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Robust extraction of baseline signal of atmospheric trace species using local regression

Atmospheric Measurement Techniques (2012) 5(11) 2613-2624
DOI: 10.5194/amt-5-2613-2012
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Abstract

The identification of atmospheric trace species measurements that are representative of well-mixed background air masses is required for monitoring atmospheric composition change at background sites. We present a statistical method based on robust local regression that is well suited for the selection of background measurements and the estimation of associated baseline curves. The bootstrap technique is applied to calculate the uncertainty in the resulting baseline curve. The non-parametric nature of the proposed approach makes it a very flexible data filtering method. Application to carbon monoxide (CO) measured from 1996 to 2009 at the high-alpine site Jungfraujoch (Switzerland, 3580 m a.s.l.), and to measurements of 1,1-difluoroethane (HFC-152a) from Jungfraujoch (2000 to 2009) and Mace Head (Ireland, 1995 to 2009) demonstrates the feasibility and usefulness of the proposed approach. The determined average annual change of CO at Jungfraujoch for the 1996 to 2009 period as estimated from filtered annual mean CO concentrations is-2.2 ± 1.1 ppb yr -1. For comparison, the linear trend of unfiltered CO measurements at Jungfraujoch for this time period is-2.9 ± 1.3 ppb yr-1. © 2012 Author(s).

Figures

  • Fig. 1. Histogram of the residuals derived from application of the REBS technique to hourly CO measurements at Jungfraujoch. The estimated scale parameter σ is 15.6 ppb. The thick vertical dashed line indicates the estimated mode of the residual distribution; the two thin vertical dashed lines denote the ±3σ range. The blue line is a Gaussian distribution fitted to the left side (residuals below the mode) of the residual distribution. The residual distribution can be used for judgement of the applicability of the REBS technique. The REBS should only be applied when the residuals below the mode follow approximately a Gaussian distribution (see Sect. 5).
  • Fig. 2. Measured CO during impact of regionally polluted air masses (black points) and background CO concentrations at Jungfraujoch for the 1996–2009 period as identified by the REBS technique and the smooth curve fit. The black crosses indicate the difference of annual background concentrations obtained by the two data filtering methods.
  • Fig. 3. Baseline curves for CO at Jungfraujoch (1996 to 2009) obtained with the REBS technique (including the bootstrapped 95 % confidence band) and the smooth curve fit. The average width of the confidence band (bootstrap uncertainty) is (−3.5 ppb, +3.8 ppb).
  • Table 1. Contingency table of the classification of the hourly CO values measured at Jungfraujoch from 1996 to 2009 (n= 111 656) derived from the REBS technique and the smooth curve fit.
  • Fig. 4. Measurements and baseline curves for HFC-152a at Jungfraujoch (2000 to 2009, top panel) and Mace Head (1995 to 2009, middle panel) estimated with the REBS technique and the smooth curve fit. The time series of monthly mean background concentration of HFC-152a calculated with the AGAGE method (see text) are also included. The lower panel gives the difference of monthly background concentrations at Jungfraujoch and Mace Head (in ppt) as determined with the REBS, the smooth curve fit, and the AGAGE method.
  • Table 3. Contingency table of the classification of HFC-152a measurements at Mace Head from 1995 to 2009 (n= 28 694) with the REBS technique, the smooth curve fit, and the AGAGE method (b = background; p = polluted).
  • Table 2. Contingency table of the classification of HFC-152a measurements at Jungfraujoch from 2000 to 2009 (n= 15 815) with the REBS technique, the smooth curve fit, and the AGAGE method (b = background; p = polluted).

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CITATION STYLE

APA

Ruckstuhl, A. F., Henne, S., Reimann, S., Steinbacher, M., Vollmer, M. K., O’Doherty, S., … Hueglin, C. (2012). Robust extraction of baseline signal of atmospheric trace species using local regression. Atmospheric Measurement Techniques, 5(11), 2613–2624. https://doi.org/10.5194/amt-5-2613-2012

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