20836416 GE Card Rack

20836416 reduces downtime, provides improved process control with high resolution and high performance data sampling for increased throughput. The new Isolated Thermocouple Analogue Input Module and Isolated Resistance Temperature Device (RTD) Module provide channel-to-channel isolation to improve performance and heat exchange capabilities and reduce downtime. The more throughput you can get through your system, the more revenue you can make. These new modules utilise high performance buses to provide higher performance and advanced diagnostics. Water/wastewater, chemical manufacturing, and oil and gas thermocouple modules provide advanced temperature input capabilities for applications where control is critical.The three most important factors in productivity are throughput, production and downtime. These new modules will go a long way to improving all of these areas. High-performance data sampling will provide better throughput because it processes critical sample information quickly. High resolution (11.1-16 bit) data provides better process control. The accuracy of your data is better and the resolution is higher, which directly contributes to the yield when you control these processes. The final step in productivity is downtime, and the new advanced diagnostics in these modules help to quickly clear faults and get processes back up and running so you can be more productive.These new modules go a long way to improving each of these areas. High-performance data sampling will provide better throughput as it quickly processes critical sample information. High resolution (11.1-16 bit) data provides better process control. The accuracy of your data is better and the resolution is higher, which directly contributes to the yield when you control these processes. The final step in productivity is downtime, and the new advanced diagnostics in these modules help to quickly clear faults and get processes back up and running so you can be more efficient.

20836416 is a three-channel, 200 MHz, 16-bit A/D, with a multi-band digital down converter (DDCS) and a digital up converter (DUC) to two 800 MHz 16-bit D/AS, XMC modules based on the XilinxKINTX Ultra Scale Fuel Component Board Assembly, which can be used in many applications. The 20836416 is designed for engineers with Digital Radio Frequency Memory (DRFM) applications, where a multi-channel input digitises the incoming RF input signal over a bandwidth of up to 80 MHz, and then generates a processed version of that RF signal as an analogue output with very low deterministic latency.The front end receives three analogue HF or if inputs on the front panel SSMC connector with converters coupled into three Texas Instruments AdS5485200 MHz, 16-bit A/D converters. These digital outputs are routed to the KINTX hyperscale FPGA for signal processing, data capture and routing to other modular resources. 20836416 and a D/A accept an actual or complex baseband data stream from the FPGA and provide inputs for upconversion, interpolation, and dual D/A layers.For DRFM radar applications, the received radar pulses are digitised and sent to an FPGA, which can apply a series of DSP algorithms before sending the modified signal back to the radar to simulate the reflected pulses. These algorithms are designed to confuse, deceive or disable the radar depending on the mission objectives. As a consistent representation of the original signal, the transmitting radar will not be able to distinguish it from other legitimate signals received and processed as targets. If the signal is stored in memory, it can be used to create false range targets behind (reactive jamming) and in front (predictive jamming) of the target. Slight modifications are made in the frequency analogue Doppler shift to create false target velocities.DRFM can also be used to create distorted phase fronts, which are necessary to counter single-pulse radar angular measurement techniques.