Please use this identifier to cite or link to this item:

Compact doppler radar system for heart rate detection

File Description SizeFormat 
M.S.Q111.H3_4193 MAY 2007_r.pdfVersion for non-UH users. Copying/Printing is not permitted2.38 MBAdobe PDFView/Open
M.S.Q111.H3_4193 MAY 2007_uh.pdfVersion for UH users2.38 MBAdobe PDFView/Open

Item Summary

Title: Compact doppler radar system for heart rate detection
Authors: Yamada, Shuhei
Issue Date: 2007
Abstract: Periodic motion, such as that resulting from cardiopulmonary activity, can be measured with a microwave Doppler radar system. This thesis focuses on the assessment of radio system requirements and critical specifications for such radar sensing systems. The fundamental limitations for transmit power, receive power and range for a functional 2.40Hz IMS band cardiopulmonary radar system were computed and measured, including free space losses, noise, and fundamental heart rate detection limits. The minimum required power for close range rate detection was also assessed. Heart rates for subjects holding their breath or breathing normally were successfully tracked for signal power levels as low as 20 nW. This is the lowest power ever reported for an ISM band CW Doppler radar for heart rate detection. These results can be extrapolated to higher power systems where obstructions and antenna gain similarly impact the signal power available for heart motion detection. A 2.40Hz microwave Doppler radar system was designed for the required assessments, with several transceiver variations fully integrated on printed circuit boards using various antenna configurations. The transceiver boards were 101.6[mm] by 111.6[mm], and included a small on-board oscillator. A multiple antenna system was used to provide more comprehensive data for advanced signal processing, and the modular system could be easily expanded. Issues and means for performance improvement of the system are also reported. Sensitivity was found to be limited by direct conversion architecture and component issues. for which several circuit configurations were explored, achieving significant DC offset and LO leakage reduction. Using DC offset cancelling, flicker noise reduction was also achieved, which significantly affects the SNR at baseband and improved the system sensitivity.
Description: Thesis (M.S.)--University of Hawaii at Manoa, 2007.
Includes bibliographical references (leaves 59-62).
x, 62 leaves, bound 29 cm
Rights: All UHM dissertations and theses are protected by copyright. They may be viewed from this source for any purpose, but reproduction or distribution in any format is prohibited without written permission from the copyright owner.
Appears in Collections:M.S. - Electrical Engineering

Please contact if you need this content in an ADA compliant alternative format.

Items in ScholarSpace are protected by copyright, with all rights reserved, unless otherwise indicated.