Abstract
The global low-carbon transition is driving the use of renewable energy for ecological monitoring. Traditional power supply for forest monitoring sensor equipment is constrained by high wired costs, frequent battery replacement, and the limitations of low light levels and special spectra under forest canopies on photovoltaic (PV) compatibility. Existing research lacks exploration of the correlation between under-forest spectra and PV performance. This study measured the summer understory light spectra of five tree species in Beijing, evaluated the performance of three types of PV cells-monocrystalline silicon, polycrystalline silicon, and amorphous silicon-and designed a low-light energy harvesting circuit. Results indicate that spectral differences under tree canopies are concentrated from 380-680 nm, exhibiting a distinctive forest-specific spectral feature of "high-band enrichment" above 680 nm. Under low-light conditions, polycrystalline silicon photovoltaics demonstrates optimal performance when adapted to this high-band spectrum. The designed circuit can activate at 5 W/m(2) irradiance and stably output 4.16 V voltage. This study fills a spectral gap in northern summer tree canopies, providing a comprehensive solution of "material adaptation + circuit customization" for the practical deployment of shaded forest PV systems.