Solar regulators for polar instrumentation: why night consumption matters

Prior-Jones, Michael R. ORCID: https://orcid.org/0000-0002-0980-4027, Craw, Lisa, Hawkins, Jonathan D., Bagshaw, Elizabeth A., Carpenter, Paul, Nylen, Thomas H. and Pettit, Joe 2025. Solar regulators for polar instrumentation: why night consumption matters. Geoscientific Instrumentation, Methods and Data Systems Item availability restricted.

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Abstract

Autonomous instruments, powered using solar panels and batteries, are a vital tool for long-term scientific observation of the polar regions. However, winter conditions, with low temperatures and prolonged lack of sunlight, make power system design for these regions challenging. Minimising winter power consumption is vital to successful operation, but power consumption data supplied by equipment manufacturers can be confusing or misleading. We measured the night consumption (power consumption in the absence of sunlight) of 16 commercially available solar regulators and compared the 15 results to the manufacturers' reported values. We developed a simple model to predict the maximum depth of discharge of a battery bank, for given values of regulator and instrument power consumption, solar panel size, location, and battery capacity. We use this model to suggest the minimum battery capacity required to continuously power a typical scientific installation in a polar environment, consisting of a single data logger (12mW power consumption) powered by a 12V battery bank and 20W solar panel, for eight different types of solar regulator. Most of the tested solar regulators consumed power at or below the 20 manufacturer's reported values, although two significantly exceeded them. For our modelled scenario, our results suggest that current consumption may be reduced by two orders of magnitude (from 23mA to 0.1mA) through careful choice of solar regulator, and the mass of the battery required for year-round operation may thus be reduced from 45kg to 1.5kg, a factor of 26x. These results demonstrate that choice of solar regulator can significantly increase the chances of successful year-round data collection from a polar environment, eases deployment and reduces costs.

Item Type:	Article
Status:	In Press
Schools:	Schools > Earth and Environmental Sciences
Date of First Compliant Deposit:	2 December 2025
Date of Acceptance:	7 November 2025
Last Modified:	03 Dec 2025 12:45
URI:	https://orca.cardiff.ac.uk/id/eprint/182840

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