SITRANS LR200 is a 2-wire, 6 GHz pulse radar level transmitter for continuous monitoring of liquids and slurries in process vessels including high temperature, pressure, agitation, and turbulence, to a range of
SITRANS LR200 is a 2-wire, 6 GHz pulse radar level transmitter for continuous monitoring of liquids and slurries in process vessels including high temperature, pressure, agitation, and turbulence, to a range of 20 m (65 ft). SITRANS LR250 is a 2-wire, 25 GHz pulse radar level transmitter...
detected objects. For example, using24GHz radar sensorsfordronesimproves soft landing and obstacle avoidance. Additionally, IoT radar sensors can also determine the direction of a moving object, speed of an object, distance and, depending on the antenna configuration, even the position of a moving...
detected objects. For example, using24GHz radar sensorsfordronesimproves soft landing and obstacle avoidance. Additionally, IoT radar sensors can also determine the direction of a moving object, speed of an object, distance and, depending on the antenna configuration, even the position of a moving...
However, the subsurface configuration in the Greenland zone, where the scattering heterogeneities are “ice pipes” produced by seasonal melting and refreezing, are unlikely to resemble those on the satellites. Therefore, unique models of subsurface structure cannot be deduced from the radar signatures...
Results for the proposed architecture are presented at the component level, and, then with transmitter and receiver in back-to-back configuration. End-to-end testing and performance analysis clearly show the X-Microwave based solutions performance and the proper operation of the designed front-end ...
nTx = radarConfiguration.NumTransmitters; txPos = getElementPosition(txArray); nRx = radarConfiguration.NumReceivers; rxPos = getElementPosition(rxArray); virtualPos = zeros(3,nTx*nRx);foriTx = 0:nTx-1 startIdx = iTx*nRx+1; endIdx = startIdx+nRx-1; ...
The frequency resolution, 1/Te, may be excellent, but the range resolution, cTe/2, is practically zero; and a radar with such a configuration will not be able to deliver useful range information. Therefore, only the frequency domain is of interest. For each value of Δf of the frequency...
% CFAR configuration example% [++++---o---++++]% o: cell under test% -: 6 guard cells% +: 8 training cellsfpks=Ncp/Nv;% Distance between DDMA peakscfar=phased.CFARDetector(...'NumGuardCells',even(ceil(fpks*0.5)),... % Use 1/2 of space between DDMA Doppler peaks as guard...
% Use the exact range of the measurement. The measurement vector for this% radar configuration is [az;rg;rr], so select the second element.tgtRg=dets{iMax}.Measurement(2);singleSweepSNR=interp1(target.ranges,availableSNR,tgtRg);predictedSNR=singleSweepSNR+coherentIntGain ...