Modelling calibration uncertainty in networks of environmental sensors

Michael Thomas Smith; Magnus Ross; Joel Ssematimba; Pablo A. Alvarado; Mauricio Alvarez; Engineer Bainomugisha; Richard Wilkinson

Modelling calibration uncertainty in networks of environmental sensors

Michael Thomas Smith, Magnus Ross, Joel Ssematimba, Pablo A. Alvarado, Mauricio Alvarez, Engineer Bainomugisha, Richard Wilkinson

Research output: Preprint/Working paper › Preprint

59 Downloads (Pure)

Abstract

Networks of low-cost sensors are becoming ubiquitous, but often suffer from poor accuracies and drift. Regular colocation with reference sensors allows recalibration but is complicated and expensive. Alternatively the calibration can be transferred using low-cost, mobile sensors. However inferring the calibration (with uncertainty) becomes difficult. We propose a variational approach to model the calibration across the network. We demonstrate the approach on synthetic and real air pollution data, and find it can perform better than the state of the art (multi-hop calibration). We extend it to categorical data produced by citizen-scientist labelling. In Summary: The method achieves uncertainty-quantified calibration, which has been one of the barriers to low-cost sensor deployment and citizen-science research.

Original language	English
Publication status	Published - 4 May 2022

Keywords

cs.LG
60G15

Access to Document

2205.01988v2

Cite this

@techreport{4bbd64bab87e4896bdeb2eb88092b824,

title = "Modelling calibration uncertainty in networks of environmental sensors",

abstract = " Networks of low-cost sensors are becoming ubiquitous, but often suffer from poor accuracies and drift. Regular colocation with reference sensors allows recalibration but is complicated and expensive. Alternatively the calibration can be transferred using low-cost, mobile sensors. However inferring the calibration (with uncertainty) becomes difficult. We propose a variational approach to model the calibration across the network. We demonstrate the approach on synthetic and real air pollution data, and find it can perform better than the state of the art (multi-hop calibration). We extend it to categorical data produced by citizen-scientist labelling. In Summary: The method achieves uncertainty-quantified calibration, which has been one of the barriers to low-cost sensor deployment and citizen-science research. ",

keywords = "cs.LG, 60G15",

author = "Smith, {Michael Thomas} and Magnus Ross and Joel Ssematimba and Alvarado, {Pablo A.} and Mauricio Alvarez and Engineer Bainomugisha and Richard Wilkinson",

note = "31 pages (23 pages of content, 4 pages of references, 4 supplementary). 11 figures. 4 tables. Submitted to Journal of the Royal Statistical Society. Series C",

year = "2022",

month = may,

day = "4",

language = "English",

type = "WorkingPaper",

}

TY - UNPB

T1 - Modelling calibration uncertainty in networks of environmental sensors

AU - Smith, Michael Thomas

AU - Ross, Magnus

AU - Ssematimba, Joel

AU - Alvarado, Pablo A.

AU - Alvarez, Mauricio

AU - Bainomugisha, Engineer

AU - Wilkinson, Richard

N1 - 31 pages (23 pages of content, 4 pages of references, 4 supplementary). 11 figures. 4 tables. Submitted to Journal of the Royal Statistical Society. Series C

PY - 2022/5/4

Y1 - 2022/5/4

N2 - Networks of low-cost sensors are becoming ubiquitous, but often suffer from poor accuracies and drift. Regular colocation with reference sensors allows recalibration but is complicated and expensive. Alternatively the calibration can be transferred using low-cost, mobile sensors. However inferring the calibration (with uncertainty) becomes difficult. We propose a variational approach to model the calibration across the network. We demonstrate the approach on synthetic and real air pollution data, and find it can perform better than the state of the art (multi-hop calibration). We extend it to categorical data produced by citizen-scientist labelling. In Summary: The method achieves uncertainty-quantified calibration, which has been one of the barriers to low-cost sensor deployment and citizen-science research.

AB - Networks of low-cost sensors are becoming ubiquitous, but often suffer from poor accuracies and drift. Regular colocation with reference sensors allows recalibration but is complicated and expensive. Alternatively the calibration can be transferred using low-cost, mobile sensors. However inferring the calibration (with uncertainty) becomes difficult. We propose a variational approach to model the calibration across the network. We demonstrate the approach on synthetic and real air pollution data, and find it can perform better than the state of the art (multi-hop calibration). We extend it to categorical data produced by citizen-scientist labelling. In Summary: The method achieves uncertainty-quantified calibration, which has been one of the barriers to low-cost sensor deployment and citizen-science research.

KW - cs.LG

KW - 60G15

M3 - Preprint

BT - Modelling calibration uncertainty in networks of environmental sensors

ER -

Modelling calibration uncertainty in networks of environmental sensors

Abstract

Keywords

Access to Document

Fingerprint

Cite this