Spatial patterns and sensitivity of intermittent stream drying to climate variability

Floods and droughts are driven, in part, by spatial patterns of extreme rainfall. Heat waves are driven by spatial patterns of extreme temperature. It is therefore of interest to design statistical methodologies that allow the identification of likely patterns of extreme rain or temperature from observed historical data. The standard work-horse for identifying patterns of climate variability in historical data is Principal Component Analysis (PCA) and its variants. But PCA optimizes for variance not spatial extremes, and so there is no particular reason why the first PCA spatial pattern should identify, or even approximate, the types of patterns that may drive these phenomena, even if the linear assumptions underlying PCA are correct. We present an alternative pattern identification algorithm that makes the same linear assumptions as PCA, but which can be used to explicitly optimize for spatial extremes. We call the method Directional Component Analysis (DCA), since it involves introducing a preferred direction, or metric, such as `sum of all points in the spatial field'. We compare the first PCA and DCA spatial patterns for US rainfall anomalies on a 6 month timescale, using the sum metric for the definition of DCA in order to focus on total rainfall anomaly over the domain, and find that they are somewhat different. The definitions of PCA and DCA result in the first PCA spatial pattern having the larger explained variance of the two patterns, while the first DCA spatial pattern, when scaled appropriately, has a higher likelihood and greater total rainfall anomaly, and indeed is the pattern with the highest total rainfall anomaly for any given likelihood. In combination these two patterns yield more insight into rainfall variability and extremes than either pattern on its own.

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Spatial patterns of meadow sensitivities to interannual climate variability in the Sierra Nevada

Ecohydrology ◽

10.1002/eco.2128 ◽

2019 ◽

Vol 12 (7) ◽

Cited By ~ 3

Author(s):

Christine M. Albano ◽

Meredith L. McClure ◽

Shana E. Gross ◽

Wesley Kitlasten ◽

Christopher E. Soulard ◽

...

Keyword(s):

Climate Variability ◽

Sierra Nevada ◽

Spatial Patterns ◽

Interannual Climate Variability

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Spatial Patterns of Climate Variability in Upper-Tropospheric Water Vapor Radiances from Satellite Data and Climate Model Simulations

Journal of Climate ◽

10.1175/1520-0442(1999)012<1940:spocvi>2.0.co;2 ◽

1999 ◽

Vol 12 (7) ◽

pp. 1940-1955 ◽

Cited By ~ 10

Author(s):

A. J. Geer ◽

J. E. Harries ◽

H. E. Brindley

Keyword(s):

Water Vapor ◽

Climate Variability ◽

Spatial Patterns ◽

Satellite Data ◽

Climate Model ◽

Model Simulations ◽

Climate Model Simulations

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Spatial Patterns of Glaciers in Response to Spatial Patterns in Regional Climate

Journal of Climate ◽

10.1175/2009jcli2857.1 ◽

2009 ◽

Vol 22 (17) ◽

pp. 4606-4620 ◽

Cited By ~ 19

Author(s):

Kathleen Huybers ◽

Gerard H. Roe

Keyword(s):

Climate Change ◽

Climate Variability ◽

Spatial Patterns ◽

Regional Climate ◽

Regional Scale ◽

Small Scale ◽

Relative Importance ◽

Spatial Correlations ◽

Climate History ◽

Glacier Length

Abstract Glaciers are direct recorders of climate history and have come to be regarded as emblematic of climate change. They respond to variations in both accumulation and ablation, which can have separate atmospheric controls, leading to some ambiguity in interpreting the causes of glacier changes. Both climate change and climate variability have characteristic spatial patterns and time scales. The focus of this study is the regional-scale response of glaciers to natural patterns of climate variability. Using the Pacific Northwest of North America as the setting, the authors employ a simple linear glacier model to study how the combination of patterns of melt-season temperature and patterns of annual accumulation produce patterns of glacier length variations. Regional-scale spatial correlations in glacier length variations reflect three factors: the spatial correlations in precipitation and melt-season temperature, the geometry of a glacier and how it determines the relative importance of temperature and precipitation, and the climatic setting of the glaciers (i.e., maritime or continental). With the self-consistent framework developed here, the authors are able to evaluate the relative importance of these three factors. The results also highlight that, in order to understand the natural variability of glaciers, it is critically important to know the small-scale patterns of climate in mountainous terrain. The method can be applied to any area containing mountain glaciers and provides a baseline expectation for natural glacier variation against which the effects of climate changes can be evaluated.

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An Alternative to PCA for Estimating Dominant Patterns of Climate Variability and Extremes, with Application to U.S. and China Seasonal Rainfall

Atmosphere ◽

10.3390/atmos11040354 ◽

2020 ◽

Vol 11 (4) ◽

pp. 354

Author(s):

Stephen Jewson

Keyword(s):

Climate Variability ◽

Spatial Pattern ◽

Spatial Patterns ◽

Historical Data ◽

Component Analysis ◽

Rainfall Anomaly ◽

Rapid Identification ◽

Total Rainfall ◽

Spatial Extremes ◽

Rainfall Anomalies

Floods and droughts are driven, in part, by spatial patterns of extreme rainfall. Heat waves are driven by spatial patterns of extreme temperature. It is therefore of interest to design statistical methodologies that allow the rapid identification of likely patterns of extreme rain or temperature from observed historical data. The standard work-horse for the rapid identification of patterns of climate variability in historical data is Principal Component Analysis (PCA) and its variants. But PCA optimizes for variance not spatial extremes, and so there is no particular reason why the first PCA spatial pattern should identify, or even approximate, the types of patterns that may drive floods, droughts or heatwaves, even if the linear assumptions underlying PCA are correct. We present an alternative pattern identification algorithm that makes the same linear assumptions as PCA, but which can be used to explicitly optimize for spatial extremes. We call the method Directional Component Analysis (DCA), since it involves introducing a preferred direction, or metric, such as “sum of all points in the spatial field”. We compare the first PCA and DCA spatial patterns for U.S. and China winter and summer rainfall anomalies, using the sum metric for the definition of DCA in order to focus on total rainfall anomaly over the domain. In three out of four of the examples the first DCA spatial pattern is more uniform over a wide area than the first PCA spatial pattern and as a result is more obviously relevant to large-scale flooding or drought. Also, in all cases the definitions of PCA and DCA result in the first PCA spatial pattern having the larger explained variance of the two patterns, while the first DCA spatial pattern, when scaled appropriately, has a higher likelihood and greater total rainfall anomaly, and indeed is the pattern with the highest total rainfall anomaly for a given likelihood. The first DCA spatial pattern is arguably the best answer to the question: what single spatial pattern is most likely to drive large total rainfall anomalies in the future? It is also simpler to calculate than PCA. In combination PCA and DCA patterns yield more insight into rainfall variability and extremes than either pattern on its own.

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Spatial patterns and sensitivity of intermittent stream drying to climate variability