Detailed Analysis and Modeling of Phase Noise and Systematic Phase Distortions in FMCW Radar Systems

Tschapek, Peter; Korner, Georg; Carlowitz, Christian; Vossiek, Martin

doi:10.1109/jmw.2022.3195574

Cited by 8 publications

(5 citation statements)

References 31 publications

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“…Consequently, the measured beat frequency utilized for range determination may be affected, resulting in estimation errors and contributing to overall range inaccuracies. Extensive analysis of phase noise’s influence on FMCW systems is presented in [ 31 , 32 , 33 , 34 ]. The cumulative phase noise of the designed PLL is estimated and visualized in Figure 10 .…”

Section: Harmonic Radar Realizationmentioning

confidence: 99%

Harmonic FMCW Radar System: Passive Tag Detection and Precise Ranging Estimation

El-Awamry,

Zheng,

Kaiser

et al. 2024

Sensors

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This paper details the design and implementation of a harmonic frequency-modulated continuous-wave (FMCW) radar system, specialized in detecting harmonic tags and achieving precise range estimation. Operating within the 2.4–2.5 GHz frequency range for the forward channel and 4.8–5.0 GHz for the backward channel, this study delves into the various challenges faced during the system’s realization. These challenges include selecting appropriate components, calibrating the system, processing signals, and integrating the system components. In addition, we introduce a single-layer passive harmonic tag, developed specifically for assessing the system, and provide an in-depth theoretical analysis and simulation results. Notably, the system is characterized by its low power consumption, making it particularly suitable for short-range applications. The system’s efficacy is further validated through experimental evaluations in a real-world indoor environment across multiple tag positions. Our measurements underscore the system’s robust ranging accuracy and its ability to mitigate self-interference, showcasing its significant potential for applications in harmonic tag detection and ranging.

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Section: Harmonic Radar Realizationmentioning

confidence: 99%

Harmonic FMCW Radar System: Passive Tag Detection and Precise Ranging Estimation

El-Awamry,

Zheng,

Kaiser

et al. 2024

Sensors

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“…As soon as a target can be resolved, the measurement precision and especially the accuracy of the measured distance, angle, and velocity values are orders of magnitude better than the resolution limits in a well-designed and well-calibrated radar. The possible accuracy can be estimated via the Cramer Rao lower bound, which is influenced by the radar resolution; however, ultimately, it is limited only by the signal-to-noise ratio of the baseband signal [39], [40].…”

Section: Oscillator Mixermentioning

confidence: 99%

A Review and Tutorial on Machine Learning-Enabled Radar-Based Biomedical Monitoring

Krauss,

Engel,

Ott

et al. 2024

IEEE Open J. Eng. Med. Biol.

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Radio detection and ranging-based (radar) sensing offers unique opportunities for biomedical monitoring and can help overcome the limitations of currently established solutions. Due to its contactless and unobtrusive measurement principle, it can facilitate the longitudinal recording of human physiology and can help to bridge the gap from laboratory to real-world assessments. However, radar sensors typically yield complex and multidimensional data that are hard to interpret without domain expertise. Machine learning (ML) algorithms can be trained to extract meaningful information from radar data for medical experts, enhancing not only diagnostic capabilities but also contributing to advancements in disease prevention and treatment. However, until now, the two aspects of radar-based data acquisition and MLbased data processing have mostly been addressed individually and not as part of a holistic and end-to-end data analysis pipeline. For this reason, we present a tutorial on radar-based ML applications for biomedical monitoring that equally emphasizes both dimensions. We highlight the fundamentals of radar and ML theory, data acquisition and representation and outline categories of clinical relevance. Since the contactless and unobtrusive nature of radar-based sensing also raises novel ethical concerns regarding biomedical monitoring, we additionally present a discussion that carefully addresses the ethical aspects of this novel technology, particularly regarding data privacy, ownership, and potential biases in ML algorithms.

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“…In the radar transmitter, the VCO and PLL are usually subject to limitations in component performance, leading to issues such as frequency offset and phase noise. Particularly during frequency modulation, if the phase-locked loop fails to fully converge, signal frequency may fluctuate [ 23 , 24 ]. Frequency multipliers and power dividers have a minor impact on the signal transmission efficiency and the power of the output signal.…”

Section: Principles Of Autonomous Driving Radarmentioning

confidence: 99%

An Overview of Millimeter-Wave Radar Modeling Methods for Autonomous Driving Simulation Applications

Huang,

Ding,

Deng

2024

Sensors

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Autonomous driving technology is considered the trend of future transportation. Millimeter-wave radar, with its ability for long-distance detection and all-weather operation, is a key sensor for autonomous driving. The development of various technologies in autonomous driving relies on extensive simulation testing, wherein simulating the output of real radar through radar models plays a crucial role. Currently, there are numerous distinctive radar modeling methods. To facilitate the better application and development of radar modeling methods, this study first analyzes the mechanism of radar detection and the interference factors it faces, to clarify the content of modeling and the key factors influencing modeling quality. Then, based on the actual application requirements, key indicators for measuring radar model performance are proposed. Furthermore, a comprehensive introduction is provided to various radar modeling techniques, along with the principles and relevant research progress. The advantages and disadvantages of these modeling methods are evaluated to determine their characteristics. Lastly, considering the development trends of autonomous driving technology, the future direction of radar modeling techniques is analyzed. Through the above content, this paper provides useful references and assistance for the development and application of radar modeling methods.

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Detailed Analysis and Modeling of Phase Noise and Systematic Phase Distortions in FMCW Radar Systems

Cited by 8 publications

References 31 publications

Harmonic FMCW Radar System: Passive Tag Detection and Precise Ranging Estimation

Harmonic FMCW Radar System: Passive Tag Detection and Precise Ranging Estimation

A Review and Tutorial on Machine Learning-Enabled Radar-Based Biomedical Monitoring

An Overview of Millimeter-Wave Radar Modeling Methods for Autonomous Driving Simulation Applications

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