SiPM-based radiation detection systems and methods

What is claimed is: 1. A system comprising: one or more scintillators; at least one SiPM adapted to receive light from the one or more scintillators; and a logic device configured to communicate with the at least one SiPM, wherein the logic device is adapted to: receive detection signals from the at least one SiPM; process the detection signals according to an operational mode for the at least one SiPM; and determine detection events from the processed detection signals in accordance with the operational mode; wherein the operational mode comprises a directionality mode and the logic device is adapted to: partition the at least one SiPM into a plurality of logical detectors; process the detection signals according to coincidence criteria applied to adjacent logical detectors; determine the detection events by omitting substantially non-coincident and non-adjacent detection signals; and determine an angle of incidence for each pair of coincident detection events from energy and timing responses for each pair of coincident detection events. 2. The system of claim 1 , wherein: the at least one SiPM comprises two or more SIPMs. 3. The system of claim 1 , wherein the logical detectors are disposed in a three dimensional array, and wherein each angle of incidence is a three dimensional projection. 4. The system of claim 1 , further comprising an absolute orientation sensor and a display configured to communicate with the logic device, wherein the logic device is adapted to: receive an absolute orientation of the at least one SiPM and/or the one or more scintillators from the orientation sensor; derive an absolute direction from the angles of incidence using the absolute orientation; and provide the absolute direction to the display to indicate the absolute direction to a user. 5. A method of using the system of claim 1 , the method comprising: receiving the detection signals from the at least one SiPM; processing the detection signals according to the operational mode for the at least one SiPM; and determining the detection events from the processed detection signals in accordance with the operational mode. 6. The method of claim 5 , further comprising: partitioning the at least one SiPM into the plurality of logical detectors; processing the detection signals according to the coincidence criteria applied to adjacent logical detectors; determining the detection events by omitting the substantially non-coincident and non-adjacent detection signals; and determining the angle of incidence for each pair of coincident detection events from the energy and timing responses for each pair of coincident detection events. 7. The method of claim 6 , wherein the logical detectors are disposed in a three dimensional array, and wherein each angle of incidence is a three dimensional projection. 8. The method of claim 6 , further comprising: receiving an absolute orientation of the at least one SiPM and/or the one or more scintillators from an orientation sensor; deriving an absolute direction from the angles of incidence using the absolute orientation; and providing the absolute direction to a display to indicate the absolute direction to a user. 9. A system comprising: one or more scintillators; at least one SiPM adapted to receive light from the one or more scintillators; and a logic device configured to communicate with the at least one SiPM, wherein the logic device is adapted to: receive detection signals from the at least one SiPM; process the detection signals according to an operational mode for the at least one SiPM; and determine detection events from the processed detection signals in accordance with the operational mode; wherein the operational mode comprises a stabilization mode, the detection signals correspond to a known radiation source having a known peak position, and the logic device is adapted to: process the detection signals by determining a peak position associated with each detection signal and by determining signal characteristics of each detection signal; determine the detection events by accumulating processed detection signals into an identification spectrum; determine an accumulated peak position from the identification spectrum; apply an adjusted bias voltage and/or electronics gain to the at least one SiPM that substantially aligns the accumulated peak position to the known peak position; determine a temperature of the one or more scintillators from the signal characteristics; and modify the adjusted bias voltage, the adjusted electronics gain, and/or filter coefficients for the at least one SiPM according to the determined temperature to substantially align the accumulated peak position to the known peak position. 10. The system of claim 9 , further comprising a temperature sensor adapted to measure a SiPM temperature of the at least one SiPM, wherein the logic device is adapted to: receive the measured SiPM temperature of the at least one SiPM; and modify the adjusted bias voltage and/or electronics gain according to the measured SiPM temperature. 11. The system of claim 9 , wherein: the one or more scintillators comprise two or more scintillators. 12. A method of using the system of claim 9 , the method comprising: processing the detection signals by determining the peak position associated with each detection signal; determining the detection events by accumulating the processed detection signals into the identification spectrum; determining the accumulated peak position from the identification spectrum; and applying the adjusted bias voltage and/or electronics gain to the at least one SiPM that substantially aligns the accumulated peak position to the known peak position. 13. The method of claim 12 , further comprising: receiving the measured SiPM temperature from the temperature sensor; and modifying the adjusted bias voltage and/or electronics gain according to the measured SiPM temperature. 14. The method of claim 12 , further comprising: processing the detection signals by determining the signal characteristics of each detection signal; determining the temperature of the one or more scintillators from the signal characteristics; and modifying the adjusted bias voltage, the adjusted electronics gain, and/or filter coefficients for the at least one SiPM according to the determined temperature to substantially align the accumulated peak position to the known peak position. 15. A system comprising: one or more scintillators; at least one SiPM adapted to receive light from the one or more scintillators; and a logic device configured to communicate with the at least one SiPM, wherein the logic device is adapted to: receive detection signals from the at least one SiPM; process the detection signals according to an operational mode for the at least one SiPM; and determine detection events from the processed detection signals in accordance with the operational mode; wherein the operational mode comprises a Compton suppression mode and the logic device is adapted to: partition the at least one SiPM to form a primary logical detector and a secondary logical detector; process the detection signals according to coincidence criteria applied to the primary and secondary logical detectors; and determine the detection events by omitting substantially coincident detection signals and/or non-coincident detection signals received from the secondary logical detector. 16. A method of using the system of claim 15 , the method comprising: partitioning the at least one SiPM to form the primary log