UWB in Medicine – High Performance UWB Systems for Biomedical Diagnostics and Short Range Communications

Lin, Dayang; Mirbach, Michael; Thiasiriphet, Thanawat; Lindner, J.; Menzel, Wolfgang; Schumacher, Hermann; Leib, Mario; Schleicher, Bernd

doi:10.5772/55078

Cited by 3 publications

(2 citation statements)

References 29 publications

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“…The design of combined UWB radar and communication systems for biomedical applications was presented in [77]. Topics addressed included components for UWB radar sensors and communication systems, namely antennas and integrated circuits, signal processing, and design of bistatic UWB radar systems.…”

Section: Radar Design Considerationsmentioning

confidence: 99%

Technical Considerations in Medical Radar

Narayanan¹

2013

Proceedings of the 8th International Conference on Body Area Networks

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Medical radar is an emerging area of research and development in recent years, spurred by rapid advances in electromagnetic modeling, simulation, component development, and signal and image processing algorithms. In this paper, we review various important considerations in the design and development of medical radar systems for diagnostic applications.Most medical radar applications basically need two components: a sensor and a communication infrastructure (transceiver and protocols) to share the data gathered by the former [7]. By combining sensing and communications in the same package, UWB radar could be used to measure vital signs information, and UWB communication standards could be used to transmit these measurements to a processor. Wireless networking is necessary to transmit and share the monitored data with a central repository.It is important to ascertain which phenomenon actually impacts measured data. It was shown that body surface movements dominated remote radar measurements of heartbeat, compared to blood perfusion in the skin or internal body organ movements [8].A comprehensive list of relevant literature on medical radar is presented in [9], which includes references on general UWB radar, radar calibration, radar heartbeat and respiration measurements, medical radar systems, and medical radar imaging. DIELECTRIC PROPERTIES OF TISSUEThe dielectric properties of human tissue determine the radar reflections from different layers. Relevant data are available from several papers and reports over the past 60 years.Some of the earliest permittivity and loss measurements of various human tissues, such as skin, fat, muscle, etc. were made at centimeter wavelengths, over the 1-26 GHz frequency range [10]-

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Section: Radar Design Considerationsmentioning

confidence: 99%

Technical Considerations in Medical Radar

Narayanan¹

2013

Proceedings of the 8th International Conference on Body Area Networks

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“…The technological advancements in the miniaturization and standardization have led to the first commercial available UWB devices approved by the US Food and Drug Administration (FDA) [16][17][18]. Thereby a medical UWB system in general includes optimized antennas for radiation into human tissues [2,19,20] and integrated circuits to transmit, receive and process the signals [4,21].…”

Section: Introductionmentioning

confidence: 99%

Reflection and transmission of ultra-wideband pulses for detection of vascular pressure variation and spatial resolution within soft tissues

Mackenberg¹,

Rackebrandt

Bollmeyer³

et al. 2016

Biomed. Phys. Eng. Express

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Ultra-wideband signals have a variety of applications. An upcoming medical application is the detection of the heart rate of patients. However, current UWB systems provide poor resolution and are only able to detect vessels with a large diameter, e.g. the aorta. The detection and quantification of vascular dilation of thinner vessels is essential to develop wearable ultra-wideband based devices for real-time detection of cardiovascular conditions of the extremities. The reflection and transmission processes of those signals within inhomogeneous bodies are complex and their prediction is challenging. In this paper, we present an experimental setup (UWB system; phantom) for the detection of vascular dilation within soft tissues. Furthermore, we suggest a theoretical simulation model for the prediction of the reflection of ultra-wideband pulses and compare these simulated predictions to results of measurements within the phantom. The results verify that we are able to identify vascular dilation within the simulation model and the experimental setup, depending on the depth of the vessel (20 mm, 40 mm, 60 mm).

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