Current mode design for multiplexing positioning data of detector blocks

What is claimed is: 1. A method of radiation detection, comprising: receiving radiation at least a second sensor of a detector having a first sensor and the second sensor; generating a signal in response to the received radiation at the second sensor; and using a circuit associated with the first sensor to: calculate, at the first sensor, a representation of the signal generated at the second sensor, wherein a position coordinate of the signal generated at the second sensor is translated into a coordinate system of the first sensor using a ratio of total energy recorded at the second sensor to a sum of total energies recorded at the first and second sensors, and perform a calculation on the representation of the signal to determine a parameter of the radiation. 2. The method of claim 1 , wherein the parameter includes at least one of: (i) an energy of the radiation; and (ii) a location at which the radiation is received. 3. The method of claim 1 , wherein the first sensor includes a first array of photodetectors and the second sensor includes a second array of photodetectors. 4. The method of claim 3 , wherein a first mini-block circuit generates the signal for the first array of photodetectors and a second mini-block circuit generates the signal for the second array of photodetectors, the method further comprising calculating position coordinates of the radiation using the energies at the first mini-block and the second mini-block. 5. An apparatus for measuring radiation, comprising: a detector for receiving the radiation, the detector including a first photodetector array and a second photodetector array; a first chip associated with the first photodetector array including a first mini-block circuit for generating a first signal in response to the radiation at the first photodetector array, and a first summation circuit; and a second chip associated with the second photodetector array including a second mini-block circuit for generating a second signal in response to the radiation at the second photodetector array; wherein the first signal and second signal are processed at the first summation circuit to determine a parameter of the radiation, wherein a position of radiation at the second photodetector array is represented at the first summation circuit by translating a position coordinate of the second mini-block into a coordinate system of the first mini-block using a ratio of total energy recorded at the second mini-block to a sum of total energies recorded at the first and second mini-blocks. 6. The apparatus of claim 5 , wherein the second chip includes a second summation circuit and the second summation circuit is turned off while the first summation circuit determines the parameter of the radiation. 7. The apparatus of claim 5 , wherein each mini-block circuit includes a plurality of anode buffers, each anode connected to a photodetector of the photodetector array. 8. The apparatus of claim 7 , wherein the first summation circuit determines the coordinate of the radiation of the electronic signals by weighting the signal energy at the photodetector with a position coordinate associated with the photodetector. 9. The apparatus of claim 8 , wherein the ratio of energies is a ratio of the energy at the second detector to a sum of the energy at the first detector and second detector. 10. An apparatus for detecting radiation, comprising: a detector comprising a plurality of sensors, each sensor having a photodiode array and a mini-block for calculating energy and position coordinates of a radiation signal received at the sensor; a summation circuit associated with a first of the plurality of sensors configured to: receive the calculated energy and position coordinates from the other of the plurality of sensors, calculating a representation of the received energies and position coordinates in the with respect to the first of the plurality of sensors, wherein a position of radiation at a mini-block of another of the plurality of sensors is represented at the summation circuit by translating a position coordinate of the mini-block of the other of the plurality of sensors into a coordinate system of a mini-block of the first of the plurality of sensors using a ratio of total energy recorded at the other mini-block to a sum of total energies recorded at the other mini-block and the mini-block of the first of the plurality of sensors, and performing calculations on the representation of the received energies and position coordinates to detect the radiation. 11. The apparatus of claim 10 , wherein calculating the representation of the received energies and position coordinates further comprises defining a coordinate system centered on the first sensor and defining the energies and position coordinates of the other sensors using the coordinate system centered on the first sensor. 12. The apparatus of claim 10 , wherein the detector block is included in a positron emission tomography device. 13. The apparatus of claim 10 , wherein the plurality of sensors of the detector block form at least one of: (i) a one-dimensional array of sensors; (ii) a two-dimension array of sensors; (iii) a ring of sensors; and (iv) an arc of sensors along a ring. 14. The apparatus of claim 10 , wherein a capacitive node of the output of the first summation circuit is less than a capacitive node of the input of the first summation circuit.