Россия
В работе описан принцип получения гамма-изображения на основе комптоновского рассеяния.
визуализация гамма-излучения, гамма‑изображение, комптоновская камера
1. R. Todd, J. Nightingale, D. Everett, “A proposed Gamma camera”, Nature, vol. 251, pp. 132-134, 1974.
2. V. Schonefelder et al, “The imaging Compton telescope COMPTEL on the gamma ray observatory”, IEEE Trans. Nucl. Sci., no. 31, pp. 766-70, 1984.
3. Manbir Singh, “An electronically collimated gamma camera for single photon emission computed tomography. Part 1: Theoretical considerations and design criteria”, Medical Physics, vol. 10, no. 4, pp. 421-427, 1983.
4. J.B. Martin et al, “A ring Compton scatter camera for imaging medium energy gamma rays”, IEEE Trans. Nucl. Sci., no. NS-40, 1993.
5. J.B. Martin et al, “A data acquisition system for a Ring Compton-scatter Camera”, IEEE Trans. Nucl. Sci., no. NS-41, 1994.
6. Z. He et al, “Position-sensitive single carrier CdZnTe detectors”, NIM A, no. 388, pp. 180-185, 1997.
7. L.C. Parra, “Reconstruction of cone-beam projections from Compton scattered data”, IEEE Trans. Nucl. Sci., vol. 47, no 4, 2000.
8. O.P. Ivanov et al, “The Improving of the Angular Resolution of Gamma-Ray Images of Portable Compton Camera with Special Iterational Method”, 2019 IEEE Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC), Manchester, United Kingdom, pp. 1-5, 2019.
9. Tom Hebert, Richard Leahy, Manbir Singh, “Three-dimensional maximum-likelihood reconstruction for an electronically collimated single-photon-emission imaging system”, J. Opt. Soc. Am., A 7, pp. 1305-1313, 1990.
10. Камера Polaris H100 [online]. URL: https://h3dgamma.com/H100Specs.pdf (дата обращения: 07.06.2020).
11. Камера Temporal [online]. URL: http://damavan-imaging.com/temporal-delta-compton-camera/ (дата обращения: 01.07.2020).