Analyzing the impact of automatization using parallel daily mean temperature series including breakpoint detection and homogenization

Hannak, Lisa; Friedrich, Karsten; Imbery, Florian; Kaspar, Frank

doi:10.1002/joc.6597

Cited by 3 publications

(7 citation statements)

References 25 publications

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“…As described in Hannak et al (2020), the correction factor is the difference of the mean deviation between the time series under study and the reference series of the training period (recent segment) and the break segment. The correction factor is determined individually for each month of the year.…”

Section: Step 3: Homogenizationmentioning

confidence: 99%

“…If ‘uniseg’ is not able to detect a break in this time range using daily data, the break date of using monthly data is used for further steps. An example is illustrated in Figure 3 (see Hannak et al, 2020).…”

Section: Procedures Of Breakpoint Detection and Homogenization Of Dai...mentioning

confidence: 99%

“…Changes in the geographical position of the station (station relocation), measurement environment (e.g., growing trees), measurement practice (e.g., observation times), measurement systems (e.g., automatization) and used formulas and time ranges (e.g., to calculate daily mean or daily extreme values) can potentially result in breakpoints in long time series (WMO-No.1245, 2020. One example of an inhomogeneous temperature time series is Hohenpeißenberg, analysed and homogenized in the study of Winkler (2009).…”

Section: Introductionmentioning

confidence: 99%

“…These investigations conclude that in Germany, there is no risk of inhomogeneities in long time series of daily mean temperature caused by the automatization. To study the effect of breakpoints and homogenization during the time period of parallel measurements, Hannak et al (2020) homogenized the parallel temperature measurements and compared the results to the study of Kaspar et al (2016). The results are comparable, the breaks during the parallel measurement period (about 10 years of data) compensate each other and the mean differences between automatic and manual measurements are close to zero.…”

Section: Introductionmentioning

confidence: 99%

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Homogenization of German daily and monthly mean temperature time series

Kunert,

Friedrich,

Imbery

et al. 2024

Intl Journal of Climatology

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Long time series can be potentially influenced by breakpoints. This study presents an automatic procedure to detect and homogenize breakpoints in German daily and monthly mean temperature time series. To verify breakpoints metadata information is used. The homogenization tool is evaluated with a synthetic data set with the result of smaller mean bias and RMSE than the unhomogenized data. For homogenized German temperature data in most cases, smaller and less breakpoints are detected compared to the raw data. The mean differences of trends before and after homogenization is small (0.05 K/length of each time series). The result of the homogenization is presented in three case studies. After homogenization, the trend in these cases is closer to the calculated trend for Germany calculated using a gridded data set.

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Section: Step 3: Homogenizationmentioning

confidence: 99%

Section: Procedures Of Breakpoint Detection and Homogenization Of Dai...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Homogenization of German daily and monthly mean temperature time series

Kunert,

Friedrich,

Imbery

et al. 2024

Intl Journal of Climatology

Self Cite

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“…In Europe, Hannak et al . (2020) examined the variable impact of site automation using parallel daily mean temperature series. In addition, the bringing together of meteorology and metrology groups within Europe to work on areas of common importance within recent years has, and continues to bring, both clarity and benefits to meteorological metrology (Merlone et al ., 2015) and a forensic examination of environmental extremes (Merlone et al ., 2019).…”

Section: Background and Motivationmentioning

confidence: 99%

Response times of meteorological air temperature sensors

Burt

Podesta

2020

Quart J Royal Meteoro Soc

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Guidelines in the Guide to Meteorological Instruments and Methods of Observation (the CIMO guide) of the World Meteorological Organization (WMO, published 2014, updated 2017, section 2.1.3.3, Response times of thermometers) recommend that the 63% response time τ for an air temperature sensor be 20 s, although – as airflow speed influences response time – the minimum airflow speed at which this applies should also be specified in the document. A 63% response time τ63 = 20 s implies that 95% of a step change be registered within 3τ63 or 60 s, the WMO recommended averaging interval for air temperature: rapid air temperature changes on this time‐scale are not uncommon, often associated with convective squalls, frontal systems or sea breeze circulations. An alternative way of expressing the effect of the time constant is that in air whose temperature is changing at 0.1 K·min−1 the thermometer would lag by approximately 0.03 K. To assess whether this response time specification was realistic, we have undertaken an experimental and theoretical study of the time constants of meteorological thermometers. Laboratory wind tunnel tests were undertaken to quantify 63% and 95% response times of 25 commercial 100 Ω platinum resistance thermometers (PRTs) of various sizes (length and sheath diameter) from five manufacturers. The test results revealed a fourfold difference in response times between different sensors: none of the PRTs tested met the CIMO response time guideline at a ventilation speed of 1 m·s−1 assumed typical of passively ventilated thermometer shields such as Stevenson‐type thermometer screens. A theoretical model of the sensors was devised which matched the experimental behaviour with regard to the most important contributing factors, namely ventilation rate and sensor diameter. Finally, suggestions and recommendations for operational air temperature sensor adoption and future sensor development are included.

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Relative Homogenization of Climatic Time Series

Domonkos

2024

Atmosphere

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Homogenization of the time series of observed climatic data aims to remove non-climatic biases caused by technical changes during the history of the climate observations. The spatial redundancy of climate information helps to recognize station-specific inhomogeneities with statistical methods, but the correct detection and removal of inhomogeneity biases is generally not easy for the combined effects of individual inhomogeneities. In a homogenization procedure, several time series of a given climatic variable observed in one climatic region are usually homogenized together via a large number of spatial comparisons between them. Such procedures are called relative homogenization. A relative homogenization procedure may include one or more homogenization cycles where a cycle includes the steps of time series comparison, inhomogeneity detection and corrections for inhomogeneities, and they may include other steps like the filtering of outlier values or spatial interpolations for infilling data gaps. Relative homogenization methods differ according to the number and content of the individual homogenization cycles, the procedure for the time series comparisons, the statistical inhomogeneity detection method, the way of the inhomogeneity bias removal, among other specifics. Efficient homogenization needs the use of tested statistical methods to be included in partly or fully automated homogenization procedures. Due to the large number and high variety of homogenization experiments fulfilled in the Spanish MULTITEST project (2015–2017), its method comparison test results are still the most informative about the efficiencies of homogenization methods in use. This study presents a brief review of the advances in relative homogenization, recalls some key results of the MULTITEST project, and analyzes some theoretical aspects of successful homogenization.

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Analyzing the impact of automatization using parallel daily mean temperature series including breakpoint detection and homogenization

Cited by 3 publications

References 25 publications

Homogenization of German daily and monthly mean temperature time series

Homogenization of German daily and monthly mean temperature time series

Response times of meteorological air temperature sensors

Relative Homogenization of Climatic Time Series

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