Metrology for sensor networks: metrological traceability and measurement uncertainties for air quality monitoring

S. Eichstädt, Olav Werhahn
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Abstract

In situ calibration of sensors delivering SI traceable measurement results still provides an open question to the design and operation of sensor networks. Particularly when addressing low-cost sensors, currently, the use of sensor networks for air quality monitoring is limited by the low or unknown accuracy of measurements that they can achieve, while the data quality of individual sensor networks is mainly derived by algorithms. Standardization bodies like DIN and CEN therefore announced the need for investigations of validation methods on gas phase species and particulate matter on the one hand side, and for the development of fully digitized quality assurance/quality control and calibration techniques for sensor networks on the other (CEN/CENELEC, Opportunity for Standardisation to Contribute to the European Partnership on Metrology EPM under Horizon Europe). This contribution concentrates on the metrological traceability of sensor networks for air quality monitoring to the international system of units (SI) based on FAIRified intra-network communications (M. Wilkinson, et al., “The FAIR guiding principles for scientific data management and stewardship,” Sci. Data, vol. 3, 2016, Art. no. 160018) and including delocalized Optical Gas Standards operated according to the digital TILSAM method (O. Werhahn, et al., The TILSAM Method Adapted into Optical Gas Standards – Complementing Gaseous Reference Materials, PTB Open Access Repository, 2021). Informed by related activities in EURAMET (Partnership project FunSNM, EMNs COO & POLMO, TC-IM 1551) (European Metrology Network Climate and Ocean Observation (COO), European Metrology Network Pollution Monitoring (POLMO), EURAMET Project TC-IM 1551, Project Database) this contribution discusses the importance of measurement uncertainties in the context of sensor networks, comprising different sensor principles and promoting an efficient uptake of state-of-the-art methods. We discuss how the sensor network case can be addressed with sensors individually using the GUM principles (Joint Committee for Guides in Metrology, Guide to the Expression of Uncertainty in Measurement (GUM), JCGM 100: 2008 (E)). For sensor network measurements becoming metrologically traceable to the SI, documented and unbroken chains of calibrations need to be implemented each contributing to the measurement uncertainty. This applies to each individual sensor of the network including the potential gold standard among them, but also to the network’s output viewed as a single entity. The contribution provides first approaches to be tested and validated that are underpinned by fundamental design strategies for sensor networks. It follows on practical applications in real world scenarios aside from model uncertainties discussed in artificial intelligence prospects.
传感器网络计量:空气质量监测的计量溯源和测量不确定性
传感器的现场校准可提供 SI 可追溯测量结果,这仍然是传感器网络设计和运行的一个未决问题。特别是在使用低成本传感器时,目前传感器网络在空气质量监测方面的应用受到了限制,因为它们所能达到的测量精度较低或未知,而单个传感器网络的数据质量主要是通过算法得出的。因此,DIN 和 CEN 等标准化机构宣布,一方面需要对气相物种和颗粒物质的验证方法进行研究,另一方面需要为传感器网络开发完全数字化的质量保证/质量控制和校准技术(CEN/CENELEC,"标准化为欧洲地平线下的欧洲计量伙伴关系 EPM 做出贡献的机会")。这篇论文集中讨论了空气质量监测传感器网络与国际单位制(SI)之间的计量可追溯性,其基础是 FAIRified 的网络内部通信(M. Wilkinson 等人,"FAIR 科学研究指导原则")、"数据》,第 3 卷,2016 年,艺术编号 160018),并包括根据数字 TILSAM 方法运行的局部光学气体标准(O. Werhahn 等人,《改编为光学气体标准的 TILSAM 方法--补充气态参考材料》,PTB 开放存取资料库,2021 年)。受 EURAMET(合作伙伴项目 FunSNM、EMNs COO & POLMO、TC-IM 1551)(欧洲计量网络气候与海洋观测(COO)、欧洲计量网络污染监测(POLMO)、EURAMET 项目 TC-IM 1551、项目数据库)相关活动的启发,本文讨论了传感器网络背景下测量不确定性的重要性,包括不同的传感器原理和促进对最先进方法的有效吸收。我们讨论了如何利用 GUM 原则(计量学指南联合委员会,《测量不确定度表达指南》(GUM),JCGM 100: 2008 (E))对传感器网络进行单独处理。为使传感器网络测量在计量上可溯源至国际单位制,需要执行记录在案且不间断的校准链,每个校准链都会对测量不确定度产生影响。这不仅适用于网络中的每个传感器,包括其中潜在的黄金标准,而且也适用于作为单一实体的网络输出。该论文提供了第一种有待测试和验证的方法,这些方法以传感器网络的基本设计策略为基础。除了人工智能前景中讨论的模型不确定性之外,它还涉及现实世界场景中的实际应用。
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