| Title |
Automatic pollen recognition with the rapid-E particle counter: the first-level procedure, experience and next steps / |
| Authors |
Šaulienė, Ingrida ; Šukienė, Laura ; Daunys, Gintautas ; Valiulis, Gediminas ; Vaitkevičius, Lukas ; Matavulj, Predrag ; Brdar, Sanja ; Panic, Marko ; Sikoparija, Branko ; Clot, Bernard ; Crouzy, Benoît ; Sofiev, Mikhail |
| DOI |
10.5194/amt-12-3435-2019 |
| Full Text |
|
| Is Part of |
Atmospheric measurement techniques.. Gottingen : Copernicus. 2019, vol. 12, iss. 6, p. 3435-3452.. ISSN 1867-1381. eISSN 1867-8548 |
| Keywords [eng] |
multimodel ensemble simulations ; allergic rhinitis ; birch pollen ; dispersion ; scattering ; asthma ; grains |
| Abstract [eng] |
Pollen-induced allergies are among the most prevalent non-contagious diseases, with about a quarter of the European population being sensitive to various atmospheric bioaerosols. In most European countries, pollen information is based on a weekly-cycle Hirst-type pollen trap method. This method is labour-intensive and requires narrow specialized abilities and substantial time, so that the pollen data are always delayed and subject to sampling- and counting-related uncertainties. Emerging new approaches to automatic pollen monitoring can, in principle, allow for real-time availability of the data with no human involvement. The goal of the current paper is to evaluate the capabilities of the new Plair Rapid-E pollen monitor and to construct a first-level pollen recognition algorithm. The evaluation was performed for three devices located in Lithuania, Serbia and Switzerland, with independent calibration data and classification algorithms. The Rapid-E output data include multi-angle scattering images and the fluorescence spectra recorded at several times for each particle reaching the device. Both modalities of the Rapid-E output were treated with artificial neural networks (ANNs) and the results were combined to obtain the pollen type. For the first classification experiment, the monitor was challenged with a large variety of pollen types and the quality of many-to-many classification was evaluated. It was shown that in this case, both scattering- and fluorescence-based recognition algorithms fall short of acceptable quality. The combinations of these algorithms performed better, exceeding 80 % accuracy for 5 out of 11 species. Fluorescence spectra showed similarities among different species, ending up with three well-resolved groups: (Alnus, Corylus, Betula and Quercus), (Salix and Populus) and (Festuca, Artemisia and Juniperus). Within these groups, pollen is practically indistinguishable for the first-level recognition procedure. Construction of multistep algorithms with sequential discrimination of pollen inside each group seems to be one of the possible ways forward. In order to connect the classification experiment to existing technology, a short comparison with the Hirst measurements is presented and the issue of false positive pollen detections by Rapid-E is discussed. |
| Published |
Gottingen : Copernicus |
| Type |
Journal article |
| Language |
English |
| Publication date |
2019 |
| CC license |
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