Quadrature Imbalance Compensation With Ellipse-Fitting Methods for Microwave Radar Physiological Sensing

Zakrzewski, Mari; Singh, Aditya; Yavari, Ehsan; Gao, Xiaomeng; Borić–Lubecke, Olga; Vanhala, Jukka; Palovuori, Karri

doi:10.1109/tmtt.2014.2321738

Cited by 56 publications

(16 citation statements)

References 25 publications

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“…Several subsequent optional calibration steps minimize the remaining absolute measurement error, e.g., by applying ellipse fitting algorithms (Singh et al, 2013;Zakrzewski et al, 2014;Linz et al, 2014) or polynomial approximation based error correction (Will et al, 2017a;Vinci et al, 2011;AOlopade and Helaoui, 2014), or by utilizing a look-up table (Vinci et al, 2011). Thus, the importance of repeatability as a figure of merit increases, which is typically analyzed by evaluating the standard deviation at each calibration point.…”

Section: Measurement Resultsmentioning

confidence: 99%

“…An orthogonalization of the elliptical shape had been investigated in preliminary experiments which yield best results by minimizing the I/Q offset. Furthermore, several algorithms for estimating and reconstructing elliptic I/Q representations have already been published (Singh et al, 2013;Zakrzewski et al, 2014;Linz et al, 2014).…”

Section: I/q Offset Cancelationmentioning

confidence: 99%

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A 24 GHz Waveguide based Radar System using an Advanced Algorithm for I/Q Offset Cancelation

et al. 2017

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Abstract. Precise position measurement with micrometer accuracy plays an important role in modern industrial applications. Herewith, a guided wave Six-Port interferometric radar system is presented. Due to limited matching and discontinuities in the radio frequency part of the system, the designers have to deal with DC offsets. The offset voltages in the baseband lead to worse relative modulation dynamics relating to the full scale range of the analog-to-digital converters and thus, considerably degrade the system performance. While common cancelation techniques try to estimate and extinguish the DC offsets directly, the proposed radar system is satisfied with equalizing both DC offsets for each of the two differential baseband signal pairs. Since the complex representation of the baseband signals is utilized for a subsequent arctangent demodulation, the proposed offset equalization implicates a centering of the in-phase and quadrature (I/Q) components of the received signal, which is sufficient to simplify the demodulation and improve the phase accuracy. Therefore, a standard Six-Port radar system is extended and a variable phase shifter plus variable attenuators are inserted at different positions. An intelligent algorithm adjusts these configurable components to achieve optimal I/Q offset cancelation.

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Section: Measurement Resultsmentioning

confidence: 99%

Section: I/q Offset Cancelationmentioning

confidence: 99%

A 24 GHz Waveguide based Radar System using an Advanced Algorithm for I/Q Offset Cancelation

et al. 2017

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“…For an Indented Radar setup, these techniques will become error prone because of mismatches such as amplitude, DC and phase imbalances. Even though there are many ellipse based fitting techniques to compensate for mismatch errors but most of these calibrations is a one time process [22,23]. To do them repeatedly in real time scenario would be challenging as the mismatch in a Indented Radar would be prominent and unpredictable.…”

Section: Prior Art On Combining I and Q Channelmentioning

confidence: 99%

Novel Approach for Vibration Detection Using Indented Radar

Gigie¹,

Rani²,

Sinharay³

et al. 2018

PIER C

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Non-contact vibration detection using microwave radar is becoming a popular research area. However, vibration sensing using Doppler radar based measurements suffers from the problem of 'Null point'. In order to mitigate this, traditional designs incorporate phase measurements using Quadrature (I/Q) radar. Such Quadrature radars are not cost effective for large scale indoor deployment scenarios. In this paper, we propose a new configuration of 'Indented Radar'; a system of two single-channel radars offset in space by a path length, which is equivalent to 90 degree phase shift. However, such a system of two independent channels is prone to different imbalances such as amplitude, phase and DC. This work closely examines the imbalance effect on the two-radar system and reports a novel approach that can be used to tackle such imbalance in a two-radar configuration. Our approach yields superior results over other commonly used I/Q algorithms, while measuring vibrational frequencies. Thus, our work can find immense application in both vital sign detection and structural vibration detection use-cases where affordable solution is sought.

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“…Researchers later developed more advanced demodulation techniques including the complex demodulation [ 54 ] and the arctangent demodulation [ 55 ]. Other signal processing methods such as adaptive DC calibration [ 17 , 56 ], noise cancellation [ 57 ], distortion cancellation [ 58 ], and I / Q mismatch mitigation [ 59 , 60 ] have been proposed to make radar systems robust enough for practical applications. This paper reviews the recent technical advances in CW Doppler radar sensors for healthcare applications, including system hardware improvement, digital signal processing, and chip integration.…”

Section: Introductionmentioning

confidence: 99%

Short-Range Noncontact Sensors for Healthcare and Other Emerging Applications: A Review

2016

Sensors

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Short-range noncontact sensors are capable of remotely detecting the precise movements of the subjects or wirelessly estimating the distance from the sensor to the subject. They find wide applications in our day lives such as noncontact vital sign detection of heart beat and respiration, sleep monitoring, occupancy sensing, and gesture sensing. In recent years, short-range noncontact sensors are attracting more and more efforts from both academia and industry due to their vast applications. Compared to other radar architectures such as pulse radar and frequency-modulated continuous-wave (FMCW) radar, Doppler radar is gaining more popularity in terms of system integration and low-power operation. This paper reviews the recent technical advances in Doppler radars for healthcare applications, including system hardware improvement, digital signal processing, and chip integration. This paper also discusses the hybrid FMCW-interferometry radars and the emerging applications and the future trends.

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Quadrature Imbalance Compensation With Ellipse-Fitting Methods for Microwave Radar Physiological Sensing

Cited by 56 publications

References 25 publications

A 24 GHz Waveguide based Radar System using an Advanced Algorithm for I/Q Offset Cancelation

A 24 GHz Waveguide based Radar System using an Advanced Algorithm for I/Q Offset Cancelation

Novel Approach for Vibration Detection Using Indented Radar

Short-Range Noncontact Sensors for Healthcare and Other Emerging Applications: A Review

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