We now learn about the radar hardware basics and then (next week) treat the digital processing of: Radar range gating, signal and noise, coherent complex digital sampling, range-time matrix, digital radar data display, coherent integration, coding /decoding complex covariance function, complex Doppler spectrum, parameter deduction. Basics of phased antenna arrays, radiation pattern calculation, radar interferometry and imaging. Finally a summary of radar methods for atmosphere and ionosphere research and explanation of some typical results, incl. coherent and incoherent scatter. We now learn about the radar hardware basics and then (next week) treat the digital processing of: Radar range gating, signal and noise, coherent complex digital sampling, range-time matrix, digital radar data display, coherent integration, coding /decoding complex covariance function, complex Doppler spectrum, parameter deduction. Basics of phased antenna arrays, radiation pattern calculation, radar interferometry and imaging. Finally a summary of radar methods for atmosphere and ionosphere research and explanation of some typical results, incl. coherent and incoherent scatter.
Radar System Design and Data Processing Radar System Design and Data Processing
The ESR Receiver - Cryo-cooled (15 K) GaAsFET preamplifier, feeding into three parallel, high dynamic range dual superhets, employing + 23 dBm balanced mixers 1st IF = 70 MHz, 2nd IF = 7.5 ± 1.8 MHz - Receiver chain 1 dedicated to ion line reception fixed at 500 ± 1.8 MHz - Chains II and 111 used for plasma line reception, tunable over 484 – 516 (± 1.8) MHz - Sample of transmitted signal detected at first mixer - 2nd IF output signals at -10 dBm digitized by continuously running10 MHz, 12 bit A/D converters - Each 10 MHz data stream fed into several digital back end channels in parallel - Detection at nonzero IF results in: DC offset, gain imbalance, quadrature phase errors and unequal filter responses are avoided altogether. - Major advantage over muIti-channel base-band detection system The ESR Receiver - Cryo-cooled (15 K) GaAsFET preamplifier, feeding into three parallel, high dynamic range dual superhets, employing + 23 dBm balanced mixers 1st IF = 70 MHz, 2nd IF = 7.5 ± 1.8 MHz - Receiver chain 1 dedicated to ion line reception fixed at 500 ± 1.8 MHz - Chains II and 111 used for plasma line reception, tunable over 484 – 516 (± 1.8) MHz - Sample of transmitted signal detected at first mixer - 2nd IF output signals at -10 dBm digitized by continuously running10 MHz, 12 bit A/D converters - Each 10 MHz data stream fed into several digital back end channels in parallel - Detection at nonzero IF results in: DC offset, gain imbalance, quadrature phase errors and unequal filter responses are avoided altogether. - Major advantage over muIti-channel base-band detection system
The ESR Antenna - 32 m shaped Cassegrain geometry, custom design - Designed, built by Kamfab-NTG-Ticra- Dielectric - high gain, 42.5 dBi at 500 MHz - low system noise temperature, 65 K at 500 MHz - low sidelobes - mechanically fast: degrees per second, can swing through 180 degrees in elevation - Dedicated real time control computer running OS-9 - Position servo loop closes numerically in computer The ESR Antenna - 32 m shaped Cassegrain geometry, custom design - Designed, built by Kamfab-NTG-Ticra- Dielectric - high gain, 42.5 dBi at 500 MHz - low system noise temperature, 65 K at 500 MHz - low sidelobes - mechanically fast: degrees per second, can swing through 180 degrees in elevation - Dedicated real time control computer running OS-9 - Position servo loop closes numerically in computer
The ESR Transmitter - Designed / built by Harris TVT, Cambridge, U.K. - Basically a combination of 4 (8) standard UHF TV transmitters, slightly modified, producing 500 kW (1 MW) at 25 % duty cycle (highest ever used in a pulsed ISR). Pulse modulator is all solid state, runs at 25 kV - Instantaneous power BW is 500 ± 2 MHz, range resolution down to 40 m can be achieved - Advanced DDS / heterodyne exciter providing - theoretically unlimited number of TX frequencies - pulse-to-pulse multi-frequency phase coherency - linear chirp (later) - possibilities for adding pseudo-random BPSK - Transmitted waveform sampled and processed by receiver: corrections for transmitter effects in the data analysis can be done exactly, not only from models (a first as a routine feature) - Designed for unattended operation The ESR Transmitter - Designed / built by Harris TVT, Cambridge, U.K. - Basically a combination of 4 (8) standard UHF TV transmitters, slightly modified, producing 500 kW (1 MW) at 25 % duty cycle (highest ever used in a pulsed ISR). Pulse modulator is all solid state, runs at 25 kV - Instantaneous power BW is 500 ± 2 MHz, range resolution down to 40 m can be achieved - Advanced DDS / heterodyne exciter providing - theoretically unlimited number of TX frequencies - pulse-to-pulse multi-frequency phase coherency - linear chirp (later) - possibilities for adding pseudo-random BPSK - Transmitted waveform sampled and processed by receiver: corrections for transmitter effects in the data analysis can be done exactly, not only from models (a first as a routine feature) - Designed for unattended operation
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LIM BLLNMIXBLIFAATT QM VA LIM LPF DC LIM IFA VA LIM BPF LIM DC LIMBLLNMIXBLIFAATT QM VALPF DCIFABPFDC LIMBLLN MIXBLIFAATT QM VALPF DC IFA BPF DC VA AMP1:4 DIV AMP 1:4 DIV IF MON1 REF (Obtained from MO) RF IN3 RF IN1 IF MON2 I-2 RF IN2 I-1 Q-3 I-3 IF MON3 Q-1 Q-2 BL SW CONTL DC SUPPLY 220 Volts AC Mains AMP 120 MHz OUT LATEST REVISION OF RECEIVER’S BLOCK DIAGRAM LO IN 120 MHz MO Generation of 120+ΔF and 150+ΔF signals 1:4 FREQ DIV MIX AMP 150 MHz OUT 30 MHz OUT NC NO LO SWITCH Default radar operation freq is 150 MHz For generation of 150+ΔF signal, LO 120+ΔF signal injected via LO IN
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MEILHAUS ME-4660S PCI DAQ CARD
The ESR Digital Signal Processor - Every four back end channels are served by a VME DSP board containing: - two T.I. TMS 320C40 DSPs (2 x 80 Mflops) - 2 x 12 MB local RAM + 16 MB of 21 global dual-port RAM - six DMA controllers + VME bus interface - DSP computes the autocovariance coefficients of the filtered sample stream, averages and stores these in lag profile format or as raw data - DSP also controls NCO and filter settings on a pulse-by-pulse basis - Data output is over dedicated 10 MB/sec DMA link into four CPU, SparcServer 1000 The ESR Digital Signal Processor - Every four back end channels are served by a VME DSP board containing: - two T.I. TMS 320C40 DSPs (2 x 80 Mflops) - 2 x 12 MB local RAM + 16 MB of 21 global dual-port RAM - six DMA controllers + VME bus interface - DSP computes the autocovariance coefficients of the filtered sample stream, averages and stores these in lag profile format or as raw data - DSP also controls NCO and filter settings on a pulse-by-pulse basis - Data output is over dedicated 10 MB/sec DMA link into four CPU, SparcServer 1000
transmitter exciter
The ESR RX Digital Back End - First known use of fully digital back end in a scientific radar receiver - Each digital back end channel contains: - a tunable numerical oscillator - a digital complex multiplier - a complex digital FIR filter / decimator - a 2 x 256 kWords ping-pong sample memory The ESR RX Digital Back End - First known use of fully digital back end in a scientific radar receiver - Each digital back end channel contains: - a tunable numerical oscillator - a digital complex multiplier - a complex digital FIR filter / decimator - a 2 x 256 kWords ping-pong sample memory
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DIAGRAM BLOK 150 MHz 1 kW T-R MODULE
TEST SETUP OF 150 MHz 1kW Transmitt MODULE
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4-PORT DISTRIBUTION SYSTEM FOR THE TX ANTENNA OF THE LAPAN-TRAINERS VHF RADAR Combiner II 1 (2,5 kW) Combiner II 2 Combiner III 10 kW Yagi antenna Combiner II 4 TX 3 kW RX TX 1 kW TX 1 kW TX 1 kW
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TRAINERS - Radar-System ( Phase 1/ Phase X ) PRP FLP RFP ADC MO 148 MHz PC Lab View Software RC Remote Control DSP Digital Signal Processing TX PA 10KW ANT ( TX ) ANT ( RX ) RX 1 φ 0/180º 0º90º 10 W100 W1 KW I Q LNA ( Phase 1) Picture 0-1 Radar System Schematic
To follow next: Radar range gating, coherent complex digital sampling, range-time matrix, digital radar data display, coherent integration, complex covariance function, complex Doppler spectrum, parameter deduction. Basics of phased antenna arrays, pattern calculation, radar interferometry. A final summary of radar methods for atmosphere and ionosphere research. To follow next: Radar range gating, coherent complex digital sampling, range-time matrix, digital radar data display, coherent integration, complex covariance function, complex Doppler spectrum, parameter deduction. Basics of phased antenna arrays, pattern calculation, radar interferometry. A final summary of radar methods for atmosphere and ionosphere research.