As silicon photomultiplier (SiPM) technology develops, its possible applications are being growingly expanded. However, the current technical obstacle is the signal readout from large-scale, multi-pixel SiPMs, especially in a large nuclear imaging device. Although the application-specific integrated circuits (ASICs) provide ways to reach that goal, it needs a long period with iterative electronic process and a very high cost. We developed a high-integrated positron emission tomography (PET) electronics system with field programmable gate array based charge-to-digital converter (FPGA-QDC) technology instead of the ASICs. Unlike traditional FPGA-based charge readout method in which low-voltage differential signaling (LVDS) receivers serve as analog voltage comparators, in the proposed electronics system voltage-referenced receivers work as analog comparators.Theoretically, nearly all of input/output (I/O) ports in the FPGA can achieve the function of analog comparators using voltage-referenced I/O standard. The electronics system is constructed using off-the-shelf low-cost commercial components. Therefore, it is feasible to fast build a distributed readout system with multiple such electronics system. The flexibility and reconfigurability of the FPGA provide multi-channel grouping and diverse triggering for different kinds of detector configurations, such as row/column summation and resistor-based readout. These features are greatly sought after in readout electronics for the SiPM-based radiation detectors. Experimental results show that the proposed highly-integrated electronics system overcomes the bottleneck that has limited the development of advanced PET detectors and scanners.
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