Difference between revisions of "Temperature Estimation with Ultrasound"

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<sidebar>Temperature_Estimation_with_Ultrasound_Nav</sidebar>
 
<sidebar>Temperature_Estimation_with_Ultrasound_Nav</sidebar>
 
===Introduction===
 
===Introduction===
Research has proven that it is possible to estimate temperature from body non-invasively by observing changes in backscatter energy in an ultrasounic image of the tissue.<ref name="Arthur Paper">[http://ieeexplore.ieee.org.libproxy.wustl.edu/xpl/tocresult.jsp?reload=true&asf_pun=58&asf_in=8&asf_iv=57&asf_sp=1724], additional text.</ref>
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Research has proven that it is possible to estimate temperature from body non-invasively by observing changes in backscatter energy in an ultrasounic image of the tissue.[http://ieeexplore.ieee.org.libproxy.wustl.edu/xpl/tocresult.jsp?reload=true&asf_pun=58&asf_in=8&asf_iv=57&asf_sp=1724]
  
 
temperature (37°C) to 60°C. Our overall goal was to contribute to the extension of this research such that it temperature estimation would be possible up to 70°C. To contribute to this research, the purpose of this work was to modify MATLAB code to be capable of data acquisition for synchronous temperature measurements and ultrasonic imaging from 36°C to 70°C. In addition to modifying the code, the design of the experiment was also modified to more efficiently produce results.
 
temperature (37°C) to 60°C. Our overall goal was to contribute to the extension of this research such that it temperature estimation would be possible up to 70°C. To contribute to this research, the purpose of this work was to modify MATLAB code to be capable of data acquisition for synchronous temperature measurements and ultrasonic imaging from 36°C to 70°C. In addition to modifying the code, the design of the experiment was also modified to more efficiently produce results.
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[[The Methods |Methods]]
 
[[The Methods |Methods]]
  
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[[Haake Commands| ThermoHaake MATLAB Functions]]
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==Sources==
 
[1] R. M. Arthur, D. Basu, Y. Guo, J. W. Trobaugh, and E. Moros, "3D In Vitro Estimation of Temperature Using the Change in Backscattered Ultrasonic Energy", ''IEEE Trans. on UFFC'', vol. 57, no. 8, pp. 1724-1733, 2010.
 
[1] R. M. Arthur, D. Basu, Y. Guo, J. W. Trobaugh, and E. Moros, "3D In Vitro Estimation of Temperature Using the Change in Backscattered Ultrasonic Energy", ''IEEE Trans. on UFFC'', vol. 57, no. 8, pp. 1724-1733, 2010.

Latest revision as of 03:51, 13 May 2011

<sidebar>Temperature_Estimation_with_Ultrasound_Nav</sidebar>

Introduction

Research has proven that it is possible to estimate temperature from body non-invasively by observing changes in backscatter energy in an ultrasounic image of the tissue.[1]

temperature (37°C) to 60°C. Our overall goal was to contribute to the extension of this research such that it temperature estimation would be possible up to 70°C. To contribute to this research, the purpose of this work was to modify MATLAB code to be capable of data acquisition for synchronous temperature measurements and ultrasonic imaging from 36°C to 70°C. In addition to modifying the code, the design of the experiment was also modified to more efficiently produce results.

Experimental Setup

Methods

ThermoHaake MATLAB Functions

Sources

[1] R. M. Arthur, D. Basu, Y. Guo, J. W. Trobaugh, and E. Moros, "3D In Vitro Estimation of Temperature Using the Change in Backscattered Ultrasonic Energy", IEEE Trans. on UFFC, vol. 57, no. 8, pp. 1724-1733, 2010.