Measurement of the temporal and spatial temperature distribution on the surface of PVCP tissue phantom illuminated by laser.
Description
Application of laboratory set-up for characterisation of thermal properties of optical tissue phantoms during laser irradiation is presented. The produced system utilizes thermographic camera VIGOcam v50 and dermatological laser system with a 975 nm diode laser module. The set-up was used to perform measurements of the temporal and spatial temperature distribution on the phantoms surface. The VIGOcam v50 thermal imaging camera allows for measurement of temperature changes with a resolution of 70 mK. The study has demonstrated that this laboratory set-up can be successfully used for visualization of the spatial temperature distribution in the phantom and to evaluation of the phantom's response to laser irradiation. Spatial temperature distribution on the surface of tissue phantom is similar to Gaussian distribution, indicating a good fit of the theoretical model to the measured experimental data.
Dataset file
hexmd5(md5(part1)+md5(part2)+...)-{parts_count}
where a single part of the file is 512 MB in size.Example script for calculation:
https://github.com/antespi/s3md5
File details
- License:
-
open in new tabCC BY-NCNon-commercial
- Raw data:
- Data contained in dataset was not processed.
Details
- Year of publication:
- 2021
- Verification date:
- 2021-01-21
- Creation date:
- 2016
- Dataset language:
- English
- Fields of science:
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- Automation, electronic and electrical engineering (Engineering and Technology)
- biomedical engineering (Engineering and Technology)
- DOI:
- DOI ID 10.34808/ga0d-gj04 open in new tab
- Verified by:
- Gdańsk University of Technology
Keywords
- IR thermography
- lasers in medicine
- thermal properties of tissues
- optical skin phantoms
- tissue-mimicking phantoms
References
- publication Multi-layered tissue head phantoms for noninvasive optical diagnostics
- publication Measurements of fundamental properties of homogeneous tissue phantoms
- publication Nanoparticle-free tissue-mimicking phantoms with intrinsic scattering
- publication Nanodiamond phantoms mimicking human liver: perspective to calibration of T1 relaxation time in magnetic resonance imaging
- dataset Optical Parameters Stability Over Time of Porous Phantoms Mimicking Tissues
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