System, method, and detector module for pet imaging

What is claimed is: 1. A PET system, comprising: a detector module configured to receive radiation rays and generate a plurality of light signals in response to the received radiation rays, the detector module comprising: a scintillator array having N rows of scintillators and M columns of scintillators, each row of scintillators being arranged in a first direction, each column of scintillators being arranged in a second direction; a first set of photosensors optically coupled to a first surface of the scintillator array, at least one photosensor of the first set of photosensors extending longitudinally in the second direction so as to be optically coupled to two or more scintillators in the second direction and being optically coupled to two or more columns of scintillators, wherein each scintillator in the scintillator array is optically coupled to only one photosensor of the first set of photosensors; and a second set of photosensors optically coupled to a second surface of the scintillator array, at least one photosensor of the second set of photosensors extending longitudinally in the first direction; and an electronics module coupled to the detector module and being configured to identify a scintillator within the scintillator array that has interacted with an impinging radiation ray. 2. The PET system of claim 1 , wherein the first set of photosensors or the second set of photosensors include at least one silicon photomultiplier (SiPM). 3. The PET system of claim 1 , further comprising a gantry with a detection region for receiving a subject to be scanned, wherein the first surface or the second surface of the scintillator array faces the detection region. 4. The PET system of claim 1 , wherein the first direction is approximately perpendicular to the second direction. 5. The PET system of claim 1 , wherein N equals M, or N is different from M. 6. The PET system of claim 1 , wherein the electronics module is coupled to the first set of photosensors and the second set of photosensors, and the electronics module is further configured to: detect a first set of electrical signals generated by the first set of photosensors and a second set of electrical signals generated by the second set of photosensors, wherein the impinging radiation ray is relating to an electrical signal of the first set of electrical signals or the second set of electrical signals. 7. The PET system of claim 6 , wherein the electronics module comprises: a plurality of analog-to-digital converters (ADC) configured to digitize the first set of electrical signals and the second set of electrical signals; and a processor configured to identify, based on the digitized first set of electrical signals and the digitized second set of electrical signals, the scintillator within the scintillator array that has interacted with the impinging radiation ray. 8. The PET system of claim 7 , wherein the processor is further configured to determine a depth of interaction of the impinging radiation ray. 9. The PET system of claim 8 , wherein the electronics module further comprises: a lower limit detection (LLD) circuit, or a constant fraction discriminator (CFD) circuit; and a time-to-digital converter (TDC) configured to determine an interaction time when the impinging radiation ray interacts with the identified scintillator. 10. The PET system of claim 9 , wherein the processor is further configured to correct the interaction time based on the depth of interaction of the impinging radiation ray. 11. The PET system of claim 1 , further comprising: a processing module configured to reconstruct an image based on the first set of electrical signals generated by the first set of photosensors and the second set of electrical signals generated by the second set of photosensors. 12. A method for PET imaging, comprising: detecting, using a scintillator array, a plurality of radiation rays, wherein the scintillator array includes N rows of scintillators and M columns of scintillators, each row of scintillators being arranged in a first direction, each column of scintillators being arranged in a second direction; generating, using a first set of photosensors, a first set of electrical signals based on the plurality of radiation rays, wherein the first set of photosensors are optically coupled to a first surface of the scintillator array, at least one photosensor of the first set of photosensors extending longitudinally in the second direction so as to be optically coupled to two or more scintillators in the second direction and being optically coupled to two or more columns of scintillators, wherein each scintillator in the scintillator array is optically coupled to only one photosensor of the first set of photosensors; generating, using a second set of photosensors, a second set of electrical signals based on the plurality of radiation rays, wherein the second set of photosensors are optically coupled to a second surface of the scintillator array, at least one photosensor of the second set of photosensors extending longitudinally in the first direction; and identifying, using an electronics module, a scintillator within the scintillator array that has interacted with an impinging radiation ray relating to an electrical signal of the first set of electrical signals or the second set of electrical signals. 13. The method of claim 12 , further comprising: identifying a depth of interaction of the impinging radiation ray in the identified scintillator, based on the first set of electrical signals and the second set of electrical signals. 14. The method of claim 13 , further comprising: determining, using a time-to-digital converter (TDC), an interaction time when the impinging radiation ray interacts with the identified scintillator. 15. The method of claim 14 , further comprising: correcting the interaction time based on the depth of interaction of the impinging radiation ray in the identified scintillator. 16. The method of claim 13 , wherein the depth of interaction of the impinging radiation ray in the identified scintillator corresponds to a position in a Z axis direction that is perpendicular to the first direction and the second direction, and wherein the identifying the depth of interaction of the impinging radiation ray in the identified scintillator comprises: determining, based on a ratio of first energy relating to the first set of electrical signals to second energy relating to the first set of electrical signals and the second set of electrical signals, a proportional distribution coefficient; and determining, based on the proportional distribution coefficient, the depth of interaction of the impinging radiation ray. 17. The method of claim 16 , wherein the first energy relates to a first sum of the first set of electrical signals, and the second energy relates to a second sum of the first set of electrical signals and the second set of electrical signals, and wherein the first set of electrical signals and the second set of electrical signals are converted by at least one analog-to-digital converter and processed by a processor. 18. The method of claim 14 , wherein the impinging radiation ray interacts with the scintillator array from the second surface of the scintillator array, and wherein the determining an interaction time comprises: determining a sum of the second set of electrical signals; and determining, using a lower limit detection (LLD) circuit, or a constant fraction discriminator (CFD) circuit, and a time-to-digital converter (TDC), the interaction time based