# Reliable data from low cost ozone sensors in a hierarchical network

**Authors:** Georgia Miskell, Kyle Alberti, Brandon Feenstra, Geoff S Henshaw,, Vasileios Papapostolou, Hamesh Patel, Andrea Polidori, Jennifer A Salmond,, Lena Weissert, David E Williams

arXiv: 1906.08421 · 2019-08-30

## TL;DR

This paper presents a hierarchical network of low-cost ozone sensors calibrated with regulatory data, enabling reliable high-resolution ozone monitoring at neighborhood scales, capturing spatial and temporal variations missed by sparse regulatory stations.

## Contribution

It introduces a calibration algorithm for low-cost sensors using regulatory data and demonstrates its effectiveness in a large urban network for high-resolution ozone monitoring.

## Key findings

- Calibration algorithms successfully corrected sensor drift.
- Dense networks reveal large ozone variations missed by sparse stations.
- Proximity to regulatory stations improves calibration accuracy.

## Abstract

We demonstrate how a hierarchical network comprising a number of compliant reference stations and a much larger number of low-cost sensors can deliver reliable high temporal-resolution ozone data at neighbourhood scales. The framework, demonstrated originally for a smaller scale regional network deployed in the Lower Fraser Valley, BC was tested and refined using two much more extensive networks of gas-sensitive semiconductor-based (GSS) sensors deployed at neighbourhood scales in Los Angeles: one of ~20 and one of ~45 GSS ozone sensors. Of these, ten sensors were co-located with different regulatory measurement stations, allowing a rigorous test of the accuracy of the algorithms used for off-site calibration and adjustment of low cost sensors. The method is based on adjusting the gain and offset of the low-cost sensor to match the first two moments of the probability distribution of the sensor result to that of a proxy: a calibrated independent measurement (usually derived from regulatory monitors) whose probability distribution evaluated over a time that emphasizes diurnal variations is similar to that at the test location. The regulatory measurement station physically closest to the low-cost sensor was a good proxy for most sites. The algorithms developed were successful in detecting and correcting sensor drift, and in identifying locations where geographical features resulted in significantly different patterns of ozone variation due to the relative dominance of different dispersion, emission and chemical processes. The entire network results show very large variations in ozone concentration that take place on short time- and distance scales across the Los-Angeles region. Such patterns were not captured by the more sparsely distributed stations of the existing regulatory network and demonstrate the need for reliable data from dense networks of monitors.

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Source: https://tomesphere.com/paper/1906.08421