
Page 588 HandKey Readers Wire the HandKey for Verification HandKey version F1 Back of Handkey unit Power (plug-in transformer) DIP Switches RJ-45 jack 1 2 3 4 5 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 CTS 206-5 T002 Jumper J7: backup battery...
Page 589 Hardware Installation Guide HandKey version F3 Back of Handkey CR Reader Important: Do not ground the rear plate or the screw with the green wire Top of Reader of the HandKey reader to earth ground! Doing so may cause damage to the HandKey unit.
Page 590 HandKey Readers Important: In either AC or DC power source applications, do not connect the HandKey unit’s ground lug or rear plate to earth ground. This signal is internally connected to the HandKey signal ground, and therefore connection of that signal to earth ground would be a cause for ground loops in multi-dropped configurations.
Page 591 Hardware Installation Guide Set the time and date. Time is kept using a 24 hour clock. The hour is represented by two digits, 00 to 23. The minute is represented by two digits, 00 to 59. The date is also numerical. The month is represented by two digits (January=01, incrementing to December=12).
Page 592 HandKey Readers HandKey II Reader DIP Switches If you are using HandKey (II or CR) version F1, the DIP switches need to be set properly for RS-485 communication. Switch 1 EOL termination Enable EOL termination 1 2 3 4 5 Disable EOL termination CTS 206-5 T002 Switch 2...
Page 593 Hardware Installation Guide LNL-500B ID3D-R Reader Ground Configure the HandKey ID3D-R for Verification To use the reader for verification purposes, certain properties must be configured. Refer to the HandKey Installation Manual for these procedures. DIP switches SW 1, SW 2, and SW 4 must be in the OFF position and SW 3 must be in the ON position. If you need to reset the default configuration, set DIP switch SW 4 to the ON position and power up the Schlage unit.
Page 594: Mifare/Iclass Handkey Reader
HandKey Readers 10. You will then be asked to set the baud rate for channel 0 (RS-485 baud rate). Set the baud rate to match the setting of the biometric reader interface. You will be prompted for a baud rate code (the default is usually 19.2 Kbps).
Page 595 Once cards are encoded, they can be used on the MIFARE or iCLASS HandKey readers. 112.2.1 Encoding The device used to encode the card must be configured in OnGuard under Workstations in the Encoders/ Scanners tab. Encoder Configuration In the General tab: Under Name, type in a unique name for the device.
Page 596 HandKey Readers Select which hand you would like to capture. Click [OK]. Follow the instructions displayed on the HandKey CR. At any time, if you wish to cancel, click [Abort Capture]. When the status displays, “Biometric template capture completed,” click [OK]. After exiting the capture screen, click [OK] again to save the biometric template.
Page 597 DATA/D0 Configure the MIFARE/iCLASS HandKey Reader for Verification In order to function properly with the OnGuard software, the MIFARE HandKey reader must be running firmware version HK2-11045A.247 or higher. The iCLASS HandKey reader must be running firmware HK2-11142A.175 or higher.
Page 598 HandKey Readers Set the date format. If the date format is acceptable, press [*/No] to move onto the next option. Or enter [#/Yes] at the prompt to set the date format. Once you do this, selecting [*/No] will allow you to pass each current date format.
Page 599 Hardware Installation Guide Place your hand on the platen when instructed to do so. You may be instructed to place your hand a second time. Access is granted/denied, depending on the results of the badge number and hand geometry data from the MIFARE/iCLASS HandKey reader, as well as on the System or Individual Reject Threshold for hand geometry templates selected for the settings to store minimum score per template.
Page 600 HandKey Readers 600 — revision 7...
Page 601: Biometric Readers
BIOMETRIC READERS...
Page 603: Overview Of Biometric Readers
Hardware Installation Guide Overview of Biometric Readers This installation guide is intended for use by technicians who will be installing and maintaining the OnGuard system with Bioscrypt readers. For more information, refer to the following: • MorphoAccess SIGMA Series Reader •...
Page 604: Morphoaccess Sigma Series Reader
DESFire EV1 cards encoded with the Open Encoding Standard (DESFire) application and OpenCapture fingerprint templates. In this case, the MorphoAccess SIGMA reader is connected to OnGuard via Ethernet. 114.1 Configure as an Alternate Bioscrypt Reader In order to use the MorphoAccess SIGMA Series reader as a Bioscrypt fingerprint identification terminal, configure it in System Administration as an alternate reader that is linked to a primary reader.
Page 605: Configure To Read The Open Encoding Standard (Desfire) Application
MorphoAccess SIGMA Series reader and application key settings must be configured using MorphoBioToolbox. For information about configuring the Open Encoding Standard (DESFire) smart card format in OnGuard, refer to the "Open Encoding Standard (DESFire) Card Format Form" in the System Administration and ID Credential Center User Guides.
Page 606 Enter a name for the card format and the length of the Wiegand data that will be encoded on the cards in BOTH Length fields. Length should match the length of the Access control card format configured for the Open Encoding Standard (DESFire) card format in the OnGuard software. Leave all other fields at their default value.
Page 607 Hardware Installation Guide – Key validity start date: Select today’s date. Press [Load Key]. revision 7 —...
Page 608: Bioscrypt 4G V-Station And V-Flex Readers
Biometric Readers Bioscrypt 4G V-Station and V-Flex Readers The Bioscrypt 4G V-Station and 4G V-Flex readers can be used with OnGuard the same as V-Station and V- Flex MV1610 (3G) devices for capturing and for fingerprint verification with primary and secondary templates.
Page 609: Configuration In Secureadmin
Hardware Installation Guide In the following example, the 4G reader is using COM7. Your setup may be different. Start the SecureAdmin software and log in. On the Network tab, click Register via Client. Configure the following settings: Port: Select the port number to which the device is connected. See step 1. b.
Page 610 Biometric Readers On the Communication tab, verify the following settings: Device ID: (This value corresponds to the address of the reader and will be the Reader number in System Administration): – If you are using the reader as an enrollment/capture device, the ID should be 0. –...
Page 611 Hardware Installation Guide iii. In the User fields area, click [Add user field] (the button with a left-pointing red arrow). Type Issue Code in the Name field. Type 56 in the Start Position field. Type 8 in the Length field. Type 254 in the Success Value field.
Page 612: Reader Interface Connections
Biometric Readers Using the menu on the left side of the window, select Smart Card > Card Device Manager. Select the following check boxes: – Use Wiegand String – Overwrite Card Wiegand String – Read-Only Mode Click [OK]. 115.4 4G Reader Interface Connections LNL-500B biometric gateway and LNL-1300/1320 reader interface connections to the 4G readers is provided in this section.
Page 613: Wiring 4G Verification Readers
System Administration in the Readers and Doors folder. The Device ID configured in SecureAdmin must match the Reader number in the OnGuard configuration. Wire pin 3 on the mini-connector to earth ground. Wire pins 1 and 2 on the mini-connector to the power source.
Page 614 Biometric Readers Wiring for MIFARE/iCLASS/DESFire badges encoded using Bioscrypt 4G V-Flex (MIFARE) or 4G V-Station (iCLASS) connected to a reader interface module as Wiegand/prox Pin 14 (White) CLK/D1 Pin 12 (Green) DATA/D0 Pin 5 (Black/Red) Reader Interface Module Pigtail connected to back of reader 1 - PWR 12-24 VDC...
Page 615 Hardware Installation Guide Wiring for fingerprint verification templates using Bioscrypt 4G V-Flex or 4G V-Station connected to a reader interface module as a Bioscrypt RS-485 alternate biometric reader Pin 1 (Blue) CLK/D1 Pin 3 (Blue/Black) DATA/D0 Pin 5 (Black/Red) Reader Interface Module Pigtail connected to...
Page 616 Biometric Readers Wiring for Bioscrypt 4G V-Flex or 4G V-Station and biometric reader gateway TR1+ TR1- Pin 1 (Blue) TR2+ Pin 3 (Blue/Black) TR2- Pin 5 (Black/Red) TR3+ TR3- Pigtail connected to back of reader 1 - PWR 12-24 VDC power source 2- GND 3 - EARTH...
Page 617: Reader Configuration In Onguard
It can also be obtained from the Supplemental Material disc. Enrollment is done through the Multimedia Capture Module. When configuring the Bioscrypt readers in the OnGuard software, choose one of the following options for the reader type and output, depending on the hardware:...
Page 618 Biometric Readers 115.6.2 Configure 4G Reader Connection to LNL-500B In System Administration, complete the following steps to configure a 4G reader connected to the LNL-500B Biometric Gateway. From the Access Control menu, select Readers and Doors. On the General tab, add the primary reader: Enter the Name of the primary reader.
Page 619: Enrollment Configuration
Hardware Installation Guide 115.6.4 Configure 4G Reader Connection to LNL-1320 In System Administration, complete the following steps to configure a 4G reader connected to the LNL-1320 Dual Reader Interface. • When you add the primary reader: Enter a Name for the primary reader. Select the Panel the LNL-1320 is connected to.
Page 620: Encoding Configuration
Biometric Readers On the Fingerprint (Bioscrypt) tab, under Secondary template, select the desired settings for Biometric feature, Security level, and Store image. Additionally, select the Make duress finger check box. If this option is enabled, you must also select Activate Duress Finger Mode and Reverse Wiegand Output in SecureAdmin. Capture biometrics.
Page 621: Bioscrypt 3G Series Readers
Hardware Installation Guide Bioscrypt 3G Series Readers This section is intended for the use of the Bioscrypt VeriSeries 3G Series product line, including the V-Pass FX, V-StationA, V-StationG/H, and V-Smart hardware products. 116.1 V-Pass FX and V-StationA The V-Pass FX is a fingerprint reader. To use this reader, it must be configured as an alternate reader and linked (through the software) to a primary reader.
Page 622 Biometric Readers Communications overview for the V-Pass FX readers using the biometric reader interface gateway Server(s) WAN / LAN Software option SWG-1402 required for Bioscrypt Interface ISC (2000) RS-232, RS-485, Ethenet, Enrollment Kit Dial-up Communications 64 Readers (maximum) RS-232 Communications Ports 2 - 5 Supported Access...
Page 623: V-Smart And V-Stationg/H
Hardware Installation Guide 116.2 V-Smart and V-StationG/H The V-Smart has a fingerprint reader as well as a contactless smart card reader (MIFARE or HID iCLASS model R10). The V-SmartA-G reader is for MIFARE; the V-SmartA-H reader is for HID iCLASS. Standard V-Smart reader The V-Smart access readers interface upstream with the reader interface module (LNL-1300 and LNL-1320) as well as the intelligent dual reader controller (LNL-2220) or intelligent single door controller (LNL-2210).
Page 624: Installation
116.3 Installation Use the following information to install V-series readers (for either enrollment or access verification). Software option SWG-1402 is required in order for these readers to function with the OnGuard software. 116.3.1 Reader Power Requirements The Bioscrypt readers (V-Smart, V-Pass FX, V-Station) require an Earth ground connection to dissipate ESD (electrostatic discharge).
Page 625 Hardware Installation Guide Connection of enrollment reader (using V-Smart) +12 VDC (@ 400 mA) Ground Pigtail Smart Card Reader RJ-11 Connector (cable provided with each reader) Connect to serial port on host PC Using the cable included with the reader, plug the RJ-11 connector into the aux port on the reader. Plug the serial connector into a free port on the host computer.
Page 626 Bioscrypt V-Pass FX and standard V-StationA readers should be connected to the LNL-500B, series 2 LNL-1300 or LNL-1320, LNL-2220, or LNL-2210 (RS-485 2-wire multi-drop). The use of the series 2 reader interface modules LNL-1300/1320 requires OnGuard 5.12.012 or higher. The use of the intelligent dual reader controller LNL-2220 requires OnGuard 5.12.110 or higher.
Page 627 Hardware Installation Guide Wiring of V-Pass FX readers with LNL-500B Reader Board Signal Color Pin 8 RS485(+) Blue 485 232 Pin 7 RS485(-) Blue/Black TR1+ TR1- Pin 12 Signal Ground Black/Red ACDC TR2+ TR2- TR3+ TR3- 8 76 5 4 3 2 1 LITHIUM BR2325 500B...
Page 628 Biometric Readers Wiring of V-Pass FX with Series 2 LNL-1300 Network Identification Number MUST be set to 0. 9-24 VDC Power Supply (DC- must tie into Signal Ground) Single Reader Interface Module Pigtail Signal Ground (Black/Red) from reader RS-485 + (Blue) CLK/D1 RS-485- (Blue/Black) DATA/D0...
Page 629 Hardware Installation Guide Wiring of V-Pass FX with LNL-2220, 2210 or Series 2 LNL-1320 Network Identification Number MUST be set to 0. 9-24 VDC Power Supply (DC- must tie into Signal Ground) Reader Interface Module Pigtail from reader RS-485 + (Blue) CLK/D1 RS-485- (Blue/Black) DATA/D0...
Page 630 Biometric Readers It is recommended that the RS-485 transmission line be terminated at both ends. The recommended termination at the PC end of the line is called fail-safe termination. This terminator ensures that there is a proper bias voltage across the receiver inputs. This, in turn, ensures that the receiver is in a known state and puts less of a strain on the driver to provide that bias.
Page 631 Hardware Installation Guide V-StationA unit with Wiegand connections to reader interface (LNL-1300, 1320, 2220, or 2210) On the back of the unit, jumper TX(+) and RX(+) together, and jumper TX(-) and RX(-) together. Then wire these to TR+ and TR- respectively on the BRI. revision 7 —...
Page 632 Biometric Readers Wiring diagram of V-StationA RS-485 (2-wire) to the LNL-500B ±15% Voltage: 12VDC or 12VDC Current Draw: 250mA @ 12 VDC To ISC TR1+ ACDC TR1- 12VDC TR2+ TR2- TR3+ TR3- LITHIUM BR2325 Biometric Reader Interface Gateway Voltage: 12-24 VDC (12 V Recommended) Current Draw: Idle: 0.50 A @ 12 VDC Current Draw: Max: 1.50 A @ 12 VDC Ethernet...
Page 633 Hardware Installation Guide firmware for these units must be upgraded using VeriAdmin. The reader must be configured using VeriAdmin software (version 7.40). Configure the LED Table Settings for the reader in Idle, Enroll, or Verify modes as shown in section 116.3.8 LED Settings.
Page 634 Biometric Readers On the Biometrics tab, Select the Global Security Threshold. Make sure that the Biometric Verification is Enabled, and that Finger Required is selected. Select the number of fingers required and enter the Inter-Finger Timeout in seconds. Under Unit Mode: Select Verify.
Page 635 Hardware Installation Guide 116.3.6 V-Smart V-Smart readers can be used as access readers, connected to the reader interface module (LNL-1300, LNL-1320), intelligent dual reader controller (LNL-2220), or intelligent single door controller (LNL-2210). Wiring the V-Smart reader with the Single Reader Interface Module Power Ground (11) Power Supply...
Page 636 Biometric Readers Wiring the V-Smart reader with the Dual Reader Interface Module Power Ground (11) Power Supply Power In (8-12VDC 400 mA) (13) Dual Reader Interface Module Pigtail Wiegand D1 Out (3) CLK/D1 Wiegand D0 Out (1) DATA/D0 Wiegand Ground (6) TYPICAL SOFTWARE SETTINGS 1.
Page 637: Led Settings
Hardware Installation Guide Wiring the V-Smart reader with the Dual Reader Interface Module Power Ground (11) Power Power In (8-12VDC 400 mA) (13) Supply IDRC Reader Port Wiegand Ground (1) Wiegand D0 Out (2) DATA/D0 Wiegand D1 Out (3) CLK/D1 TYPICAL SOFTWARE SETTINGS 1.
Page 638 Biometric Readers Configure the LED Table Settings for the reader in Idle, Enroll, or Verify modes. Configure the settings for the V-Smart reader as shown in the following screenshots. LED Table Settings for Idle mode LED Table Settings for Enroll mode 638 —...
Page 639 Hardware Installation Guide LED Table Settings for Verify mode 116.3.9 Smart Card Settings If the Smart Card Manager shows an error, this means that the reader is not properly connected. Configure the Smart Card settings via the Smart Card Manager. This is accessed by clicking the smart card button in the toolbar.
Page 640 Biometric Readers Smart Card Manager (MIFARE shown) 640 — revision 7...
Page 641 Hardware Installation Guide Click [Security Settings] to configure the smart card security settings. Smart Card Security Settings for MIFARE In the ESI SiteKey Security section, if you are using a MIFARE reader, Key B Read/Write should be selected. If you are using an iCLASS reader, this field will be blank. Note that all units should be configured to these specifications for the Smartcard Administrator SiteKey: –...
Page 642 Biometric Readers MIFARE Smart Card Layout Manager For iCLASS readers, cards should already be encoded. If you require encoding, use an iCLASS encoder for the enrollment workstation. Using Bioscrypt tools will create a 1K card, which is not practical. iCLASS Smart Card Layout Manager 116.3.10 Unit Parameter Settings From the Configure menu, select Unit Parameters.
Page 643 Initially, the Aux Port is disabled and protected by a password. In order to use any of the V- Smart units for enrollment in the OnGuard software, the Aux Port must be enabled with this password: 95186274. The software will then recognize this password, and enable the Aux Port without user intervention.
Page 644 The card format corresponding to the Lenel64 custom format must be 64 bits long. The issue code start bit should be 56, and the number of bits should be 8. Bits 0 through 55 can be configured in any way you choose. The recommended format is Lenel 64-bit Wiegand (0/8, 8/ 48, 56/8).
Page 645 If you are using Pass-Thru Format, the Wiegand tab must be configured as follows: Note: The ID bits defined in VeriAdmin correspond to the template ID (which is not utilized by the access control software), and not the OnGuard badge ID. revision 7 —...
Page 646 – Change the Global Security Threshold to Very High. Note: If a level of security is defined in OnGuard other than “Very High,” it will override this reader configuration. – Make sure that the Biometric Verification is Enabled, and that Finger Required (under Template Security) is selected.
Page 647 Hardware Installation Guide 116.3.11 Card Format Configuration Once the reader has been configured using the VeriAdmin software, exit the program. You will then need to set up card format and encoding for the V-Smart using the access control software. For more information, please refer to the System Administration User Guide.
Page 648 Biometric Readers Select the reader Type: – For LNL-1300: Select LNL-1300 (Single Interface). – For LNL-1320: Select LNL-1320 (Dual Interface). Select “Bioscrypt RS-485” as the reader Output. (Alternate Reader is automatically enabled.) Select the Port from the access panel that the LNL-1300/1320 is connected to. For LNL-1320 (Dual Interface) readers: Select a Reader number.
Page 649 Hardware Installation Guide Wiring diagram of V-StationA (G/H) to the reader interface module Dual Reader Interface Module CLK/D1 DAT/D0 Ethernet RS-485 Host RS-485 Host RS-232 RJ-45 Switch RJ-45 RJ-11 RS-485 RS-232 WIEGAND 12VDC + Back of V-Station Unit V-StationA-G and V-StationA-H Configuration In order for the V-Station readers to function properly, the firmware must be version 7.61 or later.
Page 650 Biometric Readers Enable the port using the Unit Parameter Settings window. The settings will be different for enrollment readers and verification readers. The General tab displays the product, firmware, communication, and template information for the current reader. On the Communication tab, select Enable Port. The settings for an enrollment reader are shown below.
Page 651 – Select the Pre-Defined Format radio button. – In the format drop-down list, select Lenel64. This custom format can be found on the OnGuard Supplemental disc. Click [Upload Custom Format] and navigate to the Lenel64.wgf file to select it. The card format corresponding to the Lenel64 custom format must be 64 bits long. The issue code start bit should be 56, and the number of bits should be 8.
Page 652 Biometric Readers If you are using Pass-Thru Format, the Wiegand tab must be configured as follows: 652 — revision 7...
Page 653 – Change the Global Security Threshold to Very High. Note: If a level of security is defined in OnGuard other than “Very High,” it will override this reader configuration. – Make sure that the Biometric Verification is Enabled, and that Finger Required (under Template Security) is selected.
Page 654 Password Verification: Enabled For MV1610 (3G) devices that are connected to biometric gateway or reader interface modules and configured as Bioscrypt RS-485 readers in the OnGuard software, enable PIN capability by doing the following: In the Unit Parameters, under the Misc. tab –...
Page 655 Hardware Installation Guide 116.3.17 PIV-Station The average reader current draw is 0.50 amps at 12 VDC with a maximum draw of 1.00 amp at 12 VDC. General power requirements: +12.5 to 24 VDC. This reader cannot be powered from a reader interface module reader port.
Page 656 Biometric Readers Wiring diagram of the reader and dual reader interface module WIEGAND Dual Reader Interface Module 12-24 VDC Power Supply Out 1 CLK/D1 Out 0 DATA/D0 TYPICAL SOFTWARE SETTINGS 1. Reader Type = Depends on Card Format 2. Keypad = None (keypad is not controlled by the software) 3.
Page 657 Hardware Installation Guide • FASC-N 75 MSB Low Assurance Wiegand Output If you are using FASC-N 75 MSB Low Assurance Wiegand Output, in the access control software, for the Reader Type, select Wiegand/Prox. • FASC-N 200 MSB Low Assurance Wiegand Output If you are using FASC-N 200 MSB Low Assurance Wiegand Output, in the access control software, for the Reader Type, select Mag w/ Wiegand Output.
Page 658 Biometric Readers 658 — revision 7...
Page 659: Lnl-500W Wireless Gateway Interface
LNL-500W WIRELESS GATEWAY INTERFACE...
Page 661: Overview Of Wireless Reader Interfaces
PIM (panel interface module) supports up to 16 Schlage Wireless readers or locks in many combinations. The gateway can be used with any address. When configuring the reader in the OnGuard software, a unique reader number will be specified according to the port and address of the gateway. The first reader MUST always be present and be identified as reader number 0.
Page 662: Installation Of The Gateway
LNL-500W Wireless Gateway Interface Installation of the Gateway To install the gateway, perform the installation procedures described in the following sections, in the order in which they are presented. Wire the upstream host communication. Wire the power input. Wire the downstream device communication. Cycle power to the device.
Page 663 Hardware Installation Guide no longer than 4000 feet (1219 m), 100 ohms maximum (Belden 9842 4-wire or 9841 2-wire, plenum cabling Belden 88102, West Penn, or equivalent.) The drop cables (to readers and other devices) should be kept as short as possible, no longer than 10 feet. RS-485 Communications The (EIA) Electronic Industries Association standard defines RS-485 as an electrical interface for multiport communications on a bus transmission line.
Page 664 LNL-500W Wireless Gateway Interface Wire Configuration – DIP switch 5 is used for Flow Control. Switch 5 must be OFF for all ISCs in this configuration. 118.1.3 Power The wireless reader gateway accepts either a 12 VDC or 12 VAC ± 15% power source for its power input. The power source should be located as close to the wireless reader gateway as possible.
Page 665 Hardware Installation Guide Notes: Make sure you connect from TR2+ to TA- and from TR2- to TB+. This reversed polarity wiring is different from other panel types. Jumpers 19 & 20 must be ON. Termination The typical recommendation calls for termination at each end of the line. The link between the LNL-500W and the Schlage Wireless devices is fairly short.
Page 666: Configuration
LNL-500W Wireless Gateway Interface Configuration The wireless reader gateway board contains 8 DIP switches and 11 jumpers that must be configured for your system. 119.1 Setting DIP Switches The following chart describes the use of each DIP switch. DIP SWITCH USED TO CONFIGURE: 1, 2, 3, 4, 5 Interface address...
Page 667 Hardware Installation Guide ADDRESS DIP SWITCH 119.1.2 Upstream Communication Baud Rate To configure the communication baud rate, set DIP switches 6 and 7 according to the following table. This feature controls the baud rate for upstream communication. BAUD RATE DIP SWITCH 38400 bps 19200 bps 9600 bps...
Page 668: Installing Jumpers
LNL-500W Wireless Gateway Interface 119.1.3 Downstream Baud Rate DIP switch 8 controls the downstream baud rate. DIP SWITCH 8: Baud rate 9600 bps not supported 119.2 Installing Jumpers The following diagram describes the use of each jumper on the board. The jumper is indicated by brackets [ ].
Page 669: Use With The Lnl-2020W
Hardware Installation Guide 119.4 Use with the LNL-2020W To use a WRI with the LNL-2020W and a wireless reader, the LNL-2020W must be set to format 3 (DIP switches 3 and 4 are turned on). In System Administration, configure the reader as “Mag with Wiegand Output”.
Page 670: Specifications
LNL-500W Wireless Gateway Interface Specifications The LNL-500W is for use in low voltage, class 2 circuits only. • Primary Power: (DC or AC) DC input: 12 VDC ± 10%. 250 mA AC input: 12 VAC ± 15%. 400 mA RMS •...
Page 671: Command Keypad
COMMAND KEYPAD...
Page 673: Lnl-Ck Command Keypad Overview
The LNL-CK command keypad integrates a 32-character back-lit LCD display with a 16-position keypad and a reader port. It serves as a command reader, with programming being accomplished using the OnGuard software. This device features time display (in either 12-hour or 24-hour clock format, based on the Windows setting of the Communications Server) and text feedback during reader operations.
Page 674 Command Keypad 121.1.1 Command Keypad as a Stand-alone Device The command keypad can be installed as a stand-alone device. It can be connected via RS-485 and may be used to execute command programming (*4-15#) or the extended held open command. With the optional reader connected, all reader modes are supported.
Page 675 Hardware Installation Guide 121.1.2 Command Keypad as an Alternate Reader Device The command keypad can be connected via RS-485 and used as an alternate reader device along with a primary reader (associated with a single/dual reader interface module) for door inputs and outputs from the primary reader interface device.
Page 676 Connect to a separate +12 VDC power supply Configuration in OnGuard Configuring the command keypad as an alternate reader device in OnGuard requires adding two LNL-1300 or LNL-1320 reader interface modules, one as the primary reader and the other as the alternate reader. The alternate reader will use the command keypad.
Page 677 Hardware Installation Guide Communication: Set to RS-485. Baud Rate: Set to 9600 bps. Note: If the command keypad is connected to the downstream reader interface module, set the baud rate to 9600 bps. If the command keypad is connected directly to the controller, set the baud rate to 38400 bps.
Page 678 Command Keypad 121.1.3 Command Keypad as a Primary Reader Device The command keypad can be connected as a primary reader device on the reader interface module along with any type of alternate reader (for example, a biometric device). The command keypad will support all reader modes.
Page 679 Connect to a separate +12 VDC power supply Configuration in OnGuard Configuring the command keypad as an primary reader device for another alternate reader in OnGuard requires adding two LNL-1300 or LNL-1320 reader interface modules, one as the primary reader and the other as a SIM/DIM alternate reader.
Page 680: Hardware Revision And Firmware
Command Keypad Configuration at the Command Keypad Use the Setup mode in the command keypad to make the following configuration settings. For more information, refer to Command Keypad Configuration on page 684. Disconnect and then reconnect the +12 VDC power. When the screen displays “Press two keys for Setup,”...
Page 681: Wiring The Command Keypad
Hardware Installation Guide • Controller firmware 1.194 or later for the LNL-2210, LNL-2220, or LNL-3300; or controller firmware 3.099 or higher for the LNL-500, LNL-1000, or LNL-2000. 121.3 Wiring the Command Keypad When plugging the connector into the pin block, line up the red wire with pin #1 and the black wire with pin #14 (as marked on the back of the board).
Page 682 Command Keypad Use the following table to connect the wires properly. 121.3.1 Command Keypad Power The command keypad requires 12 VDC ± 15% for power. The power source must be regulated and isolated. Wires connected to pins 1-2 are for power. Color Signal 12 VDC IN...
Page 683: Dip Switches
Hardware Installation Guide Color Signal Gray DAT D0 Connect to a separate +12 VDC power supply The command keypad should use the following settings, which are available from the keypad configuration menu (see Command Keypad Configuration, on page for details.) •...
Page 684: Jumpers
Command Keypad Proper termination is required for proper operation. If the command keypad is the first or last device on the RS-485 bus, DIP switch 1 should be ON. Set DIP switch 3 to the ON position to disable the ability to use to keypad for changing the configuration during power-up.
Page 685: Status Display
121.8 OnGuard Configuration 121.8.1 Reader Type When connecting the command keypad using RS-485, OnGuard allows for three possible choices to select for the reader type: • RS-485 Command Keypad (LNL-1300T). The LNL-1300T is no longer available for sale. This selection is available in the software for legacy support.
Page 686: Command Programming
Command Keypad All door inputs (aux inputs, REX, door contact) and door outputs (aux outputs, strike) are controlled by reader interface module. 121.8.2 Text Display Options The text displayed on the command keypad is configurable through the access control software. The display may include the time, status of default area, or any user definable text strings.
Page 687: Command Keypad Behavior
When there is an access attempt awaiting biometric data, “Enter Biometric” is displayed on line 1 in version 5.10.419. Or, if you are using a previous version of the OnGuard software, “Biometric Test” is displayed instead. This state only exists when using controller firmware 3.050 or later.
Page 688 Command Keypad 121.10.2 Alarm Mask Groups The control of alarm mask groups is accessible through command keypad devices. The command will allow a user to arm/disarm an alarm mask group from the keypad with visual feedback on the LCD. To issue the command, you must receive a valid access grant at the reader and also have arm/disarm command authority.
Page 689: Specifications
Hardware Installation Guide • Any Alarm Mask Group Intrusion Commands Mask group ID from 00 to 99 must be appended to the command. Arm the specified area. Force-arm the specified area (auto-bypass) Disarm the specified area. View faulted zones in the specified area. •...
Page 690 Command Keypad 690 — revision 7...
Page 691: Index
Hardware Installation Guide Index Communication handshake status intelligent system controller (1000)..... 87 Alarm inputs intelligent system controller (500)....70 intelligent dual reader controller Communication password status (2220) ........132, 158 intelligent system controller (1000)..... 87 intelligent dual reader controller (4420) ..196 intelligent system controller (2000)...
Page 692 Index output control module........ 308 single door controller module (1300-U) ..398 single door IP interface module (1300e) ... 369 single door IP interface module (1300e) ... 372 star multiplexer .......... 458 single reader interface module....346 wireless reader gateway......666 Embedded authentication web Downstream configuration (4420) ........
Page 693 Hardware Installation Guide input wiring..........290 jumpers ............88 installation ..........282 maintenance ..........91 jumpers ............285 memory expansion........89 mounting ............ 288 overview ............77 overview ............ 281 password status ..........87 power ............295 power ............85 relay outputs..........
Page 694 (1300-U) ..389 power ............68 single reader interface module....336 processor address ......... 69 star multiplexer .......... 454 specifications ..........73 Lenel keypads ........... 531 status,verification......... 72 Lenel opencard unsupervised alarm inputs ......63 readers............537 upstream host communication ..... 63 XF100D,XF2100D,XF2110D ....
Page 695 Hardware Installation Guide LPLRIN installation kit ........526 DIP switches ..........308 elevator control .......... 306 installation ..........304 interfaces............ 301 Magnetic card access reader jumpers ............311 configuration........466, 481 overview ............ 301 DIP switches ........466, 482 power ............306 grounding..........
Page 696 Index intelligent system controller (2000)... 104 public DHCP addressing ......369 intelligent system controller (500)....69 reader wiring..........359 relay circuit wiring........366 static IP addressing ........370 System Administration configuration of ... 371 Read range ............495 wiring and setup......... 357 Reader verification single door IP interface module (1300e) magnetic card access reader.......
Page 697 Hardware Installation Guide Troubleshooting ..........222 jumpers ............668 TTL interface ........... 466, 483 overview ............ 661 power ............664 specifications ..........670 unsupervised alarm inputs ......662 U.S. robotics modem ........250 upstream host communication ....662 UDS-10 ............. 234 wiring............
Page 698 UTC Fire & Security Americas Corporation, Inc. 1212 Pittsford-Victor Road Pittsford, New York 14534 USA Tel 866.788.5095 Fax 585.248.9185 www.lenel.com docfeedback@lenel.com...

Lenel OnGuard Hardware Installation Manual

1 Inputs, Outputs and Interface Signals

2 System Wiring and Other Considerations

3 System Turn-Up Considerations

4 Maintenance

5 UL/ULC Certified Installations

6 EN Certified Readers

7 Troubleshooting

8 Overview of the LNL-500

9 Installation

10 Configuration

11 Maintenance

12 Specifications

13 Overview of the LNL-1000

14 Installation

15 Configuration

16 Maintenance

17 Specifications

18 Overview of the LNL-2000

19 Installation

20 Configuration

21 Maintenance

22 Specifications

23 Overview of the LNL-2210

24 Installation

25 Maintenance

26 UL Listed Installations

27 Specification

28 Overview of the LNL-2220

29 Installation

30 Maintenance

31 Specifications

32 Overview of the LNL-3300

33 Installation

34 Maintenance

35 Specifications

36 Overview of the LNL-4420

37 Installation

38 Maintenance

39 UL 294 Installations

40 Specifications

41 ISC Communication

42 Overview of the LNL-1100

43 Installation

44 Configuration

45 Specifications

46 Overview of the LNL-1100-U Board

47 Installation

48 Configuration

49 Mounting

50 Wiring

51 Specifications

52 Overview of the LNL-1200

53 Installation

54 Configuration

55 Specifications

56 Overview of the LNL-1200-U Board

57 Installation

58 Configuration

59 Mounting

60 Wiring

61 Specifications

62 Overview of the LNL-1300

63 Installation

64 Configuration

65 Specifications

66 Overview of the LNL-1300E

67 Installation

68 Configure Network Address to LNL- 1300E

69 Elevator Control

70 Additional Mounting Information

71 Maintenance

72 UL Listed Installations

73 Specification

74 Overview of the LNL-1300-U Board

75 Installation

76 Configuration

77 Mounting

78 Wiring

79 Specifications