Channel-specific control of pulse integration in a gamma camera system in response to pulse pile-up
First Claim
1. A method of detecting radiation induced events in a radiation detector, the radiation detector including a plurality of channels, the method comprising:
- in response to a first event which affects both a first channel and a second channel of the plurality of channels, integrating data of the first channel and integrating data of the second channel; and
in response to a second event which temporally overlaps the first event and which affects the second channel but not the first channel, stopping said integrating of the data of the second channel and continuing said integrating of the data of the first channel.
4 Assignments
0 Petitions
Accused Products
Abstract
A method and apparatus for selectively integrating PMT channel signals in a gamma camera system are described. A trigger word is decoded to determine which of multiple PMT channels are affected by a given scintillation event. When two scintillation events overlap both spatially and temporally, only those channels which are affected by both events stop integrating in response to the second event. Pre-pulse pile-up is corrected by removing the tail of a preceding pulse from a current pulse using an approximation of the tail of the preceding pulse based upon the instantaneous energy of the current pulse and the current countrate. Extrapolation of the tail of the current pulse may also be performed in essentially the same manner.
66 Citations
19 Claims
-
1. A method of detecting radiation induced events in a radiation detector, the radiation detector including a plurality of channels, the method comprising:
-
in response to a first event which affects both a first channel and a second channel of the plurality of channels, integrating data of the first channel and integrating data of the second channel; and in response to a second event which temporally overlaps the first event and which affects the second channel but not the first channel, stopping said integrating of the data of the second channel and continuing said integrating of the data of the first channel. - View Dependent Claims (2, 3)
-
-
4. A method of correcting for pulse pile-up in a nuclear medicine imaging system, the imaging system including a detector, the detector including a plurality of photomultiplier tubes (PMTs), the method comprising:
in response to a first scintillation event affecting both a first PMT and a second PMT of the plurality of PMTs, integrating an output of the first PMT and integrating an output of the second PMT; in response to a second scintillation event which affects the second PMT but not the first PMT and which overlaps the first scintillation event temporally; determining that the second scintillation event affects the second PMT and not the first PMT; stopping said integrating of the output of the second PMT; and continuing said integrating of the output of the first PMT. - View Dependent Claims (5)
-
6. A method of correcting for pulse pile-up associated with a gamma camera, the gamma camera including a plurality of light detectors for detecting scintillation events, the method comprising:
-
integrating an output of each of the light detectors that is affected by a first scintillation event; determining which of the plurality of light detectors are affected by both the first and a second scintillation event, the second scintillation event overlapping the first scintillation event temporally and spatially; stopping said integrating for each of the light detectors that is affected by both the first and second scintillation events; and continuing said integrating for each of the light detectors that is affected by the first scintillation event but not the second scintillation event. - View Dependent Claims (7)
-
-
8. A method of correcting for pulse pile-up in a nuclear medicine imaging system, the imaging system including a detector, the detector including a plurality of photomultiplier tubes (PMTs), the method comprising:
-
detecting a first scintillation event; integrating an output of each of the PMTs affected by the first scintillation event; detecting a second scintillation event, the second scintillation event overlapping the first scintillation event temporally and spatially; determining which of the plurality of PMTs are affected by both the first and the second scintillation events; stopping said integrating for each of the PMTs affected by both the first and second scintillation events; and continuing said integrating for each of the PMTs affected by the first scintillation event but not the second scintillation event. - View Dependent Claims (9)
-
-
10. A method of correcting for pulse pile-up in a nuclear medicine imaging system, the nuclear medicine imaging system including a gamma ray detector, the gamma ray detector including a plurality of photomultiplier tubes (PMTs), the method comprising:
-
detecting a first scintillation event; integrating an output of each of the PMTs affected by the first scintillation event; detecting a second scintillation event, the second scintillation event overlapping the first scintillation event temporally and spatially; determining which of the plurality of PMTs are affected by both the first and the second scintillation events; stopping said integrating for each of the PMTs affected by both the first and second scintillation events; and continuing said integrating for each of the PMTs affected by the first scintillation event but not the second scintillation event; correcting a channel signal for each of the PMTs affected by both the first and second scintillation events for pulse pile-up associated with the first and second events without correcting channel signals for the PMTs not affected by the second event for said pile-up associated with the first and second events. - View Dependent Claims (11)
-
-
12. An imaging system comprising:
-
a support structure; a processing system; and a radiation detector coupled to the processing system and supported by the support structure, the radiation detector including a plurality of channels, the radiation detector configured to respond to a first event which affects both a first channel and a second channel of the plurality of channels by integrating an output of the first channel and integrating an output of the second channel, the radiation detector further configured to respond to a second event which temporally overlaps the first event and which affects the second channel but not the first channel by stopping said integrating of the output of the second channel and continuing said integrating of the output of the first channel. - View Dependent Claims (13)
-
-
14. A nuclear medicine imaging system comprising:
-
means for detecting a plurality of scintillation events including a first scintillation event and a second scintillation event, the second scintillation event overlapping the first scintillation event temporally and spatially, the means for detecting including a plurality of channels; means for integrating an output of each of the channels affected by the first scintillation event; means for stopping said integrating for each of the channels affected by both the first and second scintillation events; means for continuing said integrating for each of the channels affected by the first scintillation event but not the second scintillation event; means for receiving data representing integrated outputs of each of the channels; and means for generating images of an object based on the data. - View Dependent Claims (15, 16)
-
-
17. A gamma camera system comprising:
-
a gantry; a pair of gamma ray detectors movably supported by the gantry, each of the gamma ray detectors including; a scintillator; a plurality of light detectors optically coupled to the scintillator; timing circuitry configured to generate trigger signals in response to outputs of the light detectors; integration circuitry configured to integrate outputs of the light detectors in response to the trigger signals, the integration circuitry further configured to integrate the output of each of the light detectors affected by a first scintillation event and to integrate the output of each of the light detectors affected by a second scintillation event, the second scintillation event overlapping the first scintillation event temporally and spatially, the integration circuitry further configured to respond to the second scintillation event by stopping integration for each of the light detectors affected by both the first and second scintillation events and continuing integration for each of the light detectors affected by the first scintillation event but not the second scintillation event; positioning circuitry configured to generate position data based on integrated outputs of the light detectors; and a processing system coupled to each of the detectors and configured to generate images of an object based on the position data. - View Dependent Claims (18, 19)
-
Specification