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<body><h1>daq e series user manual</h1><table class="table" border="1" style="width: 60%;"><tbody><tr><td>File Name:</td><td>daq e series user manual.pdf</td></tr><tr><td>Size:</td><td>4677 KB</td></tr><tr><td>Type:</td><td>PDF, ePub, eBook, fb2, mobi, txt, doc, rtf, djvu</td></tr><tr><td>Category:</td><td>Book</td></tr><tr><td>Uploaded</td><td>27 May 2019, 22:43 PM</td></tr><tr><td>Interface</td><td>English</td></tr><tr><td>Rating</td><td>4.6/5 from 649 votes</td></tr><tr><td>Status</td><td>AVAILABLE</td></tr><tr><td>Last checked</td><td>1 Minutes ago!</td></tr></tbody></table><p><h2>daq e series user manual</h2></p><p>Please check your inbox, and if you can’t find it, check your spam folder to make sure it didn't end up there. Please also check your spam folder. All rights reserved. National Instruments will, at its option, repair or replace equipment that proves to be defective during the warranty period. This warranty includes parts and labor. National Instruments will, at its option, repair or replace software media that do not execute programming instructions if National Instruments receives notice of such defects during the warranty period. National Instruments does not warrant that the operation of the software shall be uninterrupted or error free. National Instruments will pay the shipping costs of returning to the owner parts which are covered by warranty. The document has been carefully reviewed for technical accuracy. In the event that technical or typographical errors exist, National Instruments reserves the right to make changes to subsequent editions of this document without prior notice to holders of this edition. The reader should consult National Instruments if errors are suspected. In no event shall National Instruments be liable for any damages arising out of or related to this document or the information contained in it. Any action against National Instruments must be brought within one year after the cause of action accrues. National Instruments shall not be liable for any delay in performance due to causes beyond its reasonable control. The warranty provided herein does not cover damages, defects, malfunctions, or service failures caused by owner’s failure to follow the National Instruments installation, operation, or maintenance instructions; owner’s modification of the product; owner’s abuse, misuse, or negligent acts; and power failure or surges, fire, flood, accident, actions of third parties, or other events outside reasonable control. The FCC places digital electronics into two classes.<a href="http://mebel-kxm.ru/userfiles/craftsman-19_5-hp-42-mower-manual.xml">http://mebel-kxm.ru/userfiles/craftsman-19_5-hp-42-mower-manual.xml</a></p><ul><li><strong>daq e series user manual, daq e series user manual downloads, daq e series user manual pdf, daq e series user manual download, daq e series user manual free.</strong></li></ul> <p> These classes are known as Class A (for use in industrial-commercial locations only) or Class B (for use in residential or commercial locations). Depending on where it is operated, this product could be subject to restrictions in the FCC rules. (In Canada, the Department of Communications (DOC), of Industry Canada, regulates wireless interference in much the same way.) Most of our products are FCC Class A. The FCC rules have restrictions regarding the locations where FCC Class A products can be operated. Classification requirements are the same for the Federal Communications Commission (FCC) and the Canadian Department of Communications (DOC). These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and used in accordance with the instruction manual, may cause harmful interference to 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 Cet appareil numerique de la classe A respecte toutes les exigences du Reglement sur le materiel brouilleur du Canada. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation.<a href="http://www.cenlaworkready.com/siteuploads/editorimg/craftsman-19_5-hp-lawn-tractor-manual.xml">http://www.cenlaworkready.com/siteuploads/editorimg/craftsman-19_5-hp-lawn-tractor-manual.xml</a></p><p> If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one or more of the following measures: Cet appareil numerique de la classe B respecte toutes les exigences du Reglement sur le materiel brouilleur du Canada. The Manufacturer includes a DoC for most every hardware product except for those bought for OEMs, if also available from an original manufacturer that also markets in the EU, or where compliance is not required as for electrically benign apparatus or cables. Select the appropriate product family, followed by your product, and a link to the DoC appears in Adobe Acrobat format. Click the Acrobat icon to download or read the DoC. When this symbol is marked on Bold text also denotes The SCB-68 features a general breadboard area for custom circuitry and sockets for interchanging electrical components. These sockets or component pads allow RC filtering, 4 to 20 mA current sensing, open thermocouple detection, and voltage attenuation.Quick reference labels for some other devices ship with the DAQ device itself. These labels show the switch configurations and define the screw terminal pinouts for compatible DAQ devices. You can put the label on the inside of the SCB-68 cover for easy reference if you are using one of these devices. Figure 1-1 shows where to apply the quick reference label to the inside cover of the SCB-68. The SH1006868 is Y-shaped, with a 100-pin male connector on one end and two 68-pin female connectors on the opposite end. The DAQ device connects to the 100-pin cable connector, and an SCB-68 can connect to each 68-pin cable connector. Figure 1-3 shows how use the SH1006868 to cable a 100-pin DAQ device to two SCB-68 devices. This connector is available when you use the SH68-68-EP or R6868 cable assemblies with an E Series DAQ device.</p><p> It is also one of two 68-pin connectors available when you use the SH1006868 cable assembly with a 100-pin E Series DAQ device. This pinout shows the other 68-pin connector when you use the SH1006868 cable assembly with an NI 6031E, NI 6033E, or NI 6071E. This pinout shows the other 68-pin connector when you use the SH1006868 cable assembly with an NI 6025E or the NI 6021E (AT-MIO-16DE-10) for ISA. Misuse of the SCB-68 can result in a hazard. You can compromise the safety protection built into the SCB-68 if the device is damaged in any way. If the SCB-68 is damaged, return it to NI for repair. Use the SCB-68 only with the chassis, modules, accessories, and cables specified in the installation instructions. You must have all covers and filler panels installed during operation of the SCB-68. Operate the SCB-68 only at or below the pollution degree stated in Appendix A, Specifications. The following is a description of pollution degrees. The pollution has no influence. Occasionally, however, a temporary conductivity caused by condensation must be expected. Make sure that the SCB-68 is completely dry and free from contaminants before returning it to service. Do not exceed the maximum ratings for the SCB-68. Remove power from signal lines before connecting them to or disconnecting them from the SCB-68. This category is a signal level such as voltages on a printed wire board (PWB) on the secondary of an isolation transformer. This category refers to local-level distribution such as that provided by a standard wall outlet. This category is a distribution level referring to hardwired equipment that does not rely on standard building insulation. Do not remove equipment covers or shields unless you are trained to do so. If signal wires are connected to the SCB-68, dangerous voltages may exist even when the equipment is powered off. To avoid dangerous electrical shock, do not perform procedures involving cover or shield removal unless you are qualified to do so.</p><p> Before you remove the cover, disconnect the AC power or any live circuits from the SCB-68. Do not use these terminals as safety earth grounds. Never connect voltages ?42 V rms. NI is not liable for any damage or injuries resulting from improper use or connection. You can now open the box. Slide the signal wires through the front panel strain-relief opening. You can also remove the top strain-relief bar if you are connecting many signals. Add insulation or padding if necessary. Table 2-1 illustrates the available switch configurations and the affected signals for each switch setting. Refer to Table 2-1 to determine the switch setting that applies to your application, and then refer to the following sections for more information on specific types of signals. This setting is not recommended for use with the NI 653 X, NI 670 X, or NI 660 X.On most devices, you can software-configure the DAQ device channels for two types of single-ended connections—nonreferenced single-ended (NRSE) input mode and referenced single-ended (RSE) mode. RSE input mode is used for floating signal sources. In this case, the DAQ device provides the reference ground point for the external signal. NRSE input mode is used for ground-referenced signal sources. In this case, the external signal supplies its own reference ground point, and the DAQ device should not supply one. The following sections discuss the use of single-ended and differential measurements and considerations for measuring both floating and ground-referenced signal sources. Figure 3-1 summarizes the recommended input modes for both types of signal sources. Instruments or devices with isolated outputs are considered floating signal sources, and they have high-impedance paths to ground. Some examples of floating signal sources are outputs for thermocouples, transformers, battery-powered devices, optical isolators, and isolation amplifiers.</p><p> The ground reference of a floating source must be tied to the ground of the DAQ device to establish a local or onboard reference for the signal. Otherwise, the measured input signal varies as the source floats outside the common-mode input range. To provide a return path for the instrumentation amplifier bias currents, differential floating sources must have a 10 to 100 k.You can install In this mode, the negative input of the instrumentation amplifier on the DAQ device is tied to the analog ground. In the factory-default configuration, In this configuration, you should connect all signal In such cases, to move these jumpers to and from the factory-default positions, you must solder and desolder on the SCB-68 circuit card assembly. When soldering, refer to Appendix E, Soldering and Desoldering on the SCB-68. Nonisolated outputs of instruments and devices that plug into the building power system fall into this category. If a grounded signal source is incorrectly measured, this difference may appear as a measurement error. The connection instructions for grounded signal sources are designed to eliminate this ground potential difference from the measured signal. In such cases, to move these jumpers to and from the factory-default positions, you must solder and desolder on the SCB-68 circuit card assembly. When soldering, refer to Appendix E, Soldering and Desoldering on the SCB-68. Therefore, you should configure the DAQ device for NRSE input mode. In this input mode, connect all the signal grounds to AISENSE pin, which connects to the negative input of the instrumentation amplifier on the DAQ device. RSE input mode is not recommended for grounded signal sources. It has been tested with these drivers: As of release 3.38.1.37437, the entire NI X Series plus NI USB-6000, USB-6001, USB-6002, USB-6003, USB-6008, USB-6009, PCI-6624 and PXI-6624 are supported. Only ports 0-7 and 16-23 can be used simultaneously in a differential or pseudodifferential configuration.</p><p> If you change the Analog Input port configuration to RSE or NRSE, then the corresponding port (negative port) shows up (offset by 8). Note: Most likely it is possible to also measure linear position with the two-pulse encoder by setting the corresponding NI DAQmx Transform output counter port's Port Sub Type to AngleMeasurement and Position Decoding Method to TwoPulseCounting. PWM Starting edge also only applies to ctr ports. It is the edge of the signal that is used as a reference for the PWM measurement. These ports map to the DAQ’s PFI Counter Out ports and pins as shown: The values in Analog Configuration must not exceed the properties of the hardware. The port’s input is a number between 0 and 100 corresponding to the duty cycle. The Pulse Measurement outports provide the Duty Cycle percentage. If the frequency is known and if measurement is kept exact same as frequency, then there may be issues due to any tolerance issues. All documents are available on ni.com, and help files install with the software. Getting started guide for your DAQ device The DAQ getting started guides for NI-DAQmx provides instructions for installing and configuring NI-DAQmx devices. NI 6xxx Specifications The specifications document for your DAQ device provides detailed specifications, including the device calibration interval. NI-DAQmx Readme Operating system and application software support in NI-DAQmx. NI-DAQmx Help Information about creating applications that use the NI-DAQmx driver. LabVIEW Help LabVIEW programming concepts and reference information about NI-DAQmx VIs and functions NI-DAQmx C Reference Help Reference information for NI-DAQmx C functions and NI-DAQmx C properties Password NI-DAQmx.NET Help Support for Visual Studio Reference information for NI-DAQmx.NET methods and NI-DAQmx.NET properties, key concepts, and a C enum to.net enum mapping table The default password for password-protected operations is NI.</p><p> If the recommended equipment is not available, select a substitute using the requirements listed in Table 1. Caution For compliance with Electromagnetic Compatibility (EMC) requirements, this product must be operated with shielded cables and accessories. Whether using the recommended instrument or another counter, you must ensure that it is configured to be at least 12.5 ppm ( %) accurate. PXI chassis NI PXI-1042, NI PXI-1042Q Use with PXI modules. PXI Express chassis Low thermal copper EMF plug-in cable NI PXIe-1062Q Use with PXI Express modules. If you programmatically control this fixture, you do not need to disconnect and reconnect cables at each step of the procedure. (NI 61xx Devices) S Series devices must use revision B or later of the calibration adapter. NI BNC-2110 Desktop and DIN rail-mountable BNC adapter you can connect to DAQ devices. Keep connections to the device as short as possible. Long cables and wires can act as antennae, which could pick up extra noise that would affect measurements. Use shielded copper wire for all cable connections to the device. Use twisted-pair wire to eliminate noise and thermal offsets. Maintain the ambient temperature between 18 and 28 C. The device temperature is greater than the ambient temperature. Refer to the Calibration Procedure section for more information about calibration temperatures and temperature drift. Keep relative humidity below 80%. Allow adequate warm-up time (generally between 15 and 30 minutes for most DAQ devices) to ensure that the measurement circuitry is at a stable operating temperature. Refer to your DAQ device specifications document for the recommended warm-up time for your device. Calibration Procedure The calibration process has the following steps. 1. Initial Setup Configure your device in NI-DAQmx, adjust the self-calibration constants of the device, and verify that the current device temperature does not cause you to incorrectly calibrate your device. 2.</p><p> Verification Verify the existing operation of the device. If you do not want to perform an adjustment, you can update the calibration date without making any adjustments. 5. Reverification Perform another verification to ensure that the device is operating within its specifications after adjustment. These steps are described in detail in the following sections. Note When a device is configured in MAX, it is assigned a device name. Each function call uses this device name to determine which device to calibrate. Self-Calibration Complete the following steps to self-calibrate the device. For these devices, continue with the Verification section. 1. Wait for the device to warm-up for the recommended time period generally between 15 and 30 minutes for most DAQ devices. After self-calibrating your device (as described in the Self-Calibration section), complete the following steps to compare the current device temperature to the temperatures measured during the last self-calibration and external calibration. For these devices, continue with the Verification section. Note You also can read the current device temperature, the temperature during the last self-calibration, and the temperature during the last external calibration in MAX. Refer to your DAQ device specifications document for more information. Change the system so that the temperature is closer to the temperature recorded during the last external calibration. The verification procedures assume that adequate traceable uncertainties are available for the calibration references. The verification procedure is divided into the major functions of the device. Throughout the verification process, use the tables in the Test Limits section to determine if your device needs to be adjusted. Note Test limits in tables of the Test Limits section are based upon the most recent edition of the specifications document for your device. Refer to Table 2 to determine connections between the device and the calibrator.</p><p> Note If your calibrator has a guard connection, connect that terminal to AI GND. If your calibrator does not have a guard connection and has a floating output, connect the negative output to AI GND. If the calibrator output is not floating, do not make any other connections. You must perform verification on all ranges of one analog input channel in differential mode. (Optional) Then, perform verification on one range of all remaining analog input channels in differential mode to verify that the device mux and analog input lines are operating properly. Refer to your device user documentation for signal connection locations. This table shows all acceptable settings for the device type. NI recommends that you verify all ranges, although you may want to save time by checking only the ranges used in your application. 3. Set the calibrator voltage to the test value indicated in the device table. 4. Create a task using DAQmxCreateTask. 5. Add a channel to the task using the DAQmx Create Virtual Channel VI and configure the channel. Use the tables in the Test Limits section to determine the minimum and maximum values for your device. Note Throughout the procedure, refer to the NI-DAQmx function call parameters for the LabVIEW input values. LabVIEW Block Diagram NI-DAQmx Function Call Call DAQmxStartTask with the following parameter: taskhandle: taskhandle 10. Average the voltage values that you acquired. Compare the resulting average to the upper and lower limits listed in the table in the Test Limits section. If the result is between these values, the device passes the test. Clear the acquisition using the DAQmx Clear Task VI. You have finished verifying the analog input levels on your device. Skip this step if the device you are calibrating does not have analog output circuitry. Note Test limits in tables of the Test Limits section are based upon the most recent edition of the specifications document for your device.</p><p> Refer to the Calibration Procedure section for more information and instructions on reading your device temperature and comparing it against the device temperature during the last external calibration. This table shows all acceptable settings for the device. NI recommends that you verify all ranges, although you may want to save time by checking only the ranges used in your application. 3. Create a task using DAQmxCreateTask. LabVIEW Block Diagram LabVIEW does not require this step. Note Throughout the procedure, refer to the NI-DAQmx function call parameters for the LabVIEW input values. LabVIEW Block Diagram NI-DAQmx Function Call Call DAQmxStartTask with the following parameter: taskhandle: taskhandle 6. Write a voltage (from the Test Point column of the table in the Test Limits section) to the AO channel using the DAQmx Write VI. LabVIEW Block Diagram NI-DAQmx Function Call Call DAQmxClearTask with the following parameter: taskhandle: taskhandle 10. Disconnect the DMM from AO 0, and reconnect it to AO 1, making the connections shown in Table Repeat steps 3 through 10 for all AO channels on the device. 12. Disconnect your DMM from the device. You have finished verifying the analog output levels on your device. It is not possible to adjust this timebase, so only verification can be performed. Note Test limits in tables of the Test Limits section are based upon the most recent edition of the specifications document for your device. Refer to the Calibration Procedure section for more information and instructions on reading your device temperature and comparing it against the device temperature during the last external calibration. Complete the following steps to perform checks on the counter of your device. 1. Connect your counter positive input to CTR 0 OUT (pin 2) and your counter negative input to D GND (pin 35) Create a task using DAQmxCreateTask. 3. Add a counter output channel to the task using the DAQmx Create Virtual Channel VI and configure the channel.</p><p> Note Throughout the procedure, refer to the NI-DAQmx function call parameters for the LabVIEW input values. 1 Pin numbers are given for 68-pin connectors only. LabVIEW Block Diagram NI-DAQmx Function Call Call DAQmxStopTask with the following parameter: taskhandle: taskhandle 10. Clear the generation using the DAQmx Clear Task VI. LabVIEW Block Diagram NI-DAQmx Function Call Call DAQmxClearTask with the following parameter: taskhandle: taskhandle 11. Disconnect the external counter from your device. At the end of each calibration procedure, these new constants are stored in the external calibration area of the EEPROM. These values are password-protected, which prevents the accidental access or modification of any calibration constants adjusted by the metrology laboratory. The default password is NI. Complete the following steps to perform device analog adjustment with a calibrator: 1. Connect the calibrator to the device. Refer to Table 4 to determine connections between the device and the calibrator. The calibrator connections depend on the resolution of the device you are calibrating. If your calibrator does not have a guard connection and has a floating output, connect the negative output to AI GND. If the calibrator output is not floating, do not make any other connections. For more information, refer to your DAQ device user documentation. The default password is NI. Note (NI 6010 Devices) Use the DAQmx Adjust M-Series Calibration VI (DAQmxMSeriesCalAdjust). LabVIEW Block Diagram NI-DAQmx Function Call Call DAQmxYSeriesCalAdjust with the following parameters: calhandle: calhandle referencevoltage: 7.5, 3.75, 5, or 4.5 (based on calibrator output from step 2) 5. Save the adjustment to the EEPROM, using the DAQmx Close External Calibration VI. This VI also saves the date, time, and temperature of the adjustment to the onboard memory. Note If an error occurs during adjustment, no constants is written to the EEPROM.</p><p> If you do not want to perform an adjustment, you can update the calibration date without making any adjustments by initializing an external calibration (using the DAQmx Initialize External Calibration VI) and closing the external calibration (using the DAQmx Close External Calibration VI). Reverification Repeat the Verification section to determine the as-left status of the device. Note If any test fails reverification after performing an adjustment, verify that you successfully self-calibrated the device, as described in the Self-Calibration section, before returning your device to NI. Refer to Worldwide Support and Services for assistance in returning the device to NI. Note that different devices have different calibration intervals. NI 6011E Analog Input Values (Continued) Pos FS Pos FS Pos FS 29 Table 12. NI 6036E Analog Output Values Pos FS Neg FS Table 26. NI 6040E Analog Input Values (Continued) 0 1 Pos FS Pos FS Pos FS Pos FS 45 Table 31.You choose the number of analog Vernier Digital Control Unit (DCU) LabQuest or LabPro power supply They draw current proportional to the mechanical Install your application and driver software, then your device, using the instructions Most National Each tutorial in this series, will teach you a specific topic of common measurement Minimum or maximum specifications are warranted under the following conditions: hour C-2 Data Translation: Overview.However, within your own VI you will use LabVIEW supplied Specifications are subject Pair these specifications with your FPGA module specifications. Safety instructions The following This will ensure that no noise currents can flow in the sensor leads and that no common-mode All Rights Reserved. 5 Safety instructions This guide also describes how to Connect and measure immediately! Connect and measure immediately.</p><p> XXL performance in mini format 8 universal connectors 1) on each QuantumX device suited for most common transducer technologies: 1) See technical Specifications Typical for 25 C unless otherwise specified. s in Setup Software Guide.The configuration-based user interface provides ready-to-run User's Guide The USB data acquisition system accomodated in a stable aluminum housing is ideal for User s Manual Version:1.0 Release: August 2003 Copyright and Trademarks The information of the product in this manual is subject Imagine Communications considers this document and its contents This Quick Start document contains DO NOT connect the INF-USB2 or SI-USB module to your computer before running the setup program. After running Setup and The reliability of a power supply must match or exceed the rest of the system in which it is installed. Generally, this requires The products covered by this guide are the NI PCI-8361, NI Product Guide Informatics Research Group MIMOS Berhad by Assoc. Prof. Dr. Chee Peng Lim Associate Professor Sch. Parameters Min. Typ. Max. Note. Vaux Voltage 9.8 V 12 V 13.2 V Auxiliary Supply Voltage With the latest SIFR III GPS module Low-cost chassis for remote control applications Controlled from either a PCI Express desktop host or an ExpressCard Use the meter You will also setup equations to control MP503 binary outputs. The Binary Output To use this website, you must agree to our Privacy Policy, including cookie policy. Includes standard analysis modules and unlimited module count. - Most Popular Includes all DASYLab Basic features plus standard modules, 200 layout windows, unlimited module count, and control sequencer.Includes all DASYLab Full features plus advanced signal analysis and control modules.The hardware is great, but something in DASYLab or the driver makes them very slow over even the fastest Ethernet connection. Should be easy to fix but no action by MCC so far.</p><p> I also use the USB versions, which work great with the same DASYLab software. These longer delays are not accommodated by DASYLab’s core architecture. USB timing is more deterministic, which fits well with DASYLab’s architecture. Changes to DASYLab’s core would be too intrusive to accommodate these large delays, hence we recommend 0.5 Hz or slower, and small DIO channel count, when using the E-series with DASYLab. This unit certainly meets that criteria and does the job, however it is simply not designed for an Industrial environment. I was beat to find something that is so I am currently using this device with reasonable results. The main issues are power and physical mounting. The DIN rail clip it comes with mounts it flat on the rail which mean the connections for the IO go vertically up or down and the Ethernet and power connectors on the end face make the next 40mm of DIN rail space unusable. A well designed DIN rail mountable device has all the IO and the power and data connections going vertically up or down or facing the user on the narrow ends or front narrow side and mounts sideways. I have made up a custom bracket to do this as I do not use the DIO side face but this means that I have to buy a custom bracket and cut off the terminal label and remount it facing the user. Worse still is the power connection. It is a barrel plug from a 110V ac wall wart with no alternatives. Virtually all industrial DIN mountable devices run on 24Vdc and have push in or screw down wire terminals. So to power this I need to take up even more DIN rail space by adding a 24Vdc to 5Vdc power converter and then cut the cable off the unusable wall wart and terminate it onto the converter. Software wise it is a mixed bag. We need the unit to work in a Linux environment and although we have managed to make it work it has taken a lot of effort to do so as the support is not readily available and is not directly skilled in a custom Linux environment.</p></body>
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