A MEMS accelerometer-based real-time motion-sensing module for urological diagnosis and treatment

Hongzhi Sun; Guoqing Fu; Huikai Xie

doi:10.3109/03091902.2012.753127

A MEMS accelerometer-based real-time motion-sensing module for urological diagnosis and treatment

Hongzhi Sun, Guoqing Fu, Huikai Xie^*

^*Corresponding author for this work

University of Florida

Research output: Contribution to journal › Article › peer-review

4 Citations (Scopus)

Abstract

This paper reports a real-time motion-sensing module, which is realized by incorporating multiple MEMS accelerometers into a standard Foley catheter, for assisting diagnosis and treatment of stressed urinary incontinence. The accelerometers measure the orientations of the catheter at multiple points, so the shape of the urethra and movement of the bladder neck can be tracked in real time. An algorithm for extracting tilting, position and shape information from 3-axis MEMS accelerometers has been developed. The model of measurement errors for both static and dynamic testing is also established. The experimental results indicate that the module tracks the movement of the Foley catheter successfully in a real-time environment and the absolute error for static measurement is no more than 1.1° within the operation range.

Original language	English
Pages (from-to)	127-134
Number of pages	8
Journal	Journal of Medical Engineering and Technology
Volume	37
Issue number	2
DOIs	https://doi.org/10.3109/03091902.2012.753127
Publication status	Published - 2013
Externally published	Yes

Keywords

Accelerometers
Diagnosis
Foley catheter
MEMS
SUI
Stressed urinary incontinence

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10.3109/03091902.2012.753127

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title = "A MEMS accelerometer-based real-time motion-sensing module for urological diagnosis and treatment",

abstract = "This paper reports a real-time motion-sensing module, which is realized by incorporating multiple MEMS accelerometers into a standard Foley catheter, for assisting diagnosis and treatment of stressed urinary incontinence. The accelerometers measure the orientations of the catheter at multiple points, so the shape of the urethra and movement of the bladder neck can be tracked in real time. An algorithm for extracting tilting, position and shape information from 3-axis MEMS accelerometers has been developed. The model of measurement errors for both static and dynamic testing is also established. The experimental results indicate that the module tracks the movement of the Foley catheter successfully in a real-time environment and the absolute error for static measurement is no more than 1.1° within the operation range.",

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AU - Xie, Huikai

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AB - This paper reports a real-time motion-sensing module, which is realized by incorporating multiple MEMS accelerometers into a standard Foley catheter, for assisting diagnosis and treatment of stressed urinary incontinence. The accelerometers measure the orientations of the catheter at multiple points, so the shape of the urethra and movement of the bladder neck can be tracked in real time. An algorithm for extracting tilting, position and shape information from 3-axis MEMS accelerometers has been developed. The model of measurement errors for both static and dynamic testing is also established. The experimental results indicate that the module tracks the movement of the Foley catheter successfully in a real-time environment and the absolute error for static measurement is no more than 1.1° within the operation range.

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A MEMS accelerometer-based real-time motion-sensing module for urological diagnosis and treatment

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Keywords

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