Spectrum Monitoring Receiver from Digilogic Systems

Introduction:

In today’s increasingly complex RF environments, efficient and precise spectrum monitoring is essential. Spectrum monitoring is a critical process in managing and optimizing the use of radio frequencies across various applications, including telecommunications, aerospace, and defence. By continuously observing the radio frequency spectrum, spectrum monitoring ensures compliance with regulatory standards, identifies unauthorized transmissions, and detects potential interference sources. 

Advanced Spectrum Monitoring Receiver systems utilize advanced technologies to analyze real-time frequency data, ensuring reliable performance and preventing service disruptions, safeguarding the spectrum, and enhancing communication infrastructure.

What is spectrum monitoring?

Spectrum monitoring is performed by utilizing up-to-date highly integrated PXIe-based systems to demodulate and analyse digital and analog RF/IF signals. These systems which have been created in LabVIEW and utilizing Virtex- 5 FPGA technology, can acquire up to six signals from NI PXIe monitoring receivers. 

Some of these figures include the spectrum and small satellite mapping, the use of Waterfall/Spectrogram real-time probe, and RAID for post-analysis. Operations like ‘channelizing’ and ‘demodulation’ facilitate fine-tuning and selective filtering and decoding of the signals according to the characteristics set by the user.

Why is spectrum monitoring important?

Spectrum Monitoring Importance

 Detects interprets, and successfully controls radio communication frequency signals.

Promotes proper use of the available spectrum and identifies those who are using the frequency without authority.

Reduced interference of the communications that are central to the functioning of the system.

Uses such interfaces as panoramic spectrum displays and spectrograms in real-time.

Helps in meeting the requirements of the laws, and aids in efficient spectrum management and coordination in case of an emergency.

Maintains the cleanliness of the communication networks.

Includes processing capabilities of the channelization and demodulation for targeted signal control.

How does Digilogic Systems spectrum monitoring work?

Signal Acquisition: Several RF/IF signals are received through the NI PXIe monitoring receivers.

Digital Down conversion: In the receiver path the received signals are down converted to a lower frequency to allow easy digital processing.

Channelization: The signals that are down converted are further partitioned into six independent paths for parallel processing.

Signal Analysis: Regarding the signal acquired in each channel, signal processing is applied by utilizing numerous methods on LabVIEW.

Visualization: Spectrum and waterfall are typical types of displays that give immediate information regarding signals.

What technologies are used in Digilogic Systems spectrum monitoring systems?

Spectrum monitoring systems of Digilogic Systems are designed using PXIe architecture, LabVIEW software, and Virtex-5 FPGA for effective signal analysis. These include live images of the panoramic spectrum, spectrogram displays, and recording/playback functionalities. Sophisticated channelizing and demodulation allow for processing up to six signals at a time with separate bandwidth settings.

What are the key applications of Digilogic Systems spectrum monitoring?

The main use is found in the areas of communications such as telecommunication, aerospace, and defence to the set legal requirements. Frequency supervision aids in

The administration and identification of unauthorized uses as well as signal jamming in those sectors of operation.

Potential Applications

Signal Intelligence: Gathering intelligence from intercepted exchanges using voice or digital media.

Radar Signal Processing: Interpreting the signals for identification and tracking of targets through radar.

Communications System Development and Testing: Assessment of communication systems and their overall performance.

Electronic Warfare: Identifying and categorizing the hostile signals.

How does Digilogic Systems spectrum monitoring help with regulatory compliance?

Digilogic’s Spectrum monitoring ensures that users adhere to regulatory standards by identifying unauthorized transmissions and potential interference sources. This helps regulatory bodies enforce spectrum policies and manage frequency allocations effectively.

Features:

Real-time digital IF data acquired by Spectrum Monitoring Receiver.

Real-time analog IF data digitized via high-speed digitizer

High-performance Virtex-5 FPGAs for processing

Spectrum and Waterfall representation

Signal recording & replaying on/from RAID

Processing of multiple signals (up to 6 signals in a total span of 50 MHz of bandwidth)

Manual demodulation of each signal (up to 20 MHz of bandwidth)

Facts:

Monitoring of complete signal scenarios.

Powerful classifier & extensive signal processing library with demodulators.

Configurable detection of fixed frequency & burst with the processing of the detected signal.

Modular capability of selecting from one channel through a six-channel signal processing solution.

Open interface for independent extension of signal processing capabilities of the user.

Signal recording & replaying on/from Solid Disk Drive.

Conclusion:

The Spectrum Monitoring Analyser of the Digilogic System is an efficient and multifunctional device for performing various types of RF/IF signal analysis. The use of PXIe as the basis for the system together with being integrated with LabVIEW software and Virtex-5 FPGA provides signals’ high-quality processing. As the system can handle up to six signals at a time, this means that the variety of waveforms is encompassed by the system.

The ability to analyze signal characteristics in a real-time waterfall and panoramic spectrum display is also very useful. In addition, the recording and replay function prepared for offline examination is particularly useful in this regard. Because users can alter the parameters of channelization and demodulation, it becomes possible to derive usable information from the received signal. In summary, Digilogic’s analyzer is a valuable tool for researchers and engineers who are solving problems in the RF and communications fields.

Contact us today to discuss your Spectrum Monitoring requirements:

Website: https://www.digilogicsystems.com/

Phone:

Hyderabad: (+91) 40 4547 4601 / 02 / 03

Bengaluru: (+91) 80 4975 6034

Email: [email protected]

Locations:

HEAD OFFICE          

#102, 1st Floor, DSL Abacus Tech Park beside DSL Virtue Mall, Uppal, Hyderabad, Telangana-500 039.

BRANCH OFFICE

#216, 3rd floor, Zareen Heights, Varthur Road, Nagavarapalya, C. V. Raman Nagar, Bengaluru, Karnataka — 560093.

NI Software Consulting Services by Puja Controls

Puja Controls is providing NI Software Consulting services for decades. We have professionals who are experts in National Instruments Software including:

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NI, 동급 최고 성능의 NI PXIe-5667로 일반 스펙트럼 모니터링 및 신호 감시 문제 해결

NI, 동급 최고 성능의 NI PXIe-5667로 일반 스펙트럼 모니터링 및 신호 감시 문제 해결

 NI PXIe-5667 3.6 및 7 GHz 스펙트럼 모니터링 수신기는 동급 최고의 다이나믹 레인지인 110 dB 이상과 TOI를 이용한 왜곡 성능인 17 dBm 이상을 제공 내쇼날인스트루먼트(www.ni.com)는 전파 모니터링, 방해 감지, 스펙트럼 규정 및 관련 어플리케이션을 ITU 권장사항으로 해결할 수 ��는 NI PXIe-5667 스펙트럼 모니터링 수신기를 출시한다고 발표했다. NI FlexRIO 및 NI LabVIEW FPGA Module과 결합된 NI PXIe-5667은 지속적인 스펙트럼 모니터링, 스펙트로그램 및 고급 신호 처리와 같은 RF 신호의 리얼타임 분석을 호스트 컨트롤러 또는 PC와의 데이터 이동 지연 없이 FPGA에서 수행할 수 있다. 함께 구입 가능한 LabVIEW FPGA…

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Labview 2019 crack

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Support for Vivado 2017.2 FPGA Compile Tools Native Python Node for calling Python scripts within LabVIEW Backward Compatible Run-Time Engine for simplified use of existing binaries Native package building for easy code distribution The latest version of LabVIEW 2019 includes these top features:

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To ensure compatibility with other engineering tools, LabVIEW can interoperate with, and reuse libraries from, other software and open-source languages. To turn your acquired data into real business results, you can develop algorithms for data analysis and advanced control with included math and signal processing IP or reuse your own libraries from a variety of tools. LabVIEW enables you to immediately visualize results with built-in, drag-and-drop engineering user interface creation and integrated data viewers. LabVIEW reduces the complexity of programming, so you can focus on your unique engineering problem. The LabVIEW programming environment simplifies hardware integration for engineering applications so that you have a consistent way to acquire data from NI and third-party hardware. Combine LabVIEW 2019 with proven, off-the-shelf customizable hardware from NI which has been used by engineers for over 30 years to develop and deploy custom large-scale industrial and production systems. LabVIEW 2019 simplifies the design of distributed test, measurement, and control systems decreasing your time to market.

Drivers Interface Multifunction Devices

Drivers Interface Multifunction Devices Scanner

Drivers Interface Multifunction Devices

Drivers Interface Multifunction Devices Device

Multifunction Device free download - USB Mass Storage Device, Multifunction Device, MPU-401 Compatible MIDI Device, and many more programs.

NI R Series Multifunction RIO is an NI instrument driver that supports the PXI Multifunction Reconfigurable I/O Module and Multifunction Reconfigurable I/O Device. This driver provides the files you will need to program this hardware in LabVIEW using the LabVIEW FPGA Module.

Category: Monitor and video cards Manufacturer: Delta Caution Level: Intermediate Download File Size: 1.8 MB Operating System: Windows XP, Windows 2000, Windows NT Latest Version / Release Date: N/A / N/A

In these configurations, the Toaster device is a child device on the multifunction device, and the multifunction device is a child device on a PCMCIA bus. The INF file and installers for the Toaster device install the Serial driver as lower-level device filter driver to provide a 16550 UART-compatible interface for the Toaster device. There’s no need to download individual printer drivers for every device in your office. The Global Print Driver is a truly universal printer driver that lets you print to virtually any printer or multifunction printer — even to those made by other manufacturers.

Windows device driver information for PCI Multifunction-IO Controller

The PCI Multifunction-IO Controller is an input and output card that comes with field wiring and function protection keys which ensure that the card is plugged in right. This driver is ideal for users due to its capabilities of protection keys, modularity and plug and play. It has an interface that consists of an I/O terminal block and I/O card. It makes it possible to pre-wire the I/O card before installation. The driver is mounted on the carrier of the I/O interface. This device is pocket friendly as it cuts down on cost. It is user friendly in that its installation is easy thereby saving on time and expenses. As it is mounted, this means that no cords are needed. It comes with an easy fail safe design and when in use, productivity is bound to increase. This is because its addition does not interrupt the entire system.

Outdated Drivers?

Unless you update your drivers regularly you may face hardware performance issues.

Drivers Interface Multifunction Devices Scanner

Drivers Interface Multifunction Devices

To check your drivers you should manually verify every device on your system for driver updates

Drivers Interface Multifunction Devices Device

To install the PCI Multifunction-IO Controller, users need to check compatibility of the driver with the prescribed operating systems. The file should then be downloaded from the given site and saved into the computer and then unzipped. This device is then supposed to be connected to the computer. The user then right clicks on My Computer and then on properties. He should then go to the hardware tab and click on device manager button. The user should find the new driver in the multifunction category and double click on it, then press the re-install driver button. Install should be selected from the specified location. The user should now click on the browse button to select the driver, and then click the next button to continue and the finish button to complete the procedure. The user will now see the new driver in the multifunction inside the device manager. It is highly recommended you run a free registry scan for Windows and PCI Multifunction-IO Controller errors before installing any driver updates.

Hands-on Introduction to LabVIEW by Dr. Deepak V. Bhoir, Professor & Head of Department (HOD)

LabVIEW (Laboratory Virtual Instrument Engineering Workbench) is the graphical programming environment which has become prevalent throughout research labs, academia and industry. It is a powerful and versatile analysis and instrumentation software system for measurement and automation. Its graphical programming language called G programming is performed using a graphical block diagram that compiles into machine code and eliminates a lot of the syntactical details. LabVIEW offers more flexibility than standard laboratory instruments because it is software based. Using LabVIEW, the user can originate exactly the type of virtual instrument needed and programmers can easily view and modify data or control inputs. The popularity of the National Instruments LabVIEW graphical dataflow software for beginners and experienced programmers in so many different engineering applications and industries can be attributed to the software’s intuitive graphical programming language used for automating measurement and control systems.

LabVIEW programs are called virtual instruments (VIs), because their appearance and operation imitate physical instruments like oscilloscopes. LabVIEW is designed to facilitate data collection and analysis, as well as offers numerous display options. With data collection, analysis and display combined in a flexible programming environment, the desktop computer functions as a dedicated measurement device. LabVIEW contains a comprehensive set of VIs and functions for acquiring, analyzing, displaying, and storing data, as well as tools to help you troubleshoot your code. All test, measurement and control applications can be divided into three main components and the key to virtual instrumentation is the ability to acquire, analyze and present data. LabVIEW can acquire data using the devices like GPIB, Serial, Ethernet, VXI, PXI Instruments, Data Acquisition (DAQ), PCI eXtensions for Instrumentation (PXI), Image Acquisition (IMAQ), Motion Control, Real-Time (RT) PXI, PLC (through OPC Server), PDA, and Modular Instruments. To help you analyze your data LabVIEW includes analysis functions for Differential Equations, Optimization, Curve Fitting, Calculus, Linear Algebra, Statistics and so on. Express VIs are specifically designed for measurement analysis, including filtering and spectral analysis. Signal Processing VIs for Filtering, Windowing, Transforms, Peak Detection, Harmonic Analysis, and Spectrum Analysis are provided. LabVIEW includes the following tools to help in presenting data on the computer; Graphs, Charts, Tables, Gauges, Meters, Tanks, 3D Controls, Picture Control, 3D Graphs and Report Generation. Over the Internet, Web Publishing Tools, Data socket (Windows Only), TCP/IP, VI Server, Remote Panels and Email are available to present data.

LabVIEW can communicate with hardware such as data acquisition, vision, and motion control devices, and GPIB, PXI, VXI, RS-232, and RS-485 devices. LabVIEW also has built-in features for connecting your application to the Web using the LabVIEW Web Server and software standards such as TCP/IP networking and ActiveX. Using LabVIEW, you can create test and measurement, data acquisitions, instrument control, datalogging, measurement analysis, and report generation applications. You also can create stand-alone executables and shared libraries, like DLLs, because LabVIEW is a true 32-bit compiler. For new programmers, LabVIEW Express technology transforms common measurement and automation tasks into much higher-level, intuitive VIs. With Express technology, thousands of nonprogrammers have taken advantage of the LabVIEW platform to build automated systems quickly and easily. For experienced programmers, LabVIEW delivers the performance, flexibility and compatibility of a traditional programming language such as C or BASIC. In fact, the full-featured LabVIEW programming language has the same constructs that traditional languages have such as variables, data types, objects, looping and sequencing structures, as well as error handling. And with LabVIEW, programmers can reuse legacy code packaged as DLLs or shared libraries and integrate with other software using ActiveX, TCP and other standard technologies. The LabVIEW Family consists of NI LabVIEW Graphical Programming Software for Measurement and Automation, LabVIEW Real-Time Module, LabVIEW FPGA Module, LabVIEW PDA Module, LabVIEW Datalogging and Supervisory Control Module.

National Instruments – 1.06 GHz Dual-Core Controller, LX75 FPGA With Real-Time OS (Model: NI cRIO-9081 RT)

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High-performance multicore system for intense embedded monitoring and control applications

1.06 GHz dual-core Intel Celeron processor, 16 GB nonvolatile storage, 2 GB DDR3 800 MHz RAM

LabVIEW Real-Time for determinism and continuous operation reliability

1 MXI-Express, 4 USB Hi-Speed, 2 Gigabit Ethernet, and 2 serial ports for connectivity and expansion

8-slot Spartan-6 LX75 FPGA chassis for custom I/O timing, control, and processing

0 to 55 °C operating temperature range.

The high-performance multicore NI cRIO-9081 system provides advanced Intel Celeron dual-core processing, built-in VGA display output for an integrated user interface, and the option to use a Microsoft Windows Embedded Standard 7 (WES7) or LabVIEW Real-Time OS. The increased processing power of the cRIO-9081 makes it well suited to perform the advanced processing tasks required by complex applications such as machine vision and rapid control prototyping. Choose the LabVIEW Real-Time OS to take advantage of deterministic execution and the highest degree of reliability in continuous operation environments. The high-performance multicore cRIO-9081 also offers the widest array of connectivity and expansion options available in the CompactRIO platform, including the high-bandwidth and low-latency MXI-Express bus for expansion using the 14-slot MXI-Express RIO chassis.

Specifications Summary

General Product Name cRIO-9081 Form Factor CompactRIO Product Type Controller (Computing Device) Part Number 781787-01 , 781787-11 Operating System/Target Real-Time , Windows Embedded Standard 7 LabVIEW RT Support Yes CE Compliance Yes Operating Relative Humidity 10 % – 90 % Product Certifications Demko or VDE , IEC , RoHS , C-Tick , FCC Part 15 , UL – Hazardous Locations , ICES , UL – Product Safety , WEEE , CE RoHS Compliant Yes Power Requirements 75 W Reconfigurable FPGA FPGA Spartan-6 Specific FPGA Spartan-6 LX75 Chassis Number of Slots 8 Integrated Controller Yes Input Voltage Range 9 V – 30 V Recommended Power Supply: Power 100 W Recommended Power Supply: Voltage 24 V Power Consumption 75 W Bus Interface USB Specification USB 2.0 Hi-Speed Shock and Vibration Operational Shock 50 g Random Operating Frequency Range 10 Hz – 500 Hz Random Vibration 5 g Sinusoidal Operating Frequency Range 10 Hz – 500 Hz Sinusoidal Vibration 5 g Physical Specifications Length 403.7 mm Width 87.1 mm Height 121.9 mm Weight 3.1 kilogram Minimum Operating Temperature 0 °C Maximum Operating Temperature 55 °C Minimum Storage Temperature -40 °C Maximum Storage Temperature 85 °C Maximum Altitude 2000 m

Resource & Download

Additional Product Information

Manuals  (6)

Dimensional Drawings  

Product Certifications  

Related Information

NI CompactRIO Home Page

Introducing High-Performance Multicore NI CompactRIO

Top 5 Considerations When Choosing an Embedded OS for NI CompactRIO

What Is Microsoft Windows Embedded Standard 7?

NI LabVIEW FPGA Compile Cloud Service

NI Graphical System Design Calculator: Build Versus Buy

Software Support and Compatibility for CompactRIO

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Overview of the LabVIEW Communications Application Frameworks

The insatiable demand for reliable and ubiquitous yet affordable wireless data connections for both people and machines is putting tremendous pressure on the wireless industry

Overview

The insatiable demand for reliable and ubiquitous yet affordable wireless data connections for both people and machines is putting tremendous pressure on the wireless industry. Industry consensus says that the next generation of wireless networks (5G) needs to improve capacity a thousand fold by 2020 without a commensurate increase in cost. To respond to this technological challenge, wireless researchers need to think outside the box and beyond the desktop simulation environment. They need to progress to the real-time prototyping of wireless systems to fully explore the innovations needed.

However, real-time wireless prototyping is an expensive, time-consuming task. Many factors need to be considered including the disparate skill sets required and the lack of a common hardware platform. But the most important challenge is a lack of viable starting points for the existing prevalent wireless standards such as LTE and 802.11 as well as new technologies such as massive multiple input, multiple output (MIMO).

The LTE, 802.11, and MIMO application frameworks provide ready-to-run, open, and modifiable real-time physical layer (PHY) and medium access control (MAC) layer reference designs. They are composed of modular baseband PHY and MAC blocks implemented using the LabVIEW Communications System Design Suite (LabVIEW Communications). The frameworks are designed to run on an FPGA and a general-purpose processor, which are tightly integrated with the RF and analog front ends of NI software defined radio (SDR) hardware.

These application frameworks provide a substantial starting point for researchers to find ways to improve and build prototyping systems. Some example research includes exploring brand-new algorithms and architectures that can support the tremendous increase of the number of terminals, inventing new waveforms by which to modulate and demodulate the signals, or finding new multi-antenna architectures that fully exploit the degrees of freedom in the wireless medium.

The frameworks are designed from the ground up for easy modifiability. This allows wireless researchers to quickly get their real-time prototype up and running based on the LTE and 802.11 standards as well as MIMO technology. They can then primarily focus on the selected aspects of the protocol that they wish to improve, easily modify the designs, and compare their innovations with existing standards.

The PHY and MAC blocks are documented in the product and presented in a graphical block diagram form using LabVIEW Communications. They have clearly defined interfaces, documented system performance benchmarks, and computational resource usage. Additionally, LabVIEW Communications is shipped with a video-streaming application that shows the transfer of real-time data over the air using these standards-compliant wireless links. 

Relevant parameters for the wireless links are easily adjustable from the software front panel generated with LabVIEW Communications. Furthermore, relevant link metrics, including received power spectrum, received constellation, throughput, and block error rates, are also displayed for easy assessment of the link quality. They allow researchers to understand the effects of various parameters on communications performance.

These application frameworks, combined with the ease of development LabVIEW Communications provides and the seamless integration with NI SDR hardware, enable wireless researchers to innovate faster and reduce time to market for their next breakthrough innovations.

1. LabVIEW Communications LTE Application Framework

The latest version of the LabVIEW Communications LTE Application Framework includes:

Subset of a 3GPP-LTE release 10 compliant physical layer

SISO configuration

Closed-loop over-the-air operation with channel state and ACK/ NACK feedback

20 MHz bandwidth

Physical Downlink Shared Channel (PDSCH) and Control Channel (PDCCH)

Up to 75 Mbps data throughput

Normal cyclic prefix mode

FDD and TDD configuration 5-frame structure

QPSK, 16-QAM, and 64-QAM modulation

Variable physical resource block (PRB) allocations

LTE-compliant data-channel coding

Cell-specific and UE-specific reference signals

Primary synchronization signal

Sounding reference signal (SRS)

Receiver algorithms

Automatic gain control

Synchronization based on PSS including time and frequency tracking

Channel estimation and zero-forcing channel equalization

Basic MAC to enable packet-based data transmission and MAC adaptation framework for rate adaptation

Hardware support for USRP RIO, stand-alone USRP-RIO, NI Linux Real-Time, PXIe-7975/7976 PXI FPGA Modules for FlexRIO, and NI-5791 RF Adapter Module for FlexRIO

L1/L2 API to interface with upper MAC

2. LabVIEW Communications 802.11 Application Framework

The latest version of the LabVIEW Communications 802.11 Application Framework includes:

Subset of an 802.11a/g/ac PHY layer

SISO transmission

20 MHz bandwidth legacy (802.11a)

20MHz/ 40MHz VHT modes up to MCS 9 (802.11ac)

80 MHz VHT mode up to MCS 4 (802.11ac)

BPSK, QPSK, 16-QAM, 64-QAM and 256-QAM modulation support

Convolutional encoding and Viterbi decoding

Receiver algorithms

Training field-based packet detection

Time and frequency synchronization, channel estimation and zero-forcing channel equalization

Signal field-based demodulation and decoding

Phase compensation

Lower MAC layer

MAC and PHY interface: PHY-SAP according to 802.11 standard

MPDU generation and recognition

Multinode addressing, CRC and frame type check, SIFS timing compliant (16µs) ACK generation

Clear channel assessment (CCA) information from PHY, processed by MAC

CSMA/CA procedure

Retransmission

RTS, CTS, and NAV support

L1/L2 API to interface with upper MAC

Hardware support for USRP RIO, stand-alone USRP-RIO, NI Linux Real-Time, PXIe-7975/7976 PXI FPGA Modules for FlexRIO, and NI-5791 RF Adapter Module for FlexRIO

3. LabVIEW Communications MIMO Application Framework

The latest version of the LabVIEW Communications MIMO Application Framework includes:

SU-MIMO, MU-MIMO, and Massive MIMO support

50 MHz – 6GHz frequency coverage

20 MHz bandwidth TDD UL and DL

Scalable number of base station antennas from 2 up to 128

Scalable number of mobile station antennas up to 12 antennas

Support for up to 12 spatial streams

Fully reconfigurable frame structure based on LTE

128×12 MMSE, ZF, MRC MIMO precoder/equalizer FPGA IP

4-QAM, 16-QAM, 64-QAM, and 256-QAM modulation support

Channel reciprocity calibration enabling reciprocity-based precoding 

AGC and open-loop power control

Over-the-air synchronization

Basic MAC functionality supports packet-based user data transmission in DL and UL to enable data-streaming applications such as video transmission

4. Modifying the Application Frameworks

Modifying the IP does require a deep understanding of the products. We offer a three-day in-class training course for LabVIEW Communications System Design Suite as well as a custom training for the application frameworks. If some level of the modification is required to fit your application needs, it is highly encouraged to take the training courses. Should you have any questions around the trainings, please contact your local sales representative.

5. Additional Resources

Buy LabVIEW Communications

Learn more about how LabVIEW can help you design a wireless communications system

Download the latest version of the LTE Application Framework manual

Download the latest version of the 802.11 Application Framework manual

Download the latest version of the MIMO Application Framework manual

The registered trademark Linux® is used pursuant to a sublicense from LMI, the exclusive licensee of Linus Torvalds, owner of the mark on a worldwide basis.

Overview of the LabVIEW Communications Application Frameworks syndicated from https://jiohowweb.blogspot.com

Peak6 Investments LP Has Cut Cavium (Call) (CAVM) Holding; Profile of 3 Analysts Covering National Instruments (NATI)

Peak6 Investments Lp decreased Cavium Inc (Call) (CAVM) stake by 66.54% reported in 2017Q2 SEC filing. Peak6 Investments Lp sold 16,900 shares as Cavium Inc (Call) (CAVM)’s stock rose 6.47%. The Peak6 Investments Lp holds 8,500 shares with $528,000 value, down from 25,400 last quarter. Cavium Inc (Call) now has $5.85B valuation. The stock decreased 1.04% or $0.885 during the last trading session, reaching $84.595. About 784,159 shares traded. Cavium, Inc. (NASDAQ:CAVM) has risen 55.16% since December 1, 2016 and is uptrending. It has outperformed by 38.46% the S&P500.

Among 4 analysts covering Natl Instruments (NASDAQ:NATI), 3 have Buy rating, 0 Sell and 1 Hold. Therefore 75% are positive. Natl Instruments had 7 analyst reports since July 31, 2015 according to SRatingsIntel. The company was maintained on Friday, January 27 by Stifel Nicolaus. The firm earned “Buy” rating on Sunday, September 24 by Stifel Nicolaus. The stock has “Market Perform” rating by FBR Capital on Wednesday, May 11. Oppenheimer initiated the stock with “Outperform” rating in Friday, July 31 report. Stifel Nicolaus maintained the stock with “Buy” rating in Friday, October 27 report. The stock of National Instruments Corporation (NASDAQ:NATI) earned “Buy” rating by Stifel Nicolaus on Friday, July 28. Robert W. Baird upgraded National Instruments Corporation (NASDAQ:NATI) rating on Thursday, December 22. Robert W. Baird has “Outperform” rating and $35 target. See National Instruments Corporation (NASDAQ:NATI) latest ratings:

27/10/2017 Broker: Stifel Nicolaus Rating: Buy New Target: $46.0 Maintain 24/09/2017 Broker: Stifel Nicolaus Rating: Buy New Target: $46.0 Maintain 28/07/2017 Broker: Stifel Nicolaus Rating: Buy New Target: $46.0000 Maintain

National Instruments Corporation designs, makes, and sells systems to engineers and scientists worldwide. The company has market cap of $5.69 billion. It offers LabVIEW, a system design software for measurement, automation, and control; LabVIEW Real-Time and LabVIEW FPGA, which are software add-ons to LabVIEW; LabVIEW Communications System Design Suite for wireless prototyping; LabWindows/CVI for creating test and control applications; and Measurement Studio consisting of measurement and automation add-on libraries, and additional tools for programmers. It has a 58.84 P/E ratio. The firm also provides software products, such as NI TestStand to test and measure applications in a manufacturing environment; NI VeriStand software to configure real-time testing applications; NI DIAdem, which provides users configuration technical data management, analysis, and report generation tools; NI InsightCM Enterprise for monitoring critical and ancillary rotating equipment; and NI Multisim circuit design software.

Investors sentiment decreased to 1.2 in Q2 2017. Its down 0.15, from 1.35 in 2017Q1. It fall, as 30 investors sold National Instruments Corporation shares while 69 reduced holdings. 32 funds opened positions while 87 raised stakes. 101.50 million shares or 2.46% more from 99.06 million shares in 2017Q1 were reported. Nationwide Fund Advsrs reported 0.08% of its portfolio in National Instruments Corporation (NASDAQ:NATI). Jennison Assoc Limited Liability owns 801,142 shares or 0.03% of their US portfolio. Atlanta Cap L L C reported 778,993 shares. The Maine-based Schroder Inv Management Group has invested 0.01% in National Instruments Corporation (NASDAQ:NATI). M&T Retail Bank has invested 0% in National Instruments Corporation (NASDAQ:NATI). Liberty Mutual Group Asset Mgmt has invested 0.06% in National Instruments Corporation (NASDAQ:NATI). 2,500 are held by First Quadrant Lp Ca. Louisiana State Employees Retirement System holds 0.05% or 27,700 shares in its portfolio. Bares Mngmt, Texas-based fund reported 3.78 million shares. Blair William Il has invested 0.01% of its portfolio in National Instruments Corporation (NASDAQ:NATI). Ameritas Investment has 0.06% invested in National Instruments Corporation (NASDAQ:NATI). Aperio Grp Limited Com holds 70,922 shares. 64,208 were accumulated by Great West Life Assurance Can. Daruma Cap Mngmt Ltd Com stated it has 100,019 shares or 0.24% of all its holdings. Gsa Cap Prtn Limited Liability Partnership holds 0.02% of its portfolio in National Instruments Corporation (NASDAQ:NATI) for 8,527 shares.

The stock decreased 1.07% or $0.47 during the last trading session, reaching $43.48. About 161,398 shares traded. National Instruments Corporation (NASDAQ:NATI) has risen 38.06% since December 1, 2016 and is uptrending. It has outperformed by 21.36% the S&P500.

Since June 5, 2017, it had 0 insider purchases, and 6 sales for $1.11 million activity. On Monday, June 19 the insider KODOSKY JEFFREY L sold $79,080. On Monday, June 5 TRUCHARD JAMES J sold $290,925 worth of National Instruments Corporation (NASDAQ:NATI) or 7,500 shares.

Analysts await Cavium, Inc. (NASDAQ:CAVM) to report earnings on February, 7. They expect $0.44 earnings per share, up 100.00% or $0.22 from last year’s $0.22 per share. CAVM’s profit will be $30.43M for 48.07 P/E if the $0.44 EPS becomes a reality. After $0.36 actual earnings per share reported by Cavium, Inc. for the previous quarter, Wall Street now forecasts 22.22% EPS growth.

Peak6 Investments Lp increased Exxon Mobil Corp (Put) (NYSE:XOM) stake by 747,500 shares to 824,500 valued at $66.56 million in 2017Q2. It also upped Constellation Brands Inc (Put) (NYSE:STZ) stake by 97,800 shares and now owns 226,600 shares. Mcdonalds Corp (Put) (NYSE:MCD) was raised too.

Investors sentiment decreased to 1.11 in 2017 Q2. Its down 0.09, from 1.2 in 2017Q1. It dropped, as 30 investors sold CAVM shares while 75 reduced holdings. 48 funds opened positions while 69 raised stakes. 66.91 million shares or 5.10% less from 70.51 million shares in 2017Q1 were reported. Eagle Asset Mngmt holds 0.3% of its portfolio in Cavium, Inc. (NASDAQ:CAVM) for 809,000 shares. Prelude Cap Management Llc stated it has 29,564 shares. Westfield Cap Mgmt Ltd Partnership accumulated 744,560 shares or 0.39% of the stock. Dimensional Fund Advsrs Limited Partnership reported 0.01% stake. Metropolitan Life Ins holds 4,713 shares or 0% of its portfolio. Aqr Capital Limited Com invested in 9,653 shares or 0% of the stock. Brown Advisory holds 0.21% or 1.12M shares in its portfolio. Highland Cap Mngmt Limited Partnership reported 70,144 shares. Goldman Sachs holds 0.02% or 1.20 million shares in its portfolio. Jennison Associates Ltd has 1.29M shares for 0.08% of their portfolio. Paradigm Capital Mgmt Inc owns 0.02% invested in Cavium, Inc. (NASDAQ:CAVM) for 3,828 shares. Integral Derivatives Llc stated it has 0.01% in Cavium, Inc. (NASDAQ:CAVM). Chase Invest Counsel Corporation reported 9,405 shares. First Personal Fin Services stated it has 0.01% of its portfolio in Cavium, Inc. (NASDAQ:CAVM). Oberweis Asset Management reported 88,140 shares stake.

The post Peak6 Investments LP Has Cut Cavium (Call) (CAVM) Holding; Profile of 3 Analysts Covering National Instruments (NATI) appeared first on Stock Market News | HillCountryTimes | Get it Today.

from Stock Market News | HillCountryTimes | Get it Today https://www.hillcountrytimes.com/2017/12/01/peak6-investments-lp-has-cut-cavium-call-cavm-holding-profile-of-3-analysts-covering-national-instruments-nati/

National Instruments – Integrated 266 MHz Real-Time Controller and 2M Gate FPGA (Model: NI cRIO-9073)

National Instruments – Integrated 266 MHz Real-Time Controller and 2M Gate FPGA (Model: NI cRIO-9073)

INO Measure Co., Ltd có khả năng tư vấn mua sắm, sử dụng, lắp đặt và cung cấp các thiết bị, dụng cụ đo lường, tự đông hoá, điện công nghiệp… Nếu bạn có nhu cầu mua sắm hoặc cần sự hỗ trợ về kỹ thuật cho một thiết bị không được liệt kê ở đây, xin vui lòng liên hệ với chúng tôi.

Hãy liên hệ với chúng tôi để được hỗ trợ tốt nhất!

Trần Công Lên 

Tel: 0906.7654.89

Email: [email protected]

MÔ TẢ SẢN PHẨM

Rugged, embedded control and monitoring system

266 MHz industrial real-time processor for control, data logging, and analysis

2M gate, 8-slot FPGA chassis for custom I/O timing, control, and processing

10/100BASE-T Ethernet port; RS232 serial port for connection to peripherals

-20 to 55 °C operating temperature range; single 19 to 30 VDC power supply input

Volume discounting available.

The NI cRIO-9073 integrated system combines a real-time processor and a reconfigurable field-programmable gate array (FPGA) within the same chassis for embedded machine control and monitoring applications. It integrates a 266 MHz industrial real-time processor with a 2M gate FPGA and has eight slots for NI C Series I/O modules. For rugged applications, it offers a -20 to 55 °C operating temperature range along with a single 19 to 30 VDC power supply input range. The cRIO-9073 features 64 MB of DRAM for embedded operation and 128 MB of nonvolatile memory for data logging. With the 10/100 Mb/s Ethernet port, you can conduct programmatic communication over the network and built-in Web (HTTP) and file (FTP) servers.

Aggressive OEM discounting is available.

Specifications Summary

GeneralProduct NamecRIO-9073Form FactorCompactRIOProduct TypeController (Computing Device)Part Number780471-01Operating System/TargetReal-TimeLabVIEW RT SupportYesCE ComplianceYesReconfigurable FPGAFPGASpartan-3Gates2000000ChassisNumber of Slots8Integrated ControllerYesInput Voltage Range19 V – 30 VRecommended Power Supply: Power48 WRecommended Power Supply: Voltage24 VPower Consumption20 WPhysical SpecificationsLength28.97 cmWidth8.81 cmHeight5.89 cmWeight929 gramMinimum Operating Temperature-20 °CMaximum Operating Temperature55 °CMaximum Altitude2000 m

Additional Product Information

Manuals  (5)

Dimensional Drawings 

Product Certifications 

View Data Sheet

Related Information

Software support and compatibility for CompactRIO

CompactRIO Developer’s Guide

Brand: APLISENS – AOIP – AECO – TAKEX – NORBAR – GEFRAN – CHROMA – ALSTRON – SYNERGYS – FLUKE – SICK – SIEMENS – HEIDENHAIN – ELCO HOLDING – ALLEN BRADLEY – BEI – KUEBLER – MTS – BALLUFF – IFM – BAUMER – PEPPERL+FUCHS – E+H – ROSEMOUNT – BERTHOLD – ABB – BURKERT – MOOG – NIDEC – YOKOGAWA – EMERSON – MITSUBISHI – SCHNEIDER – GEMU – OMRON – LEINE LINOLE – NOVOTECHNIK – FOTOELEKTRIK-PAULY – BANNER – AUTROL – YAN CLUTCH – ROTORK – REXROTH – BROOK INSTRUMENT…

from giaiphapdoluong http://giaiphapdoluong.blogspot.com/2017/11/national-instruments-integrated-266-mhz_27.html from Ino Measure CO https://inomeasureco.tumblr.com/post/168041641993

내쇼날인스트루먼트, 5G 무선 표준 연구용 모듈 출시

내쇼날인스트루먼트, 5G 무선 표준 연구용 모듈 출시

NI 5791 RF 트랜시버 어댑터 모듈은 PXI 플랫폼 상에서 NI FlexRIO FPGA 모듈과 인터페이스하며, 최고 100 MHz 송수신 대역폭과 함께 200 MHz ~ 4.4 GHz 지속 주파수 범위 제공   내쇼날인스트루먼트는 NI FlexRIO용 NI 5791 RF 트랜시버 어댑터 모듈을 출시한다고 발표했다. 이 모듈은 현재 여러 최신 연구 프로젝트에서 사용 중이며, 대표적으로 5G 기술에 적용 중이다. 이 모듈은 리얼타임 사용자 디자인 처리용 NI FlexRIO FPGA 모듈과 함께 결합되면 강력한 SDR 솔루션이 된다. PXI 플랫폼이 제공하는 트리거링 메커니즘을 통해 사용자는 8개 또는 그 이상의 트랜시버를 MIMO 및 빔 형성 설정에 동기화할 수 있다. NI 5791은 다양한 FPGA…

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Real-Time Processor

An industrial 400 MHz Freescale MPC5200 processor that deterministically acquires one’s LabVIEW Real-Time applications on the reliable Wind River VxWorks real-time operating system features the CompactRIO installed the system. Built-in operations for transferring data between the real-time processor within the CompactRIO embedded system and the FPGA are available in LabVIEW. One can pick from more than 600 built-in LabVIEW functions to frame its multithreaded installed system for real-time analysis, control, data logging, and communication. To save on development time, one can likewise combine existing C/C++ code with LabVIEW Real-Time code.

Starting a New CompactRIO Project in LabVIEW

One should commence by creating a new project in LabVIEW, where one can manage some hardware resources and code.

1.By selecting File » New Project, one creates a new project in LabVIEW.

2.Right-click on the Project feature at the top of the tree and by selecting New » Targets and Devices, one adds existing CompactRIO system to the project.

3.One can add offline systems, or discover, by this dialogue, systems on existing network. To enlarge the Real-Time CompactRIO folder, select existing system, and click OK. Note: LabVIEW might not find it on the network if the existing system is not listed. Ensure that the existing system is well configured with a valid IP address in Measurement & Automation Explorer. One can likewise select to manually enter the IP address if the existing system is on a remote subnet.

Select the Appropriate Programming Model

Two programming models are granted by LabVIEW for CompactRIO systems. If one has LabVIEW FPGA and LabVIEW Real-Time on the existing development CPU, the one can be incited to pick which programming model he/she would like to use. In the LabVIEW Project, the one can change this setting later, if needed.

Scan Interface (CompactRIO Scan Mode) option allows a person to programme the real-time processor of the already existing CompactRIO system on a computer, but not the FPGA. NI provides a pre-defined personality for the FPGA that regularly scans the I/O and allocates it in a memory map, in this mode, making it accessible to LabVIEW Real-Time. For applications that lack single-point access to I/O at rates of a few hundred hertz, CompactRIO Scan Mode is sufficient. If someone wants to learn more about scan mode, the one should read the ���Using CompactRIO Scan Mode” with “NI LabVIEW” white paper and sight the benchmarks.

LabVIEW FPGA Interface option allows a person to unlock the true power of CompactRIO throughout customising the FPGA personality in addition to the programming of the real-time processor and accomplishing performance that would typically lack custom hardware. One can implement custom triggering and timing, off-load signal analysis and processing, create custom protocols, and access I/O at its maximum rate by using LabVIEW FPGA.

After that, one should select the appropriate programming model for the existing application.

Consequently, LabVIEW will then try to detect C Series I/O modules present in the existing system and automatically add them to the LabVIEW Project and the chassis. Note: If a person’s existing system was not discovered and one chooses to add it offline, one will need to add the chassis and C Series I/O manually. For scan mode and FPGA mode, The LabVIEW Help online discusses this operation.

national Instrument – 1.33 GHz Dual-Core Controller, LX150 FPGA With Real-Time OS (Model: NI CRIO-9082 RT)

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Lưu ý: Tham khảo ý kiến của nhân viên INO sẽ giúp bạn tiết kiệm được thời gian và chi phí khi cần mua sắm. ​​Với sự tư vấn của chúng tôi, bạn sẽ không gặp khó khăn khi tìm hiểu về đặc tính của sản phẩm cần mua.

High-performance multicore system for intense embedded monitoring and control applications

1.33 GHz dual-core Intel Core i7 processor, 32 GB nonvolatile storage, 2 GB DDR3 800 MHz RAM

LabVIEW Real-Time for determinism and continuous operation reliability

1 MXI-Express, 4 USB Hi-Speed, 2 Gigabit Ethernet, and 2 serial ports for connectivity, expansion

8-slot Spartan-6 LX150 FPGA chassis for custom I/O timing, control, and processing

0 to 55 °C operating temperature range.

 The high-performance multicore NI cRIO-9082 system provides advanced Intel Core i7 dual-core processing, built-in VGA display output for an integrated user interface, and the option to use a Microsoft Windows Embedded Standard 7 (WES7) or LabVIEW Real-Time OS. The increased processing power of the cRIO-9082 makes it well suited to perform the advanced processing tasks required by complex applications such as machine vision and rapid control prototyping. Choose LabVIEW Real-Time to take advantage of deterministic execution and the highest degree of reliability in continuous operation environments. The high-performance multicore cRIO-9082 also offers the widest array of connectivity and expansion options available in the CompactRIO platform, including the high-bandwidth and low-latency MXI-Express bus for expansion using the 14-slot MXI-Express RIO chassis.

Specifications Summary

General Product Name cRIO-9082 Form Factor CompactRIO Product Type Controller (Computing Device) Part Number 781787-12 , 781787-02 Operating System/Target Real-Time , Windows Embedded Standard 7 LabVIEW RT Support Yes CE Compliance Yes Operating Relative Humidity 10 % – 90 % Product Certifications RoHS , C-Tick , FCC Part 15 , UL – Hazardous Locations , UL – Product Safety , WEEE , CE , Demko or VDE , IEC RoHS Compliant Yes Power Requirements 75 W Reconfigurable FPGA FPGA Spartan-6 Specific FPGA Spartan-6 LX150 Chassis Number of Slots 8 Integrated Controller Yes Input Voltage Range 9 V – 30 V Recommended Power Supply: Power 100 W Recommended Power Supply: Voltage 24 V Power Consumption 75 W Bus Interface USB Specification USB 2.0 Hi-Speed Shock and Vibration Operational Shock 50 g Random Operating Frequency Range 10 Hz – 500 Hz Random Vibration 5 g Sinusoidal Operating Frequency Range 10 Hz – 500 Hz Sinusoidal Vibration 5 g Physical Specifications Length 403.7 mm Width 87.1 mm Height 121.9 mm Weight 3.1 kilogram Minimum Operating Temperature 0 °C Maximum Operating Temperature 55 °C Minimum Storage Temperature -40 °C Maximum Storage Temperature 85 °C Maximum Altitude 2000 m

Resource & Download

Additional Product Information

Manuals  (6)

Dimensional Drawings  

Product Certifications  

Related Information

NI CompactRIO Home Page

Introducing High-Performance Multicore NI CompactRIO

Top 5 Considerations When Choosing an Embedded OS for NI CompactRIO

What Is Microsoft Windows Embedded Standard 7?

NI LabVIEW FPGA Compile Cloud Service

NI Graphical System Design Calculator: Build Versus Buy

Software Support and Compatibility for CompactRIO

Lưu ý: Nếu một thiết bị nào đó không được liệt kê ở đây, điều đó không có nghĩa rằng chúng tôi không hỗ trợ được bạn về thiết bị đó. Hãy liên hệ với chúng tôi để biết danh sách đầy đủ về thiết bị mà chúng tôi có thể hỗ trợ và cung cấp.

INO: Bán, Báo giá, tư vấn mua sắm và cung cấp, tư vấn sản phẩm thay thế; tương đương, hướng dẫn sử dụng, giá…VNĐ, …USD [email protected] | 02873000184 | national Instrument – 1.33 GHz Dual-Core Controller, LX150 FPGA With Real-Time OS (Model: NI CRIO-9082 RT).

Calibrator http://www.calibrator.vn/khac-do-luong-kiem-tra/national-instrument-1-33-ghz-dual-core-controller-lx150-fpga-with-real-time-os-model-ni-crio-9082-rt/

National Instruments – 1.06 GHz Dual-Core Controller and LX75 FPGA With Windows OS (Model: NI cRIO-9081)

Vui lòng liên hệ với chúng tôi– chúng tôi sẽ liên hệ lại với khách hàng bằng điện thoại hoặc email.

Lưu ý: Tham khảo ý kiến của nhân viên INO sẽ giúp bạn tiết kiệm được thời gian và chi phí khi cần mua sắm. ​​Với sự tư vấn của chúng tôi, bạn sẽ không gặp khó khăn khi tìm hiểu về đặc tính của sản phẩm cần mua.

High-performance multicore system for intense embedded monitoring and control applications

1.06 GHz dual-core Intel Celeron processor, 16 GB nonvolatile storage, 2 GB DDR3 800 MHz RAM

1 MXI-Express, 4 USB Hi-Speed, 2 Gigabit Ethernet, and 2 serial ports for connectivity, expansion

8-slot Spartan-6 LX75 FPGA chassis for custom I/O timing, control, and processing

Microsoft Windows Embedded Standard 7 and VGA graphics for a built-in user interface

0 °C to 55 °C operating temperature range.

 The high-performance multicore NI cRIO-9081 system provides advanced Intel Celeron dual-core processing, built-in VGA display output for an integrated user interface, and the option to use a Microsoft Windows Embedded Standard 7 (WES7) or LabVIEW Real-Time OS. The increased processing power of the cRIO-9081 makes it well suited to perform the advanced processing tasks required by complex applications such as machine vision and rapid control prototyping. Choose WES7 on the cRIO-9081 and take advantage of the extensive Windows ecosystem of software and display capabilities made possible by LabVIEW software. The high-performance multicore cRIO-9081 also offers the widest array of connectivity and expansion options available in the CompactRIO platform, including the high-bandwidth and low-latency MXI-Express bus for expansion using the 14-slot MXI-Express RIO chassis.

Resource & Download

Additional Product Information

Manuals  (6)

Dimensional Drawings  

Product Certifications  

Related Information

NI CompactRIO Home Page

Introducing High-Performance Multicore NI CompactRIO

Top 5 Considerations When Choosing an Embedded OS for NI CompactRIO

What Is Microsoft Windows Embedded Standard 7?

Developing Applications for Windows-Based CompactRIO

LabVIEW FPGA Compile Farm: FPGA Compilation On-Site or in the Cloud

Getting Started With the LabVIEW FPGA Compile Cloud Service

NI Graphical System Design Calculator: Build Versus Buy

Software Support and Compatibility for CompactRIO

CompactRIO Developer's Guide

Lưu ý: Nếu một thiết bị nào đó không được liệt kê ở đây, điều đó không có nghĩa rằng chúng tôi không hỗ trợ được bạn về thiết bị đó. Hãy liên hệ với chúng tôi để biết danh sách đầy đủ về thiết bị mà chúng tôi có thể hỗ trợ và cung cấp.

INO: Bán, Báo giá, tư vấn mua sắm và cung cấp, tư vấn sản phẩm thay thế; tương đương, hướng dẫn sử dụng, giá…VNĐ, …USD [email protected] | 02873000184 | National Instruments – 1.06 GHz Dual-Core Controller and LX75 FPGA With Windows OS (Model: NI cRIO-9081).

Calibrator http://www.calibrator.vn/khac-do-luong-kiem-tra/national-instruments-1-06-ghz-dual-core-controller-and-lx75-fpga-with-windows-os-model-ni-crio-9081/

National Instruments – Integrated 400 MHz Real-Time Controller and LX45 FPGA (Model: NI cRIO-9076)

Vui lòng liên hệ với chúng tôi– chúng tôi sẽ liên hệ lại với khách hàng bằng điện thoại hoặc email.

Lưu ý: Tham khảo ý kiến của nhân viên INO sẽ giúp bạn tiết kiệm được thời gian và chi phí khi cần mua sắm. ​​Với sự tư vấn của chúng tôi, bạn sẽ không gặp khó khăn khi tìm hiểu về đặc tính của sản phẩm cần mua.

Rugged, embedded control and monitoring system with -20 to 55 °C operating temperature range

400 MHz industrial real-time processor for control, data logging, and analysis

4-slot LX45 FPGA chassis for custom I/O timing, control, and processing

10/100BASE-T Ethernet port, USB 2.0 port, and RS232 serial port for connection to peripherals

Single 9 to 30 VDC power supply input

Small footprint suited for OEM applications with volume discounting available

 The NI cRIO-9076 integrated system combines a real-time processor and a reconfigurable field-programmable gate array (FPGA) within the same chassis for embedded machine control and monitoring applications. It integrates a 400 MHz industrial real-time processor with an LX45 FPGA and has four slots for NI C Series I/O modules. For rugged applications, it offers a -20 to 55 °C operating temperature range along with a single 9 to 30 VDC power supply input range. The cRIO-9076 provides 256 MB of DRAM for embedded operation and 512 MB of nonvolatile memory for data logging.  The cRIO-9076 features a USB 2.0 port as well as a 10/100 Mbit/s Ethernet port that you can use to conduct programmatic communication over the network. It has built-in HTTP/FTP servers and a LabVIEW remote panel Web server for interfacing with HTML pages, files, and the user interface of embedded LabVIEW applications.  Several mounting options are available for the cRIO-9076, including desktop, panel, DIN rail, and rack mounting.  The small footprint and lower cost make the cRIO-9076 well-suited for high-volume and OEM applications. Aggressive OEM discounting is available.

Specifications Summary

General Product Name cRIO-9076 Form Factor CompactRIO Product Type Controller (Computing Device) Part Number 781716-01 Operating System/Target Real-Time LabVIEW RT Support Yes CE Compliance Yes Reconfigurable FPGA FPGA Spartan-6 LX45 Chassis Number of Slots 4 Integrated Controller Yes Input Voltage Range 9 V – 30 V Recommended Power Supply: Power 24 W Recommended Power Supply: Voltage 24 V Power Consumption 15 W Physical Specifications Length 17.81 cm Width 8.81 cm Height 5.89 cm Weight 643 gram Minimum Operating Temperature -20 °C Maximum Operating Temperature 55 °C

Resource & Download

Additional Product Information

Manuals  (5)

Dimensional Drawings  

Product Certifications  

View Data Sheet

Related Information

NI CompactRIO Home Page

Prototyping to Deployment With NI CompactRIO

NI Graphical System Design Calculator: Build Versus Buy

NI LabVIEW for Industrial Measurements and Control Applications

Software Support and Compatibility for CompactRIO

CompactRIO Developer's Guide

Lưu ý: Nếu một thiết bị nào đó không được liệt kê ở đây, điều đó không có nghĩa rằng chúng tôi không hỗ trợ được bạn về thiết bị đó. Hãy liên hệ với chúng tôi để biết danh sách đầy đủ về thiết bị mà chúng tôi có thể hỗ trợ và cung cấp.

INO: Bán, Báo giá, tư vấn mua sắm và cung cấp, tư vấn sản phẩm thay thế; tương đương, hướng dẫn sử dụng, giá…VNĐ, …USD [email protected] | 02873000184 | National Instruments – Integrated 400 MHz Real-Time Controller and LX45 FPGA (Model: NI cRIO-9076).

Calibrator http://www.calibrator.vn/data-acquisition-system/national-instruments-integrated-400-mhz-real-time-controller-and-lx45-fpga-model-ni-crio-9076/

National Instruments – Integrated 400 MHz Real-Time Controller and LX25 FPGA (model: NI cRIO-9075)

Vui lòng liên hệ với chúng tôi– chúng tôi sẽ liên hệ lại với khách hàng bằng điện thoại hoặc email.

Lưu ý: Tham khảo ý kiến của nhân viên INO sẽ giúp bạn tiết kiệm được thời gian và chi phí khi cần mua sắm. ​​Với sự tư vấn của chúng tôi, bạn sẽ không gặp khó khăn khi tìm hiểu về đặc tính của sản phẩm cần mua.

Rugged, embedded control and monitoring system with -20 to 55 °C operating temperature range

400 MHz industrial real-time processor for control, data logging, and analysis

4-slot LX25 FPGA chassis for custom I/O timing, control, and processing

10/100BASE-T Ethernet port; RS232 serial port for connection to peripherals

Single 9 to 30 VDC power supply input

Small footprint suited for OEM applications with volume discounting available.

 The NI cRIO-9075 integrated system combines a real-time processor and a reconfigurable field-programmable gate array (FPGA) within the same chassis for embedded machine control and monitoring applications. It integrates a 400 MHz industrial real-time processor with an LX25 FPGA and has four slots for NI C Series I/O modules. For rugged applications, it offers a -20 to 55 °C operating temperature range along with a single 9 to 30 VDC power supply input range. The cRIO-9075 features 128 MB of DRAM for embedded operation and 256 MB of nonvolatile memory for data logging. With the 10/100 Mbit/s Ethernet port, you can conduct programmatic communication over the network, and the built-in Web (HTTP) and file (FTP) servers enable interfacing with HTML pages, files, and the user interface of embedded LabVIEW applications.  Several mounting options are available for the cRIO-9075, including desktop, panel, DIN rail, and rack mounting.  The small footprint and lower cost make the cRIO-9075 well-suited for high-volume and OEM applications. Aggressive OEM discounting is available.

Specifications Summary

General Product Name cRIO-9075 Form Factor CompactRIO Product Type Controller (Computing Device) Part Number 781715-01 Operating System/Target Real-Time LabVIEW RT Support Yes CE Compliance Yes Reconfigurable FPGA FPGA Spartan-6 LX25 Chassis Number of Slots 4 Integrated Controller Yes Input Voltage Range 9 V – 30 V Recommended Power Supply: Power 24 W Recommended Power Supply: Voltage 24 V Power Consumption 15 W Physical Specifications Length 17.81 cm Width 8.81 cm Height 5.89 cm Weight 643 gram Minimum Operating Temperature -20 °C Maximum Operating Temperature 55 °C

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Additional Product Information

Manuals  (5)

Dimensional Drawings  

Product Certifications  

View Data Sheet

Related Information

NI CompactRIO Home Page

Prototyping to Deployment With CompactRIO

NI Graphical System Design Calculator: Build Versus Buy

NI LabVIEW for Industrial Measurements and Control Applications

Software Support and Compatibility for CompactRIO

CompactRIO Developer's Guide

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