Please use this identifier to cite or link to this item: http://localhost/handle/Hannan/223351
Title: A Time-Walk Correction Method for PET Detectors Based on Leading Edge Discriminators
Authors: Junwei Du;Jeffrey P. Schmall;Martin S. Judenhofer;Kun Di;Yongfeng Yang;Simon R. Cherry
Year: 2017
Publisher: IEEE
Abstract: The leading edge timing pick-off technique is the simplest timing extraction method for PET detectors. Due to the inherent time-walk of the leading edge technique, corrections should be made to improve timing resolution, especially for time-of-flight PET. Time-walk correction can be done by utilizing the relationship between the threshold crossing time and the event energy on an event-by-event basis. In this paper, a time-walk correction method is proposed and evaluated using timing information from two identical detectors both using leading edge discriminators. This differs from other techniques that use an external dedicated reference detector, such as a fast PMT-based detector using constant fraction techniques to pick-off timing information. In our proposed method, one detector was used as reference detector to correct the time-walk of the other detector. Time-walk in the reference detector was minimized by using events within a small energy window (508.5-513.5 keV). To validate this method, a coincidence detector pair was assembled using two SensL MicroFB SiPMs and two 2.5 mm &x00D7; 2.5 mm &x00D7; 20 mm polished lutetium-yttrium oxyorthosilicate crystals. Coincidence timing resolutions (CTRs) using different time pickoff techniques were obtained at a bias voltage of 27.5 V and a fixed temperature of 20 &x00B0;C. The CTR without time-walk correction were 389.0 &x00B1; 12.0 ps (425-650 keV energy window) and 670.2 &x00B1; 16.2 ps (250-750 keV energy window). The timing resolution with time-walk correction improved to 367.3 &x00B1; 0.5 ps (425-650 keV) and 413.7 &x00B1; 0.9 ps (250-750 keV). For comparison, timing resolutions were 442.8 &x00B1; 12.8 ps (425-650 keV) and 476.0 &x00B1; 13.0 ps (250-750 keV) using constant fraction techniques, and 367.3 &x00B1; 0.4 ps (425-650 keV) and 413.4 &x00B1; 0.9 ps (250-750 keV) using a reference detector based on the constant fraction technique. These results show that the proposed leading edge-based time-walk correction method works well. Timing resolution obtained using this method was equivalent to that obtained using a reference detector and was better than that obtained using constant fraction discriminators.
URI: http://localhost/handle/Hannan/223351
volume: 1
issue: 5
More Information: 385,
390
Appears in Collections:2017

Files in This Item:
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7979575.pdf887.01 kBAdobe PDF
Title: A Time-Walk Correction Method for PET Detectors Based on Leading Edge Discriminators
Authors: Junwei Du;Jeffrey P. Schmall;Martin S. Judenhofer;Kun Di;Yongfeng Yang;Simon R. Cherry
Year: 2017
Publisher: IEEE
Abstract: The leading edge timing pick-off technique is the simplest timing extraction method for PET detectors. Due to the inherent time-walk of the leading edge technique, corrections should be made to improve timing resolution, especially for time-of-flight PET. Time-walk correction can be done by utilizing the relationship between the threshold crossing time and the event energy on an event-by-event basis. In this paper, a time-walk correction method is proposed and evaluated using timing information from two identical detectors both using leading edge discriminators. This differs from other techniques that use an external dedicated reference detector, such as a fast PMT-based detector using constant fraction techniques to pick-off timing information. In our proposed method, one detector was used as reference detector to correct the time-walk of the other detector. Time-walk in the reference detector was minimized by using events within a small energy window (508.5-513.5 keV). To validate this method, a coincidence detector pair was assembled using two SensL MicroFB SiPMs and two 2.5 mm &x00D7; 2.5 mm &x00D7; 20 mm polished lutetium-yttrium oxyorthosilicate crystals. Coincidence timing resolutions (CTRs) using different time pickoff techniques were obtained at a bias voltage of 27.5 V and a fixed temperature of 20 &x00B0;C. The CTR without time-walk correction were 389.0 &x00B1; 12.0 ps (425-650 keV energy window) and 670.2 &x00B1; 16.2 ps (250-750 keV energy window). The timing resolution with time-walk correction improved to 367.3 &x00B1; 0.5 ps (425-650 keV) and 413.7 &x00B1; 0.9 ps (250-750 keV). For comparison, timing resolutions were 442.8 &x00B1; 12.8 ps (425-650 keV) and 476.0 &x00B1; 13.0 ps (250-750 keV) using constant fraction techniques, and 367.3 &x00B1; 0.4 ps (425-650 keV) and 413.4 &x00B1; 0.9 ps (250-750 keV) using a reference detector based on the constant fraction technique. These results show that the proposed leading edge-based time-walk correction method works well. Timing resolution obtained using this method was equivalent to that obtained using a reference detector and was better than that obtained using constant fraction discriminators.
URI: http://localhost/handle/Hannan/223351
volume: 1
issue: 5
More Information: 385,
390
Appears in Collections:2017

Files in This Item:
File SizeFormat 
7979575.pdf887.01 kBAdobe PDF
Title: A Time-Walk Correction Method for PET Detectors Based on Leading Edge Discriminators
Authors: Junwei Du;Jeffrey P. Schmall;Martin S. Judenhofer;Kun Di;Yongfeng Yang;Simon R. Cherry
Year: 2017
Publisher: IEEE
Abstract: The leading edge timing pick-off technique is the simplest timing extraction method for PET detectors. Due to the inherent time-walk of the leading edge technique, corrections should be made to improve timing resolution, especially for time-of-flight PET. Time-walk correction can be done by utilizing the relationship between the threshold crossing time and the event energy on an event-by-event basis. In this paper, a time-walk correction method is proposed and evaluated using timing information from two identical detectors both using leading edge discriminators. This differs from other techniques that use an external dedicated reference detector, such as a fast PMT-based detector using constant fraction techniques to pick-off timing information. In our proposed method, one detector was used as reference detector to correct the time-walk of the other detector. Time-walk in the reference detector was minimized by using events within a small energy window (508.5-513.5 keV). To validate this method, a coincidence detector pair was assembled using two SensL MicroFB SiPMs and two 2.5 mm &x00D7; 2.5 mm &x00D7; 20 mm polished lutetium-yttrium oxyorthosilicate crystals. Coincidence timing resolutions (CTRs) using different time pickoff techniques were obtained at a bias voltage of 27.5 V and a fixed temperature of 20 &x00B0;C. The CTR without time-walk correction were 389.0 &x00B1; 12.0 ps (425-650 keV energy window) and 670.2 &x00B1; 16.2 ps (250-750 keV energy window). The timing resolution with time-walk correction improved to 367.3 &x00B1; 0.5 ps (425-650 keV) and 413.7 &x00B1; 0.9 ps (250-750 keV). For comparison, timing resolutions were 442.8 &x00B1; 12.8 ps (425-650 keV) and 476.0 &x00B1; 13.0 ps (250-750 keV) using constant fraction techniques, and 367.3 &x00B1; 0.4 ps (425-650 keV) and 413.4 &x00B1; 0.9 ps (250-750 keV) using a reference detector based on the constant fraction technique. These results show that the proposed leading edge-based time-walk correction method works well. Timing resolution obtained using this method was equivalent to that obtained using a reference detector and was better than that obtained using constant fraction discriminators.
URI: http://localhost/handle/Hannan/223351
volume: 1
issue: 5
More Information: 385,
390
Appears in Collections:2017

Files in This Item:
File SizeFormat 
7979575.pdf887.01 kBAdobe PDF