Design of a Low-Cost UWB Time-Domain Radar System for Subcentimeter Image Resolution

The design and development of a hybrid Gaussian pulse radar transceiver, including transmitter and receiver, is presented. The transmitter is realized using a transistor-based square pulse generator, a tunable step recovery diode (SRD) Gaussian pulse-shaping network, and a differentiator. The SRD ci...

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Bibliographic Details
Published in:IEEE transactions on microwave theory and techniques 2022-07, Vol.70 (7), p.3617-3628
Main Authors: Feghhi, Rouhollah, Winter, Robert S. C., Sabzevari, Fatemeh Modares, Rambabu, Karumudi
Format: Article
Language:English
Subjects:
Analog to digital converters
Antennas
Broadband amplifiers
Circuit design
Couplers
Data processing
Design modifications
Digitization
High pass filters
Hybrid integrated circuits
Image resolution
Low pass filters
Microprocessors
microwave Gaussian pulse generator
microwave transceiver
Mixers
Pulse duration
Pulse generation
Pulse generators
Pulse radar
Pulse repetition frequency
Radar equipment
Radar imaging
Radio frequency
Receivers & amplifiers
Receiving
Receiving antennas
Step recovery diodes
Transceivers
Transistors
Transmitters
Transmitting antennas
Ultrawideband
ultrawideband (UWB) synthetic aperture radar (SAR)
Ultrawideband radar
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Summary:The design and development of a hybrid Gaussian pulse radar transceiver, including transmitter and receiver, is presented. The transmitter is realized using a transistor-based square pulse generator, a tunable step recovery diode (SRD) Gaussian pulse-shaping network, and a differentiator. The SRD circuit design is modified using a high-pass filter to have a low ringing and narrow pulsewidth. The output pulse with a broadband amplifier has a power of 500 mW, at a pulse repetition frequency (PRF) of 10 MHz, and tunable pulsewidth ranges from 56 to 300 ps. A 90° coupler is configured to convert the Gaussian pulse into a monopulse. Then, a transmitter antenna is used to radiate the pulse, and a separate receiving antenna is used to receive the reflected pulse. The receiver is comprised of a local Gaussian pulse generator, a radio frequency mixer (RF-mixer) accompanied by a low-pass filter (LPF), a low-frequency amplifier (LFA), and an analog-to-digital converter (ADC). The RF-mixer is used for expanding the receiving pulse from the receiving antenna by a factor of 100000. The LPF and LFA are used to detect the envelope of the output of the RF-mixer and amplify it. The ADC is interposed between the LFA and a processor to digitize the expanded pulse for data processing. The validity and reliability of the digitized expanded pulse compared to those received using a sampling oscilloscope are 93% in agreement, which is remarkable. A version of the system is also developed for a single-antenna operation by utilizing an ultrawideband (UWB) coupler as a semicirculator. Both the systems are compared, and the benefits of each are illustrated. The flexibility and performance of the designs are analyzed. The proposed system demonstrates subcentimeter imaging capabilities.
ISSN:0018-9480
1557-9670
DOI:10.1109/TMTT.2022.3169794