6 Results
The R&S®VSE-K6 option measures all relevant parameters such as pulse duration, pulse period, pulse rise and fall times, power drop across a pulse, and intrapulse phase modulation, and produces a trend analysis over many pulses. The user selects which results should be displayed simultaneously on the screen. The R&S®VSE thus delivers a full picture of e.g. a radar system within seconds.
This video shows how to perform pulse compression measurements with the R&S®FSW-K6S time sidelobe measurement application. video, FSW, spectrum analyzer, signal analyzer, high performance, wideband This video shows how to perform pulse compression measurements with the R&S®FSW-K6S time sidelobe measurement application.
Describes the specific functions of the application, including the remote control commands with programming examples.For information on operating the R&S®FSW see the user manual of the base unit.The online version contains the documentation for the R&S®FSW base unit and ALL options for immediate display (no download required).
The high-performance R&S®FSW signal and spectrum analyzer helps engineers accomplish the most demanding tasks. Its wide internal analysis bandwidth allows the characterization of wideband components and communications systems. Its unparalleled phase noise facilitates the development of high-performance oscillators such as those used in radars. A state-of-the-art multitouch display with gesture support ensures straightforward and intuitive operation. An embedded SCPI recorder enables easy creation of executable scripts.
The R&S®FSW signal and spectrum analyzer measures and analyzes time sidelobes to optimize compressed radar signals as well as radar hardware components and systems. Developers of radar systems can improve and immediately validate their design using automated and reproducible measurements.
22-Oct-2020
Starting with the early microwave applications for radar, the advantage of increased bandwidth has been a deciding factor in shifting toward microwave and millimeterwave (mmWave) for communications technologies. It began with satellite transmissions and then came down to earth with cable television and wireless local area networks such as Wi-Fi followed by new applications in the automotive and aerospace fields. The high bandwidth and high capacity demand of 5G – the next generation of mobile networks – also promote the trend toward ever higher frequencies in electronics.