OPTICAL SYSTEMS DESIGN 1 TECHNICAL SUMMARY BRIEF DESCRIPTION 1.1.1 OVERVIEW The OSD2244 is a 5-port Ethernet switch with simple network management designed to operate in tough industrial applications providing real-time redundant performance. It has two 10/100/1000Base- T RJ45 copper ports, two SFP ports for the ring and one SFP port which can be specified by the user for 1000Base-Lx fiber mode or as 1000Base-T RJ45 copper.
OPTICAL SYSTEMS DESIGN TYPICAL CONFIGURATION Figure 1 below indicates a possible set-up for an OSD2244 system. IP Camera IP Camera IP Camera Network Switch Network Switch IP Camera IP Camera Network Switch IP Camera IP Camera FIGURE 1: OSD2244 TYPICAL RING CONFIGURATION...
OPTICAL SYSTEMS DESIGN TECHNICAL SPECIFICATIONS TABLE 1: TECHNICAL SPECIFICATIONS SPECIFICATION PERFORMANCE IEEE802.3ab IEEE802.3u, IEEE802.3i, Base-T Ethernet at 10, 100 or 1000Mbps Electrical Data Interface Electrical Data Connector RJ45 on the two fixed copper ports 1 and 2 and for SFP modules USB 2.0...
OPTICAL SYSTEMS DESIGN OSD2244 FRONT AND REAR PANELS There are two fixed copper ports for 10/100/1000Base-T and three optional SFP ports which can be either copper or fiber on the front panel. The rear panel consists of a 6-way terminal block power connector, 4-Way DIP switch, Type-A USB connector and a Type-B USB connector.
OPTICAL SYSTEMS DESIGN 2 INSTALLATION AND OPERATION INTRODUCTION This section outlines the methods required to install and operate the OSD2244 successfully. It should be studied carefully if damage to the equipment or poor results are to be avoided. This equipment has been fully tested prior to dispatch and is ready for immediate operation. However it is advisable to check for external transportation damage before operation.
OPTICAL SYSTEMS DESIGN 2.2.2 OSD2244 DRAWINGS AND DIMENSIONS The OSD2244 standalone module is designed to be mounted on an even surface and to be secured by means of M4 or smaller screws. The OSD2244 card version is designed to be inserted into a chassis and secured by means of captivated screws.
OPTICAL SYSTEMS DESIGN 2.2.3 POWER SUPPLY CONNECTIONS The OSD2244 card version is powered from the OSD370 or OSD350 chassis. DC power on the OSD2244 card version is connected via the DB9 connector. The card version of the OSD2244 should be fixed into the OSD370 (or OSD350) chassis using the captivated screws. The card can be plugged in or out of the OSD370 (or OSD350) chassis with power on or off.
OPTICAL SYSTEMS DESIGN 2.2.5 USB CONNECTOR The OSD2244 has a USB – Type B connector located on the rear of the unit that is used for Command Line Interface (CLI) from the PC to the OSD2244 via the PC’s USB connector. See section 2.5 for further CLI information.
OPTICAL SYSTEMS DESIGN 2.2.6 PORT ALLOCATION AND LED INDICATORS Port 5 Port 4 Port 3 Port 2 Port 1 Case 1 1 1 1 2 2 2 2 FIGURE 8: PORT/LED 3 3 3 3 4 4 4 4 5 5 5 5...
OPTICAL SYSTEMS DESIGN 2.2.7 CONTROLS The OSD2244 has a 4-way DIP switch to control a number of functions. Table 4 outlines the function of each switch. 4-Way DIP Switch FIGURE 9: OSD2244 CONTROLS Fiber Speed Select Firmware Update Enable ON Position...
OPTICAL SYSTEMS DESIGN 2.2.8 FITTING SFP CONNECTORS Care should be taken when inserting/removing the SFP connectors from SFP port 3,4 and 5 as SFP modules are Electrostatic (ES) sensitive and Electrostatic Discharge (ESD) precautions should be taken when installing. Ensure that the SFP is fully engaged and latched into position.
OPTICAL SYSTEMS DESIGN OSD2244 OPERATION When using the OSD2244 for the first time, check that the unit is in good condition with no visible damage. If a card version is used, insert it in an appropriate slot on the OSD370 or OSD350 chassis and check that the indicators illuminate accordingly on power up (see Table 3).
OPTICAL SYSTEMS DESIGN To connect the OSD2244 in a redundant ring configuration ports 4 and 5 must be used together with fiber SFPs. The non-ring ports (ports 1,2, &3) should be used to connect to your Ethernet devices (eg. Cameras, PLCs, computers, etc.) Figure 13 shows the connection method.
OPTICAL SYSTEMS DESIGN FIRMWARE UPDATES All OSD2244 units will be shipped with the latest firmware already installed. The Type- A USB port is used for any firmware updates. To enable the OSD2244 for firmware updates, switch 4 will need to be toggled to the ‘on’...
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OPTICAL SYSTEMS DESIGN Disable Create desktop shortcut and Show readme and click Finish. • DOC ID: 10108207 PAGE 19 OSD2244 OPERATOR MANUAL...
OPTICAL SYSTEMS DESIGN 2.4.2 INSTALLING USB DRIVER Toggle switch 4 to ‘on’ position (see Figure 10) before unit is powered on. • • Connect USB cable between target unit and PC with FLIP installed. Power the OSD2244 unit and follow steps outlined below;...
OPTICAL SYSTEMS DESIGN DRIVER FOR WINDOWS 7 64bit For 64bit operating systems use directory named win7 driver on CD as destination location for driver file. 2.4.3 UPGRADE FIRMWARE Copy firmware directory from CD to c:\osd as shown below DOC ID: 10108207...
OPTICAL SYSTEMS DESIGN Upgrade Firmware Click the OSD2244RevXX Firmware.bat file supplied on the CD. Note: XX denotes revision number of firmware. The batch file contains a small command to install the firmware. The main command is as follows; batchisp -device at32uc3a1512 -hardware usb -operation erase f memory flash blankcheck loadbuffer c:\osd\firmware\60001701.hex program verify start reset 0...
OPTICAL SYSTEMS DESIGN COMMAND LINE INTERFACE The Command Line Interface (CLI) is a useful tool for checking link status and debugging link connections. To enable the use of CLI the OSD2244 must be connected to a PC with a serial port and an appropriate cable as specified in section 2.2.5.
OPTICAL SYSTEMS DESIGN 2.5.2 COMMAND LINE FUNCTIONS There are a number of command line functions that enables the user to obtain running information of a single OSD2244 unit or the complete topology of the ring/bus network. This section explains the command lines and its functions.
OPTICAL SYSTEMS DESIGN TOPOLOGY CHECK - <tc> Command Line FIGURE 18: TOPOLOGY CHECK In this case, only one OSD2244 is connected to the USB cable. The display indicates the following; No: 1 – Number of units connected on the ring/bus (in this case only one unit) MAC_ADDRESS: 00:26:dc:00:00:6d –...
OPTICAL SYSTEMS DESIGN In the example below there are four OSD2244 connected in a ring configuration. FIGURE 19: TOPOLOGY CHECK No: 4 – Four units connected MAC_ADDRESS:– Displaying all the MAC addresses of the units connected on the ring/bus TOPOLOGY: Ring – Displaying type of connection.
OPTICAL SYSTEMS DESIGN NODE CHECK - <nc> Command Line FIGURE 20: NODE CHECK The Node Check command line is a useful command for checking the running status of any remote node connected to the ring/bus topology from any particular node that the USB cable is plugged into.
OPTICAL SYSTEMS DESIGN LOCAL NODE CHECK - <lnc> Command Line FIGURE 21: LOCAL NODE CHECK This command line displays the running status of the local node that the USB cable is plugged into. The information provided is the MAC address, Topology, Node Role, Port Role and Float Backup status.
OPTICAL SYSTEMS DESIGN FLOAT BACKUP ENABLE <fbe> Command Line FIGURE 22: FLOAT BACKUP ENABLED 1 No: 4 – Lists number of units connected (in this case 1,2,3,4) MAC_ADDRESS:– Displaying all the MAC addresses of the units connected on the ring/bus FLOAT_BACKUP: Enable –...
OPTICAL SYSTEMS DESIGN In Figure 23, node 1 will communicate with node 2, node 3 and node 4 via node 3. Node 2 will communicate to node 4 only via node 1 and 3. In the event of a fiber link being broken or disconnected (indicated by a cross) the backup branch will become the active branch.
OPTICAL SYSTEMS DESIGN FLOAT BACKUP DISABLE - <fbd> Command Line FIGURE 26: FLOAT BACKUP DISABLED 1 No: 4 – Lists number of units connected (in this case 1,2,3,4) MAC_ADDRESS:– Displaying all the MAC addresses of the units connected on the ring/bus FLOAT_BACKUP: Disable –...
OPTICAL SYSTEMS DESIGN In the event of a fiber link being broken or disconnected (indicated by a cross) the backup branch will become the active branch. If the link between node 1 and 3 is broken (see Figure 27) , node 1 will communicate with node 3 via node 2 and node 4.
OPTICAL SYSTEMS DESIGN 3 MAINTENANCE INTRODUCTION The following section outlines the fault-finding procedure for the OSD2244 modems. Please take note of the following: Personnel without appropriate training should not attempt any maintenance except that outlined ▲ below. If further maintenance is attempted you are warned that every care should be taken to ensure that ▲...
For warranty period, please contact your local OSD distributor. REPAIRS Optical Systems Design reserves the right to repair or replace faulty modules/units. Please obtain a “Return Material Authorisation” (RMA) form and number before returning goods. Goods must be returned in adequate packing material to Optical Systems Design, Warriewood or its nominated authorised representative, for all repairs.
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OPTIC L Optical Systems Design Pty. Ltd. 7/1 Vuko Pl. Warriewood 2102 SYSTEMS P.O. Box 891 Mona Vale N.S.W. Australia 2103 Telephone: +61 2 9913 8540 DESIGN Facsimile: +61 2 9913 8735 Email: sales@osd.com.au Web Site: www.osd.com.au PTY LTD A.B.N. 83 003 020 504...