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JYTEK JY-5500 Series Spec And Manual

Family of multi-functional data acquisition boards
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JY-5500 Series
Family of Multi-functional
Data Acquisition Boards
Spec and Manual
Specs and Manual Version: V2.5.6
Revision Date: July 29, 2024

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Summary of Contents for JYTEK JY-5500 Series

  • Page 1 JY-5500 Series Family of Multi-functional Data Acquisition Boards Spec and Manual Specs and Manual Version: V2.5.6 Revision Date: July 29, 2024...

  • Page 2: Main Features

    1. JY-5500 Specifications Overview The JY-5500 Series is a family of multifunction data acquisition boards, which can run on PCIe, PXIe, (Thunderbolt) buses.Depending on the model number, a JY- 5500 series provide different AI channels, AO channels, sampling rate.USB 5500 Series only supports USB 3.0 bus mode.

  • Page 3: Hardware Specifications

    Hardware Specifications 1.3.1 Analog Input Specifications Table 1 Analog Input Specifications 1.3.2 AI Absolute Accuracy...
  • Page 4 Basic DC AI Accuracy, DAQ Mode Table 2 Basic DC AI Accuracy, DAQ Mode Additional DC AI Accuracy Adjustment, DAQ Mode Table 3 JY-5500 Temperature Accuracy Adjustment...
  • Page 5 Table 4 JY-5500 Muti-Channel Accuracy Adjustment...
  • Page 6 Basic DC AI Accuracy, DS Mode Table 5 Basic DC AI Accuracy, DS Mode System Noise Range SystemNoise(uVrms) Table 6 DC System Noise...

  • Page 7: Dynamic Performance

    AC Accuracy for One Channel JY5500 Total Absolute AC Accuracy for One Channel 0.1V 0.2V 0.5V [10Hz,50K) 0.28% 0.24% 0.23% 0.22% 0.17% 0.16% 0.15% [50K,100K) 0.79% 0.66% 0.57% 0.74% 0.48% 0.39% 0.38% [100K,200K] 2.42% 2.09% 1.90% 2.12% 1.28% 1.00% 1.00% Valid for one channel measurement of sinusoidal input 90 days, Tcal±5ºC.

  • Page 8: Analog Output Specifications

    CMRR Input CMRR (DC-60Hz) Voltage (db) Table 9 CMRR Crosstalk The crosstalk is the interference from one channel wire to another channel wire. It depends on the connection wires and internal circuit layout. In JY-5500, each differential channel has three wires, AI+, AI-, and GND. The two wires, AI+ and AI-, are interwound together.

  • Page 9: Ao Absolute Accuracy

    Table 11 Analog Output Specifications 1.3.5 AO Absolute Accuracy Basic AO Accuracy Table 12 AO Absolute Accuracy...

  • Page 10: Digital Io Specifications

    Additional Accuracy AO Adjustment Table 13 Additional Accuracy AO Adjustment 1.3.6 Digital IO Specifications Table 14 Digital IO Specifications 1.3.7 Counter/Timer Specifications CI/CO 5510 5511 5515 5516 Number of channels Resolution edge count,period measurement,frequency measurement, pulse width measurement,two-edge interval measurement, orthogonal coding, etc.

  • Page 11: Clock Accuracy

    1.3.8 Clock Accuracy Clock Accuracy (5510 5511 5515 5516) ±20 ppm Table 16 Clock Accuracy 1.3.9 PFI Specifications Table 17 PFI Specifications 1.3.10 Power Specifications Table 18 Power Specifications 1.3.11 USB Power Supply Power USB-5510 USB-5511 USB-5515 USB-5516 Table 19 USB Power Supply 1.3.12 Physical and Environment Operating Environment Table 20 Operating Environment...

  • Page 12: Order Information

    2. Order Information ⚫ PXIe-5510 (PN: JY2005510-01)) 32-ch AI (18-Bit, 2 MS/s), 4-ch AO (16-Bit, 2.86MS/s), 48 DIO, PXIe Multifunction I/O Card ⚫ PXIe-5511 (PN: JY2005511-01) 32-ch AI (18-Bit, 1.25 MS/s), 4-ch AO (16-Bit, 2.86 MS/s), 48 DIO, PXIe Multifunction I/O Card ⚫...

  • Page 13: Table Of Contents

    Table of Contents 1.JY-5500 Specifications ..................1 Overview ......................1 Main Features ....................1 Hardware Specifications .................. 2 1.3.1 Analog Input Specifications..............2 1.3.2 AI Absolute Accuracy ................2 1.3.3 Dynamic Performance ................6 1.3.4 Analog Output Specifications..............7 1.3.5 AO Absolute Accuracy ................8 1.3.6 Digital IO Specifications ................
  • Page 14 C# Programming Language ................26 JY-5500 Series Hardware Driver ..............26 Install the SeeSharpTools from JYTEK ............26 Running C# Programs in Linux ............... 27 6.Operating JY-5500 ..................... 28 Quick Start ...................... 28 Data Acquisition Methods ................28 6.2.1 Continuous Acquisition ............... 31 6.2.2 Finite Acquisition ................
  • Page 15 9.About JYTEK ....................104 JYTEK China ....................104 JYTEK Software Platform ................104 JYTEK Warranty and Support Services ............104 10.Appendix 1 Common Analog Measurement Issues ......... 105 Floating Signals and Ground Referenced Signals ........105 Differential, NRSE, RSE Modes ..............105 Reducing the Common Mode Voltage Effect ..........
  • Page 16 Table 18 Power Specifications ................10 Table 19 USB Power Supply ................. 10 Table 20 Operating Environment ................. 10 Table 21 Storage Environment ................10 Table 22 JY-5500 Family and Main Features ............8 Table 23 JY-5500 on Different Bus ................. 8 Table 24 5510 / 5511 Pin Definition ..............
  • Page 17 Figure 17 Rising Slope Trigger ................40 Figure 18 Falling Slope Trigger ................40 Figure 19 Hysteresis with Rising Slope Trigger ............ 41 Figure 20 Hysteresis with Falling Slope Trigger ........... 41 Figure 21 Entering Window Trigger ..............42 Figure 22 Leaving Window Trigger ..............42 Figure 23 Analog Trigger Paraments ..............
  • Page 18 Figure 58 Buffered Edge Counting with Internal Sample Clock ......66 Figure 59 Simple Edge Counting with Implicit SampleClk ........67 Figure 60 Count Direction ..................67 Figure 61 EdgeCounting For Single Mode ............68 Figure 62 EdgeCounting For Finite Mode ............69 Figure 63 Counter Values For Internal Clock ............
  • Page 19 Figure 99 Finite Pulse Output ................96 Figure 100 Finite Pulses Generation ..............96 Figure 101 AI Acquisition Finite Pulse ..............97 Figure 102 Continuous Pulse Output ..............98 Figure 103 Continuous Pulse Generation ............98 Figure 104 AI Acquisition Continuous Pulse ............99 Figure 105 SSI Connector in PCIe-5500 ..............

  • Page 20: Introduction

    Microsoft Visual Studio and C# programming language. Overview The JY-5500 Series is a family of multifunction data acquisition boards, which can run on PCIe, PXIe, TXI(Thunderbolt) and USB buses. Depending on the model number, a JY-5500 series provide different AI channels, AO channels, sampling rate as shown in Table 22.

  • Page 21: Learn By Example

    ⚫ DAQ Mode: Common Data Acquisition Mode ⚫ DS Mode: Digital Signal Processing Mode Learn by Example JYTEK has added Learn by Example in this manual. We provide many sample programs for this device. Please download the sample programs for this device. You can download a JYPEDIA excel file from our web www.jytek.com.
  • Page 22 The TB-68 has 4 terminal columns, J1 – J4 and is shown below as Figure 3. In the rest of this manual, the wire connection in each Learn by Example section will be given by the pin numbers only. Figure 3 TB-68 Terminal Block JY-5500 Series V2.5.2| jytek.com | 10...
  • Page 23 Tip: JY-5500 also has the analog output capability. If you do not have a signal source, you can use the outputs of JY-5500 as the signal source. In this case you need first run example program Analog Output-->Winform AO Continuous Wrapping Multichannel to generate the output. JY-5500 Series V2.5.2| jytek.com | 11...

  • Page 24: Hardware Specifications

    Front Panel Figure 4 PXIe/PCIe 5510 Front Panel JY-5500 series boards are connected to outside signals by either two 68-pin cables for the 32 channel configurations or one 68-pin cable for 16 channel configurations. Table 24, Table 25, Table 26, Table 27 show the pin definitions for 32 channels and 16 channels of JY-5500 series boards respectively.

  • Page 25: Pin Definition

    67 AI_GND 33 AI 17(AI 17+) 67 AI_GND 34 AI 8(AI 0-) 68 AI 0(AI 0+) 34 AI 24(AI 16-) 68 AI 16(AI 16+) Table 24 5510 / 5511 Pin Definition * NC: Not Connected JY-5500 Series V2.5.2| jytek.com | 13...

  • Page 26: 5510/5511 Counter Pin Definition (Connector 0)

    4.2.2 5510/5511 Counter Pin Definition (Connector 0) Signal Name Signal Name CTR0_Source/A CTR1_Source/A CTR0_Gate/Z CTR1_Gate/Z CTR0_AUX/B CTR1_AUX/B CTR0_ OUT CTR1_ OUT CTR2_Source/A CTR3_Source/A CTR2_Gate/Z CTR3_Gate/Z CTR2_AUX/B CTR3_AUX/B CTR2_ OUT CTR3_ OUT Table 25 5510 / 5511 Counter Pin Define JY-5500 Series V2.5.2| jytek.com | 14...

  • Page 27: 5515/5516 Connector Pin Definition

    AI 3(AI 3+) AI_GND AI10(AI 2-) AI 2(AI 2+) AI_GND AI 9(AI 1-) AI 1(AI 1+) AI_GND AI 8(AI 0-) AI 0(AI 0+) Table 26 5515 / 5516 Pin Definition * NC: Not Connected JY-5500 Series V2.5.2| jytek.com | 15...

  • Page 28: 5515/5516 Counter Pin Definition

    Di gi ta l Si gna l Reference Ground P<0..3>.<0..7> Di gi ta l I/O Cha nnel PFI<0..15> Progra mma bl e Functi on Interfa ce +5V_OUT 5V power s uppl y Table 28 Notes to Legend JY-5500 Series V2.5.2| jytek.com | 16...

  • Page 29: Ai Absolute Dc Accuracy

    2MHz sample rate. You can use this number for other calibration columns. But if you have other sample rate or the temperature or multiple- channel adjustment, you should use ���������� ������������������ �� = �� �� 10 ∗ ���������� JY-5500 Series V2.5.2| jytek.com | 17...

  • Page 30: Temperature Adjustment

    Max input freqency = (total accuracy/range)*Sample Rate/10, only 24 Hr. data provided All accuracy data in this table are tested with 1m shield cable. Specs subject to minor changes Table 29 Basic Accuracy in DAQ Mode 4.3.2 Temperature Adjustment JY-5500 Series V2.5.2| jytek.com | 18...

  • Page 31: Multi-Channel Adjustment

    Because JY-5500’s 32 channels share one ADC, the channel sample rate of each channel is dedermined by ChannelSample Rate = Sample Rate/N JY-5500 Series V2.5.2| jytek.com | 19...
  • Page 32 DC measurements. Please refer to 10.4 for details. The source impedence, cable length and terminal block also affect the accuracy adjustment. Table 31. uses a 25Ωimpedence source, a JYTEK 2-meter cable and TB68 terminal block. The accuracy adjustment for the longer cable length and larger soure impedence have not been tested.

  • Page 33: Basic Dc Accuracy, Ds Mode

    In the DS Mode, these boards use the onboard FPGA processing to reduce the noise effect and to improve the AI accuracy. The FPGA processing uses more sample points and will reduce the overall sample rates. For each range, the processing can be JY-5500 Series V2.5.2| jytek.com | 21...

  • Page 34: Ai Absolute Ac Accuracy

    Table 33 gives the total AC accuracy specification for JY-5500. It is for one channel only. There is no AC accuracy specification when the sinusoidal input is greater than 200KHz. The reason is we need at least 5 sample points per cycle to calculate a time domain sinusoidal waveform. JY-5500 Series V2.5.2| jytek.com | 22...

  • Page 35: Ao Absolute Accuracy

    AO Absolute Accuracy 4.5.1 Basic AO Accuracy The AO output accuracy of JY-5500 Series when using the analog output function can be calculated according to the corresponding parameters in the following table Each entry in the basic accuracy table is a pair of gain and offset coefficients. Using...

  • Page 36: Additional Ao Accuracy Adjustment

    24 Hour Tcal±1ºC range, the basic accuracy entry (0.003%, 0.006%) must be adjusted to (0.003%+0.0025%*2, 0.006%+0.0008%*2) = (0.008%, 0.0076%). The accuracy of the same 2V output value is ± ( 0.008% ∗ 2 + 0.0076% ∗ 5 ) = ±0.00054V = ±540uV JY-5500 Series V2.5.2| jytek.com | 24...

  • Page 37: Software

    Microsoft Windows: Windows 7 32/64 bit, Windows 10 32/64 bit. Linux Kernel Versions: There are many Linux versions. It is not possible JYTEK can support and test our devices under all different Linux versions. JYTEK will at the best support the following Linux versions.

  • Page 38: C# Programming Language

    Once you get yourself familiar with how one JYTEK DAQ card works, you should be able to know how to use all other DAQ hardware by using the same methods.

  • Page 39: Running C# Programs In Linux

    If you want to use your own Linux development system other than MonoDevelop, you can do it by using our Linux driver. However, JYTEK does not have the capability to support the Linux applications. JYTEK completely relies upon Microsoft to maintain the cross-platform compatibility between Windows and Linux using MonoDevelop.

  • Page 40: Operating Jy-5500

    This chapter provides the operation guides for JY-5500, including AI, AO, DI, DO, Timer and programmable I/O interface, etc. JYTEK provides extensive examples, on-line help and documentation to assist you to operate the JY-5500 board. JYTEK strongly recommends you go through these examples before writing your own application.
  • Page 41 ◼ Set a sinewave signal (f=4Hz, Vpp=5V) and a squarewave signal (f=4Hz, Vpp=5V). ◼ Open Analog Input-->Winform AI Continuous MultiChannel, set the following numbers as shown. This sample program will continuously acquire data from multiple channels. JY-5500 Series V2.5.2| jytek.com | 29...
  • Page 42 The continuous mode will acquire blocks after blocks until Stop button is pressed. ◼ When start is clicked, it generates a software trigger, which starts the acquisition. The result is shown below. Figure 8 MultiChannel Continuous Acquisition JY-5500 Series V2.5.2| jytek.com | 30...

  • Page 43: Continuous Acquisition

    However, to acquire one input signal, two AI channels are required to form the differential pair. The RSE and NRSE are recommended when the input signal sources are floating signals. In RSE and NRSE JY-5500 Series V2.5.2| jytek.com | 31...

  • Page 44: Diff Mode

    AI Ch1 negative (AI1-, Pin#66) as shown in Figure 2 and Figure 3. (AI0+, AI0-) and (AI1+, AI1-) consist of two pairs of DIFF inputs; ◼ Choose Differential in AI Terminal; ◼ Set other numbers as shown and click start. JY-5500 Series V2.5.2| jytek.com | 32...
  • Page 45 Figure 10 Choose Differential In AI Terminal JY-5500 Series V2.5.2| jytek.com | 33...

  • Page 46: Rse Mode

    The JY-5500is also designed to better reject the common mode noise than the RSE mode. Therefore the NRSE model still offers twice many channels as the DIFF mode. Please see Appendix 1 Common Analog Measurement Issues for more explainations. JY-5500 Series V2.5.2| jytek.com | 34...
  • Page 47 (Pin#62) of the second TB-68 as shown in Figure 2 and Figure 3. (AI0+, AI_SENSE 0) and (AI1+, AI_SENSE 1) consist of two channels of NRSE inputs. ◼ Choose the NRSE in AI Terminal ◼ Set other numbers as shown and click start. JY-5500 Series V2.5.2| jytek.com | 35...
  • Page 48 Figure 13 Choose NRSE In AI Terminal JY-5500 Series V2.5.2| jytek.com | 36...

  • Page 49: Trigger Source

    ◼ Use the same program and connection as in Learn by Example6.2. Figure 14 Immediate trigger Paraments ➢ With Immediate trigger you can click Start to generate the task instead of sending a trigger signal. JY-5500 Series V2.5.2| jytek.com | 37...

  • Page 50: Software Trigger

    Figure 15 Software trigger Paraments ➢ Data will not be acquired until there is a positive signal from Software Trigger when Send Soft Trigger is clicked. ◼ After sending the trigger signal, the result will be like this: JY-5500 Series V2.5.2| jytek.com | 38...

  • Page 51: External Analog Trigger

    Figure 17. Falling Slope Trigger: The Edge comparator output is high when the signal goes below the threshold; the output is low when the signal goes above the threshold as shown in Figure 18. JY-5500 Series V2.5.2| jytek.com | 39...
  • Page 52 The output will change to low when the signal goes above the high threshold as shown in Figure 20. JY-5500 Series V2.5.2| jytek.com | 40...
  • Page 53 Figure 21. Leaving Window Trigger: The window comparator output is high when the signal leaves the window defined by the Low Threshold and High Threshold. The output will JY-5500 Series V2.5.2| jytek.com | 41...
  • Page 54 (AI_GND, Pin#67) as shown in Figure 2 and Figure 3. (AI0+, AI_GND) consists of a RSE input. ◼ Set a sinewave signal (f=4Hz, Vpp=5V). ◼ Open Analog Input-->Winform AI Continuous Analog Trigger, set the following numbers as shown. JY-5500 Series V2.5.2| jytek.com | 42...
  • Page 55 ➢ According to the rules of Rising mentioned above, the signal acquisition will not start until it raises to 2.0 V, which is set by Threshold above. ◼ Click Start, a message will appear in the lower left corner: Figure 24 Waiting For Trigger JY-5500 Series V2.5.2| jytek.com | 43...

  • Page 56: External Digital Trigger

    Figure 26 Rising Falling Edge Edge Trigger Trigger Figure 26 External Digital Trigger JY-5500 Series V2.5.2| jytek.com | 44...
  • Page 57 Figure 27 Digital Trigger Paraments ➢ Trigger Source must match the pin on 5510. ➢ There are two Trigger Edge: Rising and Falling. ◼ Click Start and the result shows below: JY-5500 Series V2.5.2| jytek.com | 45...

  • Page 58: Trigger Mode

    The JY-5500's analog inputs support several trigger modes: start trigger, reference trigger, and re-trigger. 6.5.1 Start Trigger In this mode, data acquisition begins immediately after the trigger. This trigger mode is suitable for continuous acquisition and finite acquisition. As shown in Figure 29. JY-5500 Series V2.5.2| jytek.com | 46...

  • Page 59: Reference Trigger

    Example ⚫ Total samples: 1000; ⚫ Channel Count: 1 ⚫ Pre-trigger samples: 10; ⚫ After triggering, it returns total 1000 samples, 10 being pre-triggered, 990 after triggering The principle is shown in Figure 30. JY-5500 Series V2.5.2| jytek.com | 47...

  • Page 60: Retrigger

    Figure 30 Reference Trigger 6.5.3 ReTrigger JY-5500 series products support retrigger mode. In the retrigger mode, you can set the number of retrigger and the length of each acquisition. Assuming that the number of re triggers is n and the length of each trigger acquisition is m, the length of all acquisition data is n * m * channelcount.
  • Page 61 Retrigger Count. ➢ PretriggerSamples is set by Pretrigger Samples. ◼ Now the trigger is a Start Trigger. Click Start to begin the data acquisition, the result is shown below: JY-5500 Series V2.5.2| jytek.com | 49...
  • Page 62 ◼ Now change the Trigger Mode to Reference mode with Pretrigger Samples 1000. A different result shows below: Figure 34 Retrigger In Reference Trigger Mode ➢ You can see the horizontal movement between two signals due to the change of Trigger Mode. JY-5500 Series V2.5.2| jytek.com | 50...

  • Page 63: Ao Operations

    RSE input; (AO0, AO_GND) consists of an output. JY-5500 sends an analog signal through (AO0, AO_GND) and reads back the signal from (AI0+, AI_GND). ◼ Open Analog Input-->Winform AI Continuous, set the following numbers as shown. JY-5500 Series V2.5.2| jytek.com | 51...
  • Page 64 Figure 36 AI Continuous Paraments ◼ Click Start to start the data acquisition. ◼ Open Analog Output-->Winform AO Finite, set the following numbers as shown: JY-5500 Series V2.5.2| jytek.com | 52...
  • Page 65 Figure 37 AO Finite Output Paraments ◼ Click Start to generate a SineWave. The generated signal is shown below: Figure 38 AO Finite Signal ◼ And the received signal is shown below. JY-5500 Series V2.5.2| jytek.com | 53...

  • Page 66: Continuous Nowrappping Output

    RSE input; (AO0, AO_GND) consists of an output. ◼ JY-5500 sends an analog signal through (AO0, AO_GND) and reads back the signal from (AI0+, AI_GND). ◼ Open Analog Input-->Winform AI Continuous, set the following numbers as shown. JY-5500 Series V2.5.2| jytek.com | 54...
  • Page 67 Figure 40 AI Continuous Paraments ◼ Click Start to start the data acquisition. ◼ Open Analog Output-->Winform AO Continuous NoWrapping, set the following numbers as shown: JY-5500 Series V2.5.2| jytek.com | 55...
  • Page 68 Waveform Configuration when generating the wave. After the configuration you should click Update to apply the changes. ◼ Click Start to generate a sine wave first. The result is shown below. Figure 42 AO ContinuousNoWrapping Signal JY-5500 Series V2.5.2| jytek.com | 56...
  • Page 69 Figure 43 AI Acquisition AO Sin Signal ◼ Now change the Wave Type to SquareWave and click Update to generate it. The result is shown below. Figure 44 Update AO Square Signal ◼ And the received signal is shown below. JY-5500 Series V2.5.2| jytek.com | 57...

  • Page 70: Continuous Wrapping Output

    RSE input; (AO0, AO_GND) consists of an output. ◼ JY-5500 sends an analog signal through (AO0, AO_GND) and reads back the signal from (AI0+, AI_GND). ◼ Open Analog Input-->Winform AI Continuous, set the following numbers as shown. JY-5500 Series V2.5.2| jytek.com | 58...
  • Page 71 Figure 46 AI Continuous Paraments ◼ Click Start to start the data acquisition. ◼ Open Analog Output-->Winform AO Continuous Wrapping, set the numbers as shown. Figure 47 AO Continuous Wrapping Paraments JY-5500 Series V2.5.2| jytek.com | 59...
  • Page 72 ◼ Click Start to generate the signal. The result is shown below. Figure 48 AO Continuous Wrapping Signal ◼ And the received signal is shown below. Figure 49 AI Acquisition AO Signal ➢ The analog signal is successfully generated and received by JY-5500. JY-5500 Series V2.5.2| jytek.com | 60...

  • Page 73: Digital I/O Operations

    ◼ Select port 1 for Digital Output, Set Line 1,3,5,7 in High-Level positions, make sure all other lines are in Low-Level positions. Click Start to generate the High-Levels as shown. Figure 50 Single Digital Output ◼ Open the second program Digital Input-->Winform DI SinglePoint. JY-5500 Series V2.5.2| jytek.com | 61...

  • Page 74: Dynamic Di/Do

    (P1.0~1.7). JY-5500 sends digital signals through Port 1/Port 0 and reads them back from Port 2/Port 1. ◼ Open Digital Input-->Winform DI Continuous and set the numbers as shown. Select port 2(PCIe/PXIe-5510/5511) or port 1(PCIe/PXIe-5515/5516). JY-5500 Series V2.5.2| jytek.com | 62...
  • Page 75 ◼ Click Start to generate the signal. The result is shown below. Figure 53 DO ContinuousNoWrapping Output ◼ In program Winform DI Continuous, you can see the acquired signal. Select port 1(PCIe/PXIe-5510/5511) or port 0(PCIe/PXIe-5515/5516). JY-5500 Series V2.5.2| jytek.com | 63...
  • Page 76 Figure 54 DI Continuous Acquisition ➢ The digital signal is successfully generated and acquired by JY-5500. JY-5500 Series V2.5.2| jytek.com | 64...

  • Page 77: Counter Input Operations

    For buffered acquisition, each counter has a separate DDR storage space and requires a sample clock. For each counter input application type, the measured signal needs to be connected to different terminals, as shown in the following table. Figure 56 Counter Signal Wiring Instruction JY-5500 Series V2.5.2| jytek.com | 65...

  • Page 78: Edge Counting

    The count value is stored into the buffer on each rising edge or falling edge of the sample clock as shown in Figure 58. Figure 58 Buffered Edge Counting with Internal Sample Clock 3) Finite/Continuous Mode with Implicit Sample Clock JY-5500 Series V2.5.2| jytek.com | 66...
  • Page 79 (CTR0_Source/A, Pin#11), negative terminal to the ground (DGND, Pin#44) as shown in Figure 2 and Figure 3. (CTR0_Source, DGND) consists of an edge counting counter input and they share the same ground. JY-5500 Series V2.5.2| jytek.com | 67...
  • Page 80 ◼ The result is shown by Counter Value. In this example the Counter Value increases by 1 every second for a 1Hz sinewave. Finite/Continuous Mode ◼ Change the squarewave frequency to 50 Hz. ◼ Open Counter Input-->Winform CI Finite/Continuous EdgeCounting, set the following numbers as shown: JY-5500 Series V2.5.2| jytek.com | 68...
  • Page 81 ◼ Click Start to start counting by rising edge. The result is shown below: Figure 63 Counter Values For Internal Clock ➢ The numbers are stored in a buffer CounterValues. ◼ Change the Clock Source to Implicit: JY-5500 Series V2.5.2| jytek.com | 69...
  • Page 82 Figure 64 Counter Values For Implicit Clock ➢ The numbers are stored in a buffer CounterValues. ➢ The counter values are different as before because of the change from Clock Source. JY-5500 Series V2.5.2| jytek.com | 70...

  • Page 83: Pulse Measurement

    The count value of the duration of the high or low level is stored into the buffer on each rising or falling edge of the sample clock, as shown in Figure 66. Figure 66 Pulse Measurement with Internal SampleClk JY-5500 Series V2.5.2| jytek.com | 71...
  • Page 84 ◼ Set a squarewave signal (f=1Hz, Duty Cycle=50%, Vpp=5V). Single Mode ◼ Open Counter Input-->Winform CI Single PulseMeasure, set the following numbers as shown: JY-5500 Series V2.5.2| jytek.com | 72...
  • Page 85 Figure 69 Pulse Measure Value For Single Mode ➢ The numbers show the duration of High/Low Pulse in one signal period and match the duty cycle set before. Finite/Continuous Mode ◼ Change the frequency of Squarewave to 50 Hz. JY-5500 Series V2.5.2| jytek.com | 73...
  • Page 86 ➢ The table in the sample program is a connection diagram for your convenience. ◼ Click Start to begin the finite/continuous pulse measurement. The result is shown below: Figure 71 Pulse Measure Values For Finite Mode JY-5500 Series V2.5.2| jytek.com | 74...

  • Page 87: Frequency Measurement

    (��1) of the signal to measure, and the number of rising edges of timebase (��2) during those full periods. These two values are stored into the buffer on each rising edge of the sample clock, as shown in Figure 72. JY-5500 Series V2.5.2| jytek.com | 75...
  • Page 88 (CTR0_Gate/Z, Pin#10), negative terminal to the ground (DGND, Pin#44) as shown in Figure 2 and Figure 3. (CTR0_Gate/Z, DGND) consists of a frequency measure counter input and they share the same ground. ◼ Set a squarewave signal (f=50Hz, Duty Cycle=50%, Vpp=5V). JY-5500 Series V2.5.2| jytek.com | 76...
  • Page 89 Figure 73 Frequency Measure For Single Mode ➢ The table in the sample program is a connection diagram for your convenience. ➢ The result matches the frequency set before. Finite/Continuous Mode ◼ Open Counter Input-->Winform CI Finite/Continuous Frequency Measure. JY-5500 Series V2.5.2| jytek.com | 77...

  • Page 90: Period Measurement

    ◼ Set a squarewave signal (f=200Hz, Duty Cycle=50%, Vpp=5V). Single Mode ◼ Open Counter Input-->Winform CI Single Period Measure and click Start. The result is shown below by Period Measure(S): JY-5500 Series V2.5.2| jytek.com | 78...
  • Page 91 ➢ The result of Period Measure(S) shows the correspond to the frequency set before. Finite/Continuous Mode ◼ Open Counter Input-->Winform CI Finite/Continuous Period Measure and click Start. The result is shown below by PeriodMeasure (S). JY-5500 Series V2.5.2| jytek.com | 79...

  • Page 92: Two-Edge Separation

    The number of rising edges of timebase between previous rising edge of the second signal and current rising edge of the first signal is written to the register on each rising edge of the first signal as shown in Figure 78. JY-5500 Series V2.5.2| jytek.com | 80...
  • Page 93 3) Finite/Continuous Mode with Implicit Sample Clock The count values of rising edges of timebase between first signal and second signal are stored into buffer on each rising edge of the first signal, as shown in Figure 80. JY-5500 Series V2.5.2| jytek.com | 81...
  • Page 94 ◼ Open Counter Input-->Winform CI Single TwoEdgeSeparation Measure and click Start. The result is shown below by First to Second(S) and Second to First(S), which represent the time difference between the rising edges of the two signals: JY-5500 Series V2.5.2| jytek.com | 82...
  • Page 95 ◼ Open Counter Input-->Winform CI Finite/Continuous TwoEdge Separation Measure and click Start. The result is shown below by First to Second(S) and Second to First(S), which represent the time difference between the rising edges of the two signals: JY-5500 Series V2.5.2| jytek.com | 83...
  • Page 96 Figure 82 Two-EdgeSeparation Measure For Finite Mode ➢ The result in this picture is similar to the result in Single Mode before. ➢ The table in the sample program is a connection diagram for your convenience. JY-5500 Series V2.5.2| jytek.com | 84...

  • Page 97: Quadrature Encoder

    When A leads B, the increase of count occurs on the rising and falling edges of A and B. When B leads A, the decrease in count occurs on the rising and falling edges of A and B. As shown in Figure 85. JY-5500 Series V2.5.2| jytek.com | 85...
  • Page 98 2) Finite/Continuous Mode with Internal Sample Clock The count value is stored into the buffer on each rising edge of the sample clock, as shown in Figure 86. Figure 86 Quadrature Encoder x1 with Sample Clock JY-5500 Series V2.5.2| jytek.com | 86...
  • Page 99 ◼ Set a sqaurewave signal (f=10Hz, Phase=90°) and a squarewave signal (f=10Hz, Phase=0°). Single Mode ◼ Open Counter Input--> Winform CI Single QuadEncoder and click Start. The result is shown below by CounterValue according to the counting rules explained in 6.8.6: JY-5500 Series V2.5.2| jytek.com | 87...
  • Page 100 CounterValue is twice and four times than x1Mode. Continuous Mode ◼ Open Counter Input--> Winform CI Continuous QuadEncoder and click Start. The result is shown below by CounterValues. Figure 89 QuadEncoder For Continuous Mode JY-5500 Series V2.5.2| jytek.com | 88...

  • Page 101: Two-Pulse Encoder

    Figure 90 Two-Pulse Encoder in Single Mode 2) Finite/Continuous Mode with Internal Sample Clock The count value is stored into the buffer on each rising edge of the sample clock, as shown in Figure 91. JY-5500 Series V2.5.2| jytek.com | 89...
  • Page 102 ◼ Connect the signal source’s two positive terminals to PCIe-5510 first signal input (squarewave, CTR0_Source/A, Pin #11) and second signal input (squarewave, CTR0_AUX/B, Pin#43), two negative terminals to the ground (DGND, Pin#44) and (D_GND, Pin#9) as shown in Figure 2 and Figure 3. JY-5500 Series V2.5.2| jytek.com | 90...
  • Page 103 Value, which follows the counting rules explained in this chapter. Finite Mode ◼ Change the frequency of the second channel squarewave from 50Hz to 120Hz. ◼ Open Counter Input-->Winform CI Finite Two PulseEncoder and set the numbers as shown. JY-5500 Series V2.5.2| jytek.com | 91...
  • Page 104 Continuous Mode ◼ Change the frequency of the second squarewave back to 50 Hz. ◼ Open Counter Input-->Winform CI Continuous Two PulseEncoder and set the numbers as shown. JY-5500 Series V2.5.2| jytek.com | 92...
  • Page 105 ➢ The table in the sample program is a connection diagram for your convenience. ◼ Click Start and you can see a group of rising numbers in CounterValues, which follows the counting rules explained in this chapter. JY-5500 Series V2.5.2| jytek.com | 93...

  • Page 106: Counter Output Operations

    Pin#68). Please note Counter Output and AI Ch0 input share the same ground so only one connection is needed. ◼ Open Counter Output-->Winform CO Single and click Start and set the numbers as follow: JY-5500 Series V2.5.2| jytek.com | 94...
  • Page 107 ◼ Please refer Learn by Example to configure an analog input to receive the signal from Counter Output. ◼ Click Start to generate a single pulse as shown. Figure 98 AI Acquisition Single Pulse JY-5500 Series V2.5.2| jytek.com | 95...

  • Page 108: Finite Pulse Output

    Pin#68). Please note Counter Output and AI Ch0 input share the same ground so only one connection is needed. ◼ Open Counter Output-->Winform CO Finite and click Start and set the numbers as follow: Figure 100 Finite Pulses Generation JY-5500 Series V2.5.2| jytek.com | 96...
  • Page 109 ◼ Please refer Learn by Example to configure an analog input to receive the signal from Counter Output. ◼ Click Start to generate the pulse shown below. Figure 101 AI Acquisition Finite Pulse ➢ According to the picture, the duty cycle is 0.5 as set before. JY-5500 Series V2.5.2| jytek.com | 97...

  • Page 110: Continuous Pulse Output

    Pin#68). Please note Counter Output and AI Ch0 input share the same ground so only one connection is needed. ◼ Open Counter Output-->Winform CO Continuous and click Start and set the numbers as follow: Figure 103 Continuous Pulse Generation JY-5500 Series V2.5.2| jytek.com | 98...
  • Page 111 ➢ The frequency and duty cycle of the pulse are set by Frequency and Duty Cycle. ◼ Change the Duty Cycle to 0.7 for instance. The result is shown below. Figure 104 AI Acquisition Continuous Pulse ➢ According to the picture, the duty cycle is 0.7 as set before. JY-5500 Series V2.5.2| jytek.com | 99...

  • Page 112: System Synchronization Interface(Ssi)For Pcie Modules

    DIP Switch in PCIe-5500 PCIe-5500 series modules have a DIP switch. The card number can be adjusted manually by changing the DIP switch setting, which is used to identify the boards with different slot positions. JY-5500 Series V2.5.2| jytek.com | 100...
  • Page 113 Slot 5 Slot 6 Slot 7 Slot 8 Slot 9 Slot 10 Slot 11 Slot 12 Slot 13 Slot 14 Slot 15 Note: OFF=0/ ON=1 Table 38 Relationship between switch position and slot number JY-5500 Series V2.5.2| jytek.com | 101...

  • Page 114: Calibration

    7. Calibration JY-5500 Series boards are precalibrated before the shipment. We recommend you recalibrate JY-5500 board periodically to ensure the measurement accuracy. A commonly accepted practice is one year. If for any reason, you need to recalibrate your board, please contact JYTEK.

  • Page 115: Using Jy-5500 In Other Software

    JYTEK provides and supports a native Python driver for JY-5500 boards. There are many different versions of Python. JYTEK has only tested in CPython version 3.5.4. There is no guarantee that JYTEK python drivers will work correctly with other versions of Python.

  • Page 116: About Jytek

    9. About JYTEK JYTEK China Founded in June, 2016, JYTEK China is a leading Chinese test & measurement company, providing complete software and hardware products for the test and measurement industry. The company has evolved from re-branding and reselling PXI(e) and DAQ products to a fully-fledged product company.

  • Page 117: Appendix 1 Common Analog Measurement Issues

    Thus, the NRSE mode can handle twice as many channels as the DIFF mode. The three measurement modes and the two types of input signals, floating and ground referenced, form 6 different measurement scenarios as shown in the following. Figure 107 Six Measurement Scenarios JY-5500 Series V2.5.2| jytek.com | 105...

  • Page 118: Reducing The Common Mode Voltage Effect

    As a rule of thumb, R should be 1000 times of the signal source output impedance, roughly 10K to 100KΩ. At this level, R has very little impact on the measurement. Figure 108 Using Resister to Reduce Common Mode Voltage Effect JY-5500 Series V2.5.2| jytek.com | 106...

  • Page 119: Dc, Ac And Dsa Mode

    But inappropriate use of averaging will not reduce the noise effect but introduce the error. Given the Total Accuracy Ɛ, from Sections 4.3.1, 4.3.4, 4.3.4, the maximum source signal frequency f should be bounded by: JY-5500 Series V2.5.2| jytek.com | 107...

  • Page 120: Ac Mode

    Table 31. If you need better accuracy, you should consider using the simultaneous DAQ devices such as JYTEK PXIe-5315. These devices do not use scanning mode. Rather, each channel is serviced by a dedicated ADC to avoid the channel switching error. This ensures better AC accuracy as well as better synchronization.

  • Page 121: Statement

    11. Statement The hardware and software products described in this manual are provided by JYTEK China, or JYTEK in short. This manual provides the product review, quick start, some driver interface explanation for JYTEK JY-5500 Series family of multi-function data acquisition boards.

This manual is also suitable for:

Jy-5510Jy-5511Jy-5515Jy-5516

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