Showing results: 151 - 158 of 158 items found.
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Lynred USA
As a pioneer in infrared imaging solutions, our engineers have an unsurpassed level of proficiency in prototype design, customization and system integration. Our expertise is multifaceted ranging from advanced infrared sensor signal processing, calibration techniques, radiometry, optics, embedded software development, PC application software development, industrial and mechanical design and production tooling. Our goal is your successful project; one that utilizes the correct components and is completed on time and within budget. This is accomplished through our Concept to Solution approach which allows for the use of technically advanced components, group collaboration, quick responses and final products tested to spec. Whatever level of integration you choose and support you need, know our engineering team is there to assist.
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Test Coach Corporation
Test Coach offers Design for Test (DFT) consulting to assist customers with design review of prototype boards prior to release for production. Design for Test analysis is extremely important in ensuring that an assembly will achieve the highest possible test coverage. For ICT, this DFT will review the board to confirm that the bed-of-nails test fixture can be fabricated to test an assembly without sacrificing test coverage. As with ICT, Flying Probe benefits from DFT analysis by reviewing test point access and mechanical challenges that may affect the potential test coverage. Completing a DFT enables Test Coach to make recommendations to our customers that may be implemented on boards during the design phase which will allow for the most comprehensive coverage at time of test.
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Furaxa, Inc.
Ultraview's PCIe series of data acquisition add-in cards are complete A/D systems on a single PCIe add-in card. These boards incorporate up to 8GB of on-board RAM with up to 7GB/sec on Kintex 7 (up to 1.4GB/sec on Virtex 5) typical PCIe bus transfer rates enabling full-rate acquisition for long durations. All boards in the PCIe series are supported with the same user software allowing users to select the bit resolution and acquisition rate appropriate for a given application and then easily re-use the same software on a different part. Included with each card are graphical waveform viewers, example user software with source code included, and device drivers for Linux and Windows. The example software is intended to allow users to quickly prototype and develop their applications.
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Ultraview Corporation
Ultraview's PCIe series of data acquisition add-in cards are complete A/D systems on a single PCIe add-in card. These boards incorporate up to 8GB of on-board RAM with up to 7GB/sec on Kintex 7 (up to 1.4GB/sec on Virtex 5) typical PCIe bus transfer rates enabling full-rate acquisition for long durations. All boards in the PCIe series are supported with the same user software allowing users to select the bit resolution and acquisition rate appropriate for a given application and then easily re-use the same software on a different part. Included with each card are graphical waveform viewers, example user software with source code included, and device drivers for Linux and Windows. The example software is intended to allow users to quickly prototype and develop their applications.
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NI
The USRP-2974 is built on the LabVIEW reconfigurable I/O (RIO) architecture with an onboard Intel Core i7 processor running the NI Linux Real-Time OS. The USRP-2974 is a USRP Software Defined Radio Stand-Alone Device, meaning that you can target the onboard processor with LabVIEW Communications System Design Suite to deterministically perform processing. The USRP-2974 is also equipped with a GPS-disciplined 10 MHz oven-controlled crystal oscillator (OCXO) Reference Clock. You can prototype a range of advanced research applications that include stand-alone LTE or 802.11 device emulation; Medium Access Control (MAC) algorithm development; multiple input, multiple output (MIMO); heterogeneous networks; LTE relaying; RF compressive sampling; spectrum sensing; cognitive radio; beamforming; and direction finding. 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.
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NI
The USRP Software Defined Radio Stand-Alone Device consists of an onboard processor, FPGA, and RF front end. You can program this device using either LabVIEW Communications System Design Suite or an open-source software workflow, depending on the operating system you choose. You can provision the device with NI Linux Real-Time, Linux Fedora, or Linux Ubuntu real-time operating systems. The USRP Software Defined Radio Stand-Alone Device enables you to prototype a range of advanced research applications such as stand-alone LTE or 802.11 device emulation; Medium Access Control (MAC) algorithm development; multiple input, multiple output (MIMO); heterogeneous networks; LTE relaying; RF compressive sampling; spectrum sensing; cognitive radio; beamforming; and direction finding.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.
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Pure Engineering, llc
At Pure Engineering, we specialize in providing custom solutions to help our clients overcome their most challenging problems. Our services range from rapid prototyping to mass production of consumer products and are backed by our deep understanding of low power design, RF complexities, design for manufacturing, and product life cycles. Our team is skilled in a variety of areas, including strategic planning, product development, and architecture design. We use engineering principles to assess the feasibility and suitability of technology for a given design and can create proof-of-concepts, prototypes, and subject matter experts to solve design challenges. We also have expertise in the Internet of Things (IoT) and have experience developing low-power systems that run on batteries and efficiently transfer data. Additionally, we have extensive experience in Bluetooth Low Energy (BLE) technology, creating sensors that connect to modern phones and computers and creating custom protocols using off-the-shelf hardware. Whether you need help with a specific aspect of your project or support throughout the development process, we are here to assist you.
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NIT Laboratory
The NITOS prototype wireless sensor mote, is comprised of open-source and configurable modules. NITOS mote features the ATmega32u4 microcontroller running at 8MHz and operating at 3.3V. The aforementioned microcontroller is fully compatible with the Arduino platform that enables ease of software development and provides compatibility with several commercial sensing modules. Moreover, the platform is equipped with an Xbee radio interface that enables communication with the respective gateway. The Xbee module is a tiny device ideal for setting up mesh networks and has a defined rate of 250 kbps. This module uses the IEEE 802.15.4 stack which is the basis for theZigbee protocol. Apart from the Xbee module, NITOS mote can also feature a WiFi wireless interface in order to communicate with WiFi gateways. The developed mote currently features specific sensing modules, an air temperature and humidity sensor, a light intensity sensor and a human presencesensor. Various types of sensing modules and actuators can be further integrated exploiting existing Arduino software that implements several existing communications protocols. The firmware can be easily uploaded through the on-board USB connection. Figure 1 illustrates the developed NITOS mote and the respective gateway node.
