Compact single-chip W-band FMCW radar modules for commercial high-resolution sensor applications

Tessmann, A.; Kudszus, S.; Feltgen, T.; Riessle, M.; Sklarczyk, C.; Haydl, W.H.

doi:10.1109/tmtt.2002.805162

Cited by 102 publications

(26 citation statements)

References 7 publications

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“…In the proof-of-concept experiment, a frequency coverage of 28 GHz from 10 to 38 GHz, has been demonstrated using a single hardware platform. As for the electrical techniques, however, the DFS estimation is usually limited by a frequency tuning range below 10 GHz [41][42][43], which is less than that of this proposed photonic approach. At the same time, the sign of the DFSs can also be determined.…”

Section: Experiments and Resultsmentioning

confidence: 99%

Wideband Microwave Doppler Frequency Shift Measurement and Direction Discrimination Using Photonic I/Q Detection

Lü

Pan

Zou

et al. 2016

J. Lightwave Technol.

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An enhanced approach to realizing wideband microwave Doppler frequency shift (DFS) measurement and direction discrimination based on photonic in-phase and quadrature (I/Q) coherent detection is proposed and demonstrated experimentally. In the proposed approach, the DFS between the transmitted microwave signal and the received echo signal is converted into two quadrature low-frequency electrical signals through the coherent detection by using an optical hybrid and two balanced photodetectors (BPDs). The microwave DFS of interest can be estimated with an unambiguous direction, and in particular with a greatly improved resolution. Meanwhile, photonic coherent and balanced detection effectively eliminates the optical signal to signal beating interferences. In the proof-of-concept experiment, the DFSs from -90 to +90 kHz are successfully estimated for microwave signals at 10, 14, 18, and 38 GHz. The measurement errors are estimated to be less than 5.8 Hz which are an order of magnitude lower than those (i.e., 60 Hz) released before. Such results provide a high resolution for radial velocity measurement as well. In addition, the performance of the proposed approach in term of the signal-to-noise ratio and stability is discussed.Index Terms-Doppler frequency shift measurement, microwave photonics, I/Q coherent detection, optical microwave processing. 0733-8724 (c)

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Section: Experiments and Resultsmentioning

confidence: 99%

Wideband Microwave Doppler Frequency Shift Measurement and Direction Discrimination Using Photonic I/Q Detection

Lü

Pan

Zou

et al. 2016

J. Lightwave Technol.

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“…The monolithic microwave integrated circuit (MMIC) of the 94 GHz radar (shown in Fig. 4 and 5) module includes a varactor tuned VCO with injection port, very compact transmit and receive amplifiers and a single-ended resistive mixer [1][2][3][4]. The VCO approach in comparison with an upconverter approach has the advantage of much lower spurious frequencies.…”

Section: A Rf Frontendmentioning

confidence: 99%

Security assistant system combining millimetre wave radar sensors and chemical sensors

Hantscher

Hagelen

Lang

et al. 2011

2011 IEEE International Symposium on Antennas and Propagation (APSURSI)

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This contribution describes a security assistant system comprising distributed millimeter wave radar sensors and chemical sensors. The system is deployable for a wide range of security applications, e. g. passenger security checks on airports, surveillance of people crowds in mass transportation systems or in other security-sensitive areas. The system looks for body-worn hazardous chemical substances in two steps: At first, distributed chemical sensors detect traces of chemicals in a tight tunnel in which multiple persons move freely. These measurements are repeated at different locations whereby the person carrying the chemical can be determined. Afterwards, the radar module scans the person to be screened and yields as the result the exact location of the detected explosive on the body. This facilitates a time-saving manual follow-up check by security staff. In this paper, the main focus is on the system set-up and millimeter wave radars for object imaging

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“…A single antenna can reduce the module size greatly because the antenna is one of the largest components in microwave Doppler radar [8]. Also, the circulator can be replaced with a coupler, such as a Lange coupler, which can be integrated onto the semiconductor [9], [10].…”

Section: ⅰ Introductionmentioning

confidence: 99%

A Compact Ka-Band Doppler Radar Sensor for Remote Human Vital Signal Detection

Han¹,

Kim

Hong³

2012

Journal of electromagnetic engineering and science

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This paper presents a compact K-band Doppler radar sensor for human vital signal detection that uses a radar configuration with only single coupler. The proposed radar front-end configuration can reduce the chip size and the additional RF power loss. The radar front-end IC is composed of a Lange coupler, VCO, and single balanced mixer. The oscillation frequency of the VCO is from 27.3 to 27.8 GHz. The phase noise of the VCO is -91.2 dBc/Hz at a 1 MHz offset frequency, and the output power is -4.8 dBm. The conversion gain of the mixer is about 11 dB. The chip size is 0.89×1.47 mm 2 . The compact Ka-band Doppler radar system was developed in order to demonstrate remote human vital signal detection. The radar system consists of a Ka-band Doppler radar module with a 2×2 patch array antenna, baseband signal conditioning block, DAQ system, and signal processing program. The front-end module size is 2.5×2.5 cm 2 . The proposed radar sensor can properly capture a human heartbeat and respiration rate at the distance of 50 cm.

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Compact single-chip W-band FMCW radar modules for commercial high-resolution sensor applications

Cited by 102 publications

References 7 publications

Wideband Microwave Doppler Frequency Shift Measurement and Direction Discrimination Using Photonic I/Q Detection

Wideband Microwave Doppler Frequency Shift Measurement and Direction Discrimination Using Photonic I/Q Detection

Security assistant system combining millimetre wave radar sensors and chemical sensors

A Compact Ka-Band Doppler Radar Sensor for Remote Human Vital Signal Detection

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