Timestamping detected radiation quanta

The invention claimed is: 1. A radiation detection device comprising: an optical detector pixel array having one or more pixel cells which can be triggered by optical photons; a timestamp trigger unit in operative communication with at least one timing unit; wherein the timestamp trigger unit is configured to receive signals from the optical detector pixel array and is further configured to determine at least a first pixel cell triggering rate for the one or more pixel cells within the optical detector pixel array; wherein the at least a first pixel cell triggering rate is determined by computing the number of triggered pixel cells within the optical detector pixel array within a predetermined delay period; wherein the timestamp trigger unit is configured to cause the at least one timing unit to generate a first timestamp indicative of the end of the predetermined delay period based on the at least a first pixel cell triggering rate for the one or more pixel cells within the optical detector pixel array and based further on a second pixel cell triggering rate for the one or more pixel cells within the optical detector pixel array and wherein the second pixel cell triggering rate is determined at a later point in time to the first pixel cell triggering rate. 2. The radiation detection device according to claim 1 wherein the timestamp trigger unit is configured to cause the at least one timing unit to generate the first timestamp if the at least a first pixel cell triggering rate for the one or more pixel cells within the optical detector pixel array exceeds a threshold rate value. 3. The radiation detection device according to claim 1 wherein the first timestamp is generated based further upon a triggered pixel cell count for the one or more pixel cells within the optical detector pixel array; wherein the first timestamp is generated if the triggered pixel cell count meets a predetermined triggered pixel cell count condition prior to the at least a first pixel cell triggering rate meeting a predetermined pixel cell triggering rate condition. 4. The radiation detection device according to claim 3 wherein the predetermined triggered pixel cell count condition is that the triggered pixel cell count exceeds a threshold count value; and wherein the predetermined pixel cell triggering rate condition is that the at least a first pixel cell triggering rate exceeds a threshold rate value; and wherein the predetermined delay period begins when the triggered pixel cell count exceeds the threshold count value; such that the at least one timing unit is caused to generate the first timestamp if the triggered pixel cell count exceeds the threshold count value and then subsequently exceeds a higher count value before the end of the predetermined delay period such that the threshold rate value is exceeded. 5. The radiation detection device according to claim 3 further comprising a timestamp adjustment unit configured to receive the first timestamp from the at least one timing unit; wherein the timestamp adjustment unit is configured to generate an adjusted first timestamp indicative of the time at which the predetermined triggered pixel cell count condition was met by subtracting the predetermined delay period from the time of the first timestamp. 6. The radiation detection device according to claim 1 wherein the timestamp trigger unit is configured to cause the at least one timing unit to generate the first timestamp if the first pixel cell triggering rate for the one or more pixel cells within the optical detector pixel array exceeds a first threshold rate and the second pixel cell triggering rate for the one or more pixel cells within the optical detector pixel array exceeds a second threshold rate. 7. The radiation detection device according to claim 1 further comprising at least a second timing unit; wherein the at least a second timing unit is in communication with the timestamp trigger unit; wherein the timestamp trigger unit is further configured to cause the at least a second timing unit to generate a photon count timestamp indicative of the time of detection of one or more optical photons by pixel cells within the optical detector pixel array. 8. A PET imaging system comprising a plurality of radiation detection devices according to claim 7 ; wherein each radiation detection device further comprises a scintillator element in optical communication with the optical detector pixel array; the PET imaging system further comprising: a depth-of-interaction calculation unit; wherein the depth-of-interaction calculation unit is configured to compute a depth of interaction of a radiation quant in the scintillator element based on either i) the time difference between the first timestamp and the photon count timestamp or ii) the time difference between the first timestamp and the triggering rate timestamp. 9. A PET imaging system comprising a plurality of radiation detection devices according to claim 7 ; wherein each radiation detection device further comprises a scintillator element in optical communication with the optical detector pixel array; the PET imaging system further comprising a timestamp correction unit configured to generate a corrected timestamp based on a weighted average of the first timestamp and the second timestamp. 10. The radiation detection device according to claim 1 further comprising at least a second timing unit; wherein the at least a second timing unit is in communication with the timestamp trigger unit; wherein the timestamp trigger unit is further configured to cause the at least a second timing unit to generate a triggering rate timestamp indicative of the time at which the pixel cell triggering rate for the one or more pixel cells within the optical detector pixel array meets a second triggering rate condition. 11. A PET imaging system comprising a plurality of radiation detection devices according to claim 1 ; wherein each radiation detection device further comprises a scintillator element in optical communication with the optical detector pixel array. 12. A timing method for use in PET imaging or Cherenkov imaging, the timing method comprising the steps of: receiving signals from an optical detector pixel array indicative of the triggering of one or more pixel cells within the optical detector pixel array; determining at least a first pixel cell triggering rate for the one or more pixel cells within the optical detector pixel array by computing the number of triggered pixel cells within the optical detector pixel array within a predetermined delay period; generating a first timestamp that is indicative of the end of the predetermined delay period and is also indicative of the detection of a radiation quanta based on the at least a first pixel cell triggering rate for the one or more pixel cells within the optical detector pixel array and based further on a second pixel cell triggering rate for the one or more pixel cells within the optical detector pixel array and wherein the second pixel cell triggering rate is determined at a later point in time to the first pixel cell triggering rate. 13. A non-transitory computer-readable medium carrying executable instructions which control one or more processors to perform the method steps of: receiving signals from an optical detector pixel array indicative of the triggering of one or more pixel cells within the optical detector pixel array; determining at least a first pixel cell triggering rate for the one or more pixel cells within the optical detector pixel array by computing the number of triggered pixel cells within the optical detector pixel array within a pre