Pixel identification for small pitch scintillation crystal arrays

The invention claimed is: 1. A method of diagnostic imaging using a gamma ray detector including a scintillator array for emitting scintillation photons at photo conversion positions in response to incident gamma rays and a photodetector array coupled thereto in light-sharing mode for determining a spatial intensity distribution of scintillation photons, said method comprising: in a memory, recording spatial intensity distributions of scintillation photons emitted by the scintillator array in response to multiple incident gamma rays; with a computer, determining sets of coincidently emitted scintillation photons from the recorded spatial intensity distributions; with the computer, determining for the sets of coincidently emitted scintillation photons center-of-gravity positions and cumulative energies; with the computer, performing a clustering analysis based on the determined center-of-gravity positions and cumulative energies to obtain clusters of gamma ray events attributed to a scintillator array element; with the computer, cumulating for a cluster the spatial intensity distributions to determine a cumulative spatial intensity distribution of scintillation photons emitted in response to incident gamma rays in the scintillator array element; with the computer, determining a light matrix including expected spatial intensity distributions of scintillation photons for different scintillator array elements based on the cumulative spatial intensity distributions; generating spatial intensity distributions from gamma rays received from an imaged subject with the gamma ray detector; operating on the spatial intensity distributions using the light matrix to generate corrected spatial intensity distributions; and reconstructing the corrected spatial intensity distributions in a diagnostic image of the imaged subject. 2. The method according to claim 1 , wherein performing the clustering analysis includes using a standard clustering algorithm based on hierarchical clustering, centroid based clustering, distribution based clustering, density based clustering or Maximum Likelihood Expectation Maximization Clustering. 3. The method according to claim 1 , further including: with the computer, determining the expected spatial intensity distributions based on normalizing the determined cumulative spatial intensity distributions. 4. The method according to claim 1 , further including: with the computer, dividing the determined sets of coincidently emitted scintillation photons into groups including all sets of coincidently emitted scintillation photons with their centers-of-gravity over the same photodetector array element; and with the computer, performing a separate clustering analysis for each group. 5. The method according to claim 1 , wherein the incident gamma rays are emitted by a point source. 6. The method according to claim 1 , wherein the computer is controlled by a computer program stored on a non-transitory computer readable medium. 7. A calibration module for a gamma ray detector including a scintillator array for emitting scintillation photons at photo conversion positions in response to incident gamma rays and a photodetector array coupled thereto in light-sharing mode for determining a spatial intensity distribution of scintillation photons, said module comprising: a recorder for recording spatial intensity distributions of scintillation photons emitted by the scintillator array in response to multiple incident gamma rays; a computer configured to: determine sets of coincidently emitted scintillation photons from the recorded spatial intensity distributions, determine for the sets of coincidently emitted scintillation photons center-of-gravity positions and cumulative energies, perform a clustering analysis based on the determined center-of-gravity positions and cumulative energies to obtain clusters of gamma ray events attributed to a scintillator array element, cumulate for a cluster the spatial intensity distributions to determine a cumulative spatial intensity distribution of scintillation photons emitted in response to incident gamma rays in the scintillator array element, and determine a light matrix including expected spatial intensity distributions of scintillation photons for different scintillator array elements based on the cumulative spatial intensity distributions. 8. A gamma ray detector comprising a scintillator array for emitting scintillation photons at photo conversion positions in response to incident gamma rays; a photodetector array coupled to the scintillator array in light-sharing mode for determining a spatial intensity distribution of scintillation photons; and a calibration module according to claim 7 . 9. The gamma ray detector according to claim 8 , further comprising a lightguide interposed between the scintillator array and the photodetector array for guiding the emitted scintillation photons from the scintillator array to the photodetector array. 10. The gamma ray detector according to claim 9 , wherein the lightguide comprises a high refractive index material with a refractive index higher than the refractive index of the photodetector array's entrance window. 11. The gamma ray detector according to claim 10 , wherein the high refractive material includes sapphire Glass. 12. The gamma ray detector according to claim 8 , wherein the computer is further configured to determine a gamma ray intensity image from a Maximum Likelihood Estimation of the photo conversion positions of incident gamma rays based on the light matrix. 13. A medical imaging device comprising: a gamma ray detector according to claim 8 , wherein the gamma ray detector is disposed to receive gamma rays from a subject and generate signals indicative thereof and operate on the signals with the generated light matrix. 14. The calibration module according to claim 7 , wherein the computer is further configured to divide the sets of concurrently emitted scintillation photons into groups including all sets of coincidently emitted scintillation photons with their centers-of-gravity over the same photodetector array element and perform a separate clustering analysis for each group. 15. A gamma ray imaging device comprising: a gamma ray detector including a scintillator array configure to emit scintillation photons at photo conversion positions in response to incident gamma rays and a photodetector array coupled thereto in light-sharing mode and configured to determine a spatial intensity distribution of scintillation photons; the calibration module according to claim 7 configured to generate the light matrix in a calibration mode from gamma rays received from a calibration gamma ray source; and wherein in an imaging mode, the gamma imaging device is configured to operate on the spatial intensity distributions generated by gamma rays from an imaged subject to generate light matrix corrected spatial intensity distributions and to reconstruct the matrix corrected spatial intensity distribution into a diagnostic image. 16. A non-transitory computer-readable medium carrying program code configured to control a computer to: record spatial intensity distributions of scintillation photons from a gamma ray detector including a scintillator array which emits scintillation photons at photo conversion positions in response to incident gamma rays and a photodetector array coupled thereto in light-sharing mode which determines the spatial intensity distribution of scintillation photons, determine sets of coincidently emitted scintillation photons from the recorded spatial intensity distribu