Development, Characterization, and Testing of a Bias Supply for SiPMs in the CMVD Experiment

TL;DR

This paper presents the design and testing of a specialized bias power supply for silicon photomultipliers used in a cosmic muon veto detector, emphasizing stability, modularity, and compatibility with detector electronics.

Contribution

A novel bias power supply for SiPMs with precise voltage control, stability, and features like temperature compensation, tailored for use in the CMVD experiment.

Findings

The power supply provides 50-58 V in 50 mV steps with stable operation.

It supports multiple SiPMs with close to breakdown voltages in parallel.

The system is compatible with external controllers and includes temperature compensation capabilities.

Abstract

To assess the viability of a shallow-depth neutrino detector, a Cosmic Muon Veto Detector (CMVD) is being constructed on top of the stack of Resistive Plate Chamber (RPC) detectors at TIFR, Mumbai. The CMVD employs extruded plastic scintillators for muon detection, with wavelength-shifting fibers coupled to silicon photomultipliers (SiPMs) for signal readout. A highly stable, low-noise power source is essential for biasing the SiPMs, as the precision, accuracy, and stability of the supply directly impact the consistency of their gain. To address this, we designed a biasing power supply capable of delivering 50-58 V in 50 mV steps, with a maximum short-circuit current output of 1 mA. The system incorporates digital voltage control, stabilization, and current monitoring, making it compatible with external controllers (such as microcontrollers). This added flexibility and modularity allow for additional functionalities, including temperature compensation. Designed to supply multiple SiPMs with close to breakdown voltages in parallel, the circuit seamlessly integrates with the front-end electronics of the detector system.