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Machine Learning for Light Sensor Calibration.

Yichao Zhang1, Lakitha O H Wijeratne1, Shawhin Talebi1

  • 1Hanson Center for Space Sciences, University of Texas at Dallas, Richardson, TX 75080, USA.

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Summary
This summary is machine-generated.

We developed a low-cost sensor system (<$20) that accurately measures sunlight spectra (360-780 nm) using machine learning calibration. This enables widespread deployment for detailed environmental monitoring.

Keywords:
light sensormachine learningneural networksspectrophotometer

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Area of Science:

  • Atmospheric science
  • Environmental monitoring
  • Sensor technology

Background:

  • Sunlight drives crucial photochemical and environmental processes, including atmospheric radiative heating.
  • Accurate measurement of wavelength-resolved solar irradiance is vital for understanding these processes.
  • Existing reference instruments are costly, limiting widespread deployment.

Purpose of the Study:

  • To develop and validate a low-cost sensor ensemble for measuring wavelength-resolved solar irradiance spectra.
  • To achieve high accuracy comparable to expensive reference instruments.
  • To enable dense, neighborhood-scale sensor networks for micro-scale environmental variability studies.

Main Methods:

  • Utilized an ensemble of very low-cost sensors (total cost <$20).
  • Employed machine learning algorithms for sensor calibration against a reference instrument (NIST-calibrated Konica Minolta CL-500A).
  • Achieved 1 nm spectral resolution between 360-780 nm.

Main Results:

  • The calibrated low-cost sensor ensemble accurately reproduced reference instrument measurements with a correlation coefficient R² > 0.99.
  • Demonstrated the feasibility of using machine learning to calibrate inexpensive sensors.
  • Made sensor circuits and calibration code publicly available.

Conclusions:

  • Low-cost sensor ensembles, when calibrated with machine learning, can provide high-fidelity solar irradiance spectra.
  • This methodology allows for unprecedented spatial and temporal insights into irradiance micro-variability.
  • Applications include air quality, environmental science, and agronomy.