Abstract
Abstract. The hydroclimatic process is changing non-monotonically and identifying its trends is a great challenge. Building on the discrete wavelet transform theory, we developed a discrete wavelet spectrum (DWS) approach for identifying non-monotonic trends in hydroclimate time series and evaluating their statistical significance. After validating the DWS approach using two typical synthetic time series, we examined annual temperature and potential evaporation over China from 1961–2013 and found that the DWS approach detected both the “warming” and the “warming hiatus” in temperature, and the reversed changes in potential evaporation. Further, the identified non-monotonic trends showed stable significance when the time series was longer than 30 years or so (i.e. the widely defined “climate” timescale). The significance of trends in potential evaporation measured at 150 stations in China, with an obvious non-monotonic trend, was underestimated and was not detected by the Mann–Kendall test. Comparatively, the DWS approach overcame the problem and detected those significant non-monotonic trends at 380 stations, which helped understand and interpret the spatiotemporal variability in the hydroclimatic process. Our results suggest that non-monotonic trends of hydroclimate time series and their significance should be carefully identified, and the DWS approach proposed has the potential for wide use in the hydrological and climate sciences.
Highlights
Climate and hydrological processes are exhibiting great variability (Allen and Ingram, 2002; Trenberth et al, 2014)
When using the discrete wavelet spectrum (DWS) approach (Fig. 1), we considered the timescale as data length, and used the Daubechies wavelet to decompose series S1 into seven (i.e. < log2200) sub-signals using Eqs. (2) and (3)
We developed the DWS approach for identifying the non-monotonic trend in hydroclimate time series, in which the discrete wavelet transform (DWT) is used first to separate the trend, and its statistical significance is evaluated by using the discrete wavelet spectrum (Fig. 1)
Summary
Climate and hydrological processes are exhibiting great variability (Allen and Ingram, 2002; Trenberth et al, 2014). A debate on the recent change in global air temperature has been receiving enormous public and scientific attention. This global air temperature increase during 1980– 1998, passing most statistical significance tests and has since stabilized until now, is widely called the “global warming hiatus” (Kosaka and Xie, 2013; Roberts et al, 2015; Medhaug et al, 2017). Identifying the non-monotonic trends hidden in those hydroclimate time series and assessing its statistical significance present a significant research task for understanding hydroclimatic variability and changes on long timescales
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