Abstract
In this review we examine the past 5 years of landscape ecology research examining the effects of both spatial and thematic resolution on ecological analysis. While spatial resolution has been a topic of research for many decades, scale effects from thematic resolution have only recently been studied. Recent multi-scale analyses have demonstrated that the effects of thematic resolution on ecological analysis are comparable to spatial resolution and both spatial and thematic resolution interact. Additionally, spatial and thematic resolution can impact on multi-scale methods that are commonly used to identify the intrinsic scale—the scale at which ecological phenomena interact with the environment. A key aim of multi-scale analysis in landscape ecology is to characterise the scale-dependency of ecological processes, however, the interdisciplinary nature of landscape ecology means that research on scale has incorporated methods from a range of disciplines. These methods and concepts include: 1) multi-scale methods which characterise the sensitivity of an analysis to the modifiable areal unit problem, 2) spatial statistics for characterising the scale dependency of landscape patterns and identifying the optimal scale and 3) ecological theory describing intrinsic scales/domains of scales. We conclude by drawing on the existing literature to describe potential future areas of research to address the impacts of spatial and thematic resolution. We suggest further research on the effects of thematic resolution and conceptualising the scale continuum as multi-dimensional. We also identify mechanistic models and spatial statistics as a promising direction for future research.
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Introduction
Determining scale-dependencies of ecological responses to landscape patterns—in particular spatial scale—is a central question in landscape ecology and has been the focus of research for many decades [1–4]. Ecological processes are multi-scaled in nature and analysing them at inappropriate scales can result in the phenomenon remaining undetected due to a mismatch between the scale of the analysis and the scale of the ecological processes of interest [3, 5, 6]. This can potentially result in the derivation of spurious relationships and/or erroneous results [7, 8]. Despite the recognition of the importance of scale, its impacts are not commonly addressed, partly due to the difficulties of conducting multi-scale analysis [9].
There are numerous facets to scale in landscape ecology that affect the measurement of ecological responses and responses to management for conservation, two of which are the focus of this paper—spatial and thematic resolution. The first, spatial resolution, is probably one of the most studied aspect of scale research undertaken in the field of landscape ecology [3, 4, 7], and related disciplines such as conservation biology [10, 11], spatial sciences [12, 13] and statistics [14]. While, the second aspect of scale, thematic resolution (also known as attribute precision [15] or categorical resolution [16]) which refers to the level of classification detail of the sampling units, is a relative newcomer to research in landscape ecology. Its effects on spatial analysis in landscape ecology have only recently been described in the ecological literature, with the earliest papers published in 2004 and 2007 [17–19].
In this review we look back on the past 5 years of landscape ecology research on the role of spatial and thematic resolution and evaluate the latest findings in light of the many decades of existing research. We first define spatial and thematic resolution in the context of an existing paradigm describing the domains of scale (observation, analysis and intrinsic scale). Next we summarise the effects of spatial and thematic resolution on ecological analysis and multi-scale analysis methods. We then focus on studies from the past 5 years, identifying examples of research that have made progress in characterising and addressing the effects of spatial and thematic resolution on ecological analysis. In particular we focus on studies which examined the effects of both spatial and thematic resolution. Drawing on these latest finding and more broadly from research in landscape ecology we conclude by suggesting future research directions for addressing spatial and thematic resolution.
Definition and Effects of Spatial and Thematic Resolution, and Multi-Scale Methods
Dimensions of Scale and Definition of Spatial and Thematic Resolution
Spatial resolution, often referred to as the grain size, is a product of several factors associated with the acquisition and processing of spatial data from the field or remote sensing [20–22]. In remote sensing, spatial resolution is primarily a product of the pixel size of the sensor or the object-scale for data produced through geographic object-based image analysis [22–26]. Pre- and post-processing of spatial data, commonly used for improving classification and geometric accuracy, also affects spatial resolution through: removing features below a minimum area (minimum mappable unit) [27, 28], the application of smoothing filters [29] and the characteristics of the remote sensing device [30].
Thematic resolution is a property of the ruleset used to describe a hierarchy of land cover classes, the criteria used to distinguish them, and the relationship between the classes. The Anderson classification scheme is a classic example of a land use/land cover classification hierarchy that has a hierarchy of different thematic resolutions [31]. The Anderson classification scheme contains four resolutions with each finer resolution class nested within a coarser resolution level class. For example, residential and industrial are nested within urban. Within the vegetation sciences thematic resolution can be considered as the hierarchical relationships between vegetation classification units where natural taxonomic units can be grouped, and/or regrouped from individual species, communities, to biogeographic regions [32]. In continuous data (i.e. temperature, rainfall) thematic resolution refers to how accurately environmental variability is measured [33] (e.g. what is the precision of the units measuring thematic differences).
Spatial and thematic resolution represent aspects of the three dimensions of scale [34] or three kinds of scale [2]. The first dimension, the observation/measurement scale, describes the size, shape, extent and distance between observational units used to sample a phenomenon. The second dimension, the analysis/modelling scale refers to the units used to analyse data and is an aggregate of the spatial units at the observation scale. When using remote sensing data, the observation scale is often the pixel size and the units of the analysis scale are patches in the landscape (or sometimes circular buffers around point locations), where each patch is composed of multiple pixels whose values are aggregated (e.g. percent vegetation cover for each patch).
The final dimension, the intrinsic scale, is the scale at which ecological phenomena interact with the environment and is an emergent property of an organism’s response to its environment, which is measured indirectly at the observation scale(s) and/or analysis scale(s) [2, 29, 35]. In this paper we focus primarily on observation scale effects from changing spatial and thematic resolution in the context of GIS analysis using data derived from remote sensing. The combination of GIS analysis with remote sensing data represents one of the most common ways for representing and analysing data in landscape ecology [25, 36, 37].
Effects on Ecological Analysis
Multi-scale analyses are often used to test the sensitivity of a statistical analysis to variations in the spatial units [38, 39] such as in the case of the assessment of the modifiable areal unit problem (MAUP) [8] and the related change of support problem (COSP) [14]. The MAUP view of scale suggests that statistical relationships derived from areal units with different boundaries and levels of aggregation can confound the results of spatial statistical analyses [7, 40]. While the COSP is broader than the MAUP and refers to the effects of the types, size and shape of the spatial units used in spatial analysis, e.g. point, lines, areas and pixels [14, 34].
Changing spatial and thematic resolution have been shown to affect both the characterisation of landscapes and ecological analysis such as measuring land cover proportions [41–43], landscape metrics [19, 44, 45], graph-based connectivity metrics [46, 47], change detection [48] and statistical relationships between the landscape context and species distributions [49, 50]. Spatial resolution has been demonstrated to affect statistical analysis such as inference about population mean, variation and statistical significance [43, 51–54].
Along with the effects of spatial and thematic resolution on analyses of ecological phenomenon that are considered purely from a statistical point of view or to test the sensitivity of an analysis to scale, multi-scale analysis with ecological data (i.e. species abundance, occurrence) are commonly used to identify intrinsic-scales associated with pattern-process relationships. The relationship of scale with ecological processes is described by related theories such as scale discontinuities [55, 56], domains of scale [3, 57] and hierarchy theory [20] (see Nash et al. [56] for a summary).
Multi-Scale Analysis Methods
A common experimental design for assessing scale effects in landscape ecology is to aggregate pixels or alter the thematic resolution of one or more land cover maps and quantify changes to response variables, such as landscape metric values [6, 58–60]. Another common multi-scale analysis method used frequently in landscape ecology characterises multi-scale species-environment relationships by altering the size of circular buffers/kernel around point locations at which ecological data is sampled [61–63], while leaving the spatial or thematic resolution constant. However, this type of multi-scale analysis is not an explicit focus of this paper as it does not involve altering the spatial and/or thematic resolution to identify scale effects (see [63, 64] for a comprehensive review).
In parallel to the ecological literature focusing on ecological pattern-process scale effects, the spatial sciences and, in particular the geostatistics/spatial statistics literature, have also addressed scale issues, but more from the perspective of quantifying the scale dependence of observed landscape patterns and finding the optimal spatial scale for mapping [35, 65–67]. These methods address the relationship between the sampling unit (observation scale) and the feature being measured (i.e. the relationship between a tree and a 30 × 30 m pixel used to sample tree density) by factoring-in the spatial structure of the landscape such as clustering and directionality [67]. In ecology these methods have also been used to measure the statistical property of the spatial pattern of the landscape for assessing the relationship between spatial patterns and processes [67–69]. These techniques are also commonly used to address the COSP associated with mapping continuous spatial data (i.e. temperature, soil PH) with point data. Spectral decomposition techniques including wavelet analysis [70] and eigenvector approaches [71] represent another suite of statistical techniques that has been applied to ecological analysis to determine the key spatial scales at which underlying ecological processes act on species.
Recent Progress (Post-2010) in Research on the Effects of Spatial and Thematic Resolution on Ecological Analysis
Our review found that in the past 5 years (2010–2015) there has continued to be more research on spatial resolution than thematic resolution, with the number of publications on spatial resolution rising, while the number of publications on thematic resolution having stayed constant with an average of 6.8 publications per year, compared to 113.2 for spatial resolution (identified with a Scopus keyword search on 16/12/2015 (thematic or spatial resolution and (“scaling” OR “multi-scale”))). A recent study that reviewed all the studies published in landscape ecology using remote sensing data in 2007 found only 6 % of articles addressed the impact of thematic resolution [25]. A keyword search examining studies that had assessed both aspects of resolution (“spatial resolution AND thematic resolution”) identified a total of only 15 publications in the past 5 years (some of which were not ecological studies), indicating very little focus on dealing with both aspects of scale simultaneously.
In the past 5 years there have been a number of publications further developing the ‘theory of scale’ in the context of ecological analysis [56, 57, 72] that are relevant to understanding and interpreting the effects of spatial and thematic resolution on ecological analyses. They build on existing theories that consider ecological phenomena to interact with or perceive the environment at relatively isolated, distinct scales or intrinsic scales defined by specific pattern-process relationships. For example, influences on foraging movement operate at fine-scales and movement for dispersal operates at coarser scales [73]. These theories suggest that along the scale continuum there are segments/domains which are invariant to scale and then transition zones or discontinuities at scales where it is not sensible to measure patterns [56, 57]. It is within the context of these broader ecological concepts that the effects of spatial and thematic resolution are often addressed with multi-scale analysis in landscape ecology.
While it has been recognised for some time that spatial and thematic resolution impact on the measurement of ecological responses [17–19, 53, 54, 74], only recently have studies looked at both of these factors together. Several studies have compared the effects of using explanatory variables with a range of thematic and spatial resolutions in species distribution modelling and showed that they have a large effect on predictive accuracy [75, 76]. In particular Liang et al. [77] modelled three thematic and six spatial resolutions and assessed individual effects and interactions. They showed that both thematic and spatial resolutions affected model-based predictions of tree species distribution.
For multi-scale analysis of landscape metrics, previous studies, before 2010, have tested multiple scale-dependent factors such as extent and spatial resolution [6, 58, 78], but only recently have studies explicitly tested interactions and effect sizes statistically [77, 79]. Studies examining the effects of scale on the calculation of landscape metrics using analysis of variance have shown statistically that factors interact [79, 80]. This means that not only do spatial and thematic resolution have main effects, but that the level of one will affect the level of another. Thus, studies that consider a single factor in isolation (e.g. pixel size) may produce different results when other factors are fixed at different levels.
In addition to the recognition that thematic and spatial resolution interact, affecting predictive modelling and the derivation of landscape metrics, they also affect other forms of multi-scale analysis. Ecological studies characterising an intrinsic scale infer that differences in correlation coefficients are related to the response of an ecological phenomenon to particular scales, and scales where there are high correlation coefficient values represents intrinsic scales [62, 81]. In most cases these forms of multi-scale analysis involve assessing the effects of analysis scale by changing the size of circular buffers around point locations at which ecological data are sampled for testing multi-scale species-environment relationships [64, 82, 83]. However, a recent study by Kendall et al. [50] using this multi-scale buffer analysis method showed that patterns of r2 values for a range of buffer sizes changed with thematic resolution and spatial resolution (defined by the minimum mappable unit). Additionally, Lechner et al. [29] using synthetic analysis showed that the highest r2 values may incorrectly identify intrinsic scales identified with multi-scale buffer analyses as a result of changes in pixel size and applying a smoothing filter (which also reduces spatial resolution).
The recent studies described above have utilised relatively simple multi-scale analyses methods (often equivalent to a sensitivity analysis) for examining the effects of spatial and thematic resolution. While using spatial statistics for examining spatial resolution are very common in ecology [84–86], we only know of one example where these methods have been used to address the effects of thematic resolution [87]. Vicente et al. [87] provides an example of the use of spatial autocorrelation analysis (using Moran’s I and Geary’s C) and statistical clustering to identify scales of spatial patterning of environmental factors for a range of thematic and spatial resolutions.
The differences between the types of multi-scale analyses that have been used in landscape ecology are nuanced and include a range of sometimes contradictory aims. The interdisciplinary nature of landscape ecology means that research on scale has incorporated methods from remote sensing, spatial statistics and ecological theory, with the objective of characterising the sensitivity of an analysis to scale (MAUP), address scale effects by identifying scale-dependence and optimal scales, and explaining scale effects in terms of ecological processes by their intrinsic scales/domains of scale (Fig. 1).
One of the key aims in the discipline of landscape ecology, which unites much of the research, is to characterise the scale-dependency of ecological processes. Figure 2a, b, c and d describe a classic conceptual diagram of the scale continuum [e.g. 9] which underpin scale theory in ecology. Although commonly the scale continuum is conceptualised for a single scale, it is in fact multi-dimensional and needs to be re-conceptualised as multi-dimensional, as studies identified in this review have shown, both thematic and spatial resolution interact and cannot be considered in isolation (Fig. 2e). Furthermore, each environmental variable used in an ecological analysis may be represented by multiple spatial datasets with a range of observation scales [64, 72], which each could be represented by multiple scale dimensions.
Thus, there is a need for a better understanding of the link between ecological scale theories, such as conceptualised in Fig. 2e, with multi-scale spatial analysis methods. Currently, there is no substantive difference in type of analysis conducted for studies testing for the presence of the MAUP (which indicate an analysis is not robust and perhaps spurious), to studies characterising the intrinsic scale. Crucial to deepening the understanding of the multiple dimensions of scale, is more research on the effects of thematic resolution and the combined effects of thematic and spatial resolution. Many studies comparing the influence of thematic resolution versus spatial resolution show that thematic resolution has as a great, or greater influence on the results of ecological analyses than spatial resolution. For example, a recent study by Cushman and Landguth [33] assessing the impact of thematic resolution, pixel size and focal window size on landscape genetic analysis found that thematic resolution had the largest effect. Additionally, the relationship between studies assessing intrinsic scale and spatial statistics (i.e. geostatistical) methods are unclear, especially for thematic resolution which has received little attention in the ecological literature.
Future Research Directions
Common approaches to multi-scale analyses of spatial and thematic resolution that simply aggregate spatial data to identify relationships between ecological metrics and scale can be a blunt instrument for understanding scale-dependent ecological responses. One aspect that limits understanding of spatial and thematic resolution is a lack of integration of ecological processes into scale-dependent models. Scale-dependent relationships emerge from a myriad of ecological process operating at different scales [56, 64, 67] and generalisations about scale should consider these processes more explicitly. While, spatial statistics can be used to measure the statistical property of spatial patterns for multiple spatial predictors at multiple scales in order to identify the appropriate predictor to model the relationship between species’ distributions and environmental variables [67]. Consequently, we suggest two ways forward for future research in this area: 1) utilising mechanistic models for capturing ecological processes [72, 88] and 2) integrating ecological theory/models with spatial statistics [87].
Using mechanistic models multi-scale processes can be captured explicitly by representing how organisms interact with landscape features at different scales. For example, species’ foraging movements operate at finer spatial scales to dispersal and migratory movements and respond to different habitat components at each scales [89]. These phenomena can be accounted for by simultaneously modelling movement for foraging and dispersal processes that are explicitly represented by movement interactions with fine and coarse levels of spatial and thematic data aggregation respectively [73, 90]. The key advantage of using a more mechanistic approach is being explicit about the multi-scaled ecological processes that drive emergent scale-dependent ecological patterns and thereby allow for a more generalisable understanding of scale.
Recent advances in mechanistic and hierarchical statistical approaches will help to parameterise and develop these models from data [91]. However, approaches such as this will also require more explicit multi-scale characterisation of landscape features, which in part can be provided by multi-scale object-based image analysis methods with fine-scale spatial data to minimize the artificial boundaries associated with the pixels at multiple spatial resolutions [92].
While some ecological processes can be explicitly characterised with mechanistic models, an alternative approach or an approach to be used in parallel, is to characterise ecological patterns by their spatial structure using spatial statistics. Rather than explicitly representing landscape features and ecological processes using mechanistic methods as described above, spatial statistics can be used to summarise complex multi-scale relationships. These methods need to be developed to test multiple aspects of scale in a single analysis and aspects of scale that have received little attention such as thematic resolution. Vicente et al. [87] provides a promising example, how spatial autocorrelation analyses characterising multiple environmental factors—at a range of spatial and thematic resolutions—can be used to build predictors for ecological models (see [87, 93]). Such frameworks can potentially also incorporate data from mechanistic models as inputs into their analysis.
Conclusions
In the past 5 years there has been progress in addressing spatial and thematic resolution in landscape ecology, however, research on thematic resolution has lagged, even though its impacts are comparable to spatial resolution. Furthermore, research on the interactions between thematic and spatial resolution demonstrates that scale is even more complex than previously acknowledged and multi-dimensional. There are numerous methods for addressing scale issues arising from a range of disciplines that intersect with landscape ecology which require further consideration and definition. Studies which combine methods that explicitly account for the multi-dimensional nature of spatial and thematic resolution, using mechanistic models and/or spatial statistics represent a promising area of future research.
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Acknowledgements
We thank the anonymous reviewers for their constructive feedback which has significantly improved the quality of the manuscript. This work was supported by funding from the Australian Research Council Centre of Excellence for Environmental Decisions.
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Lechner, A.M., Rhodes, J.R. Recent Progress on Spatial and Thematic Resolution in Landscape Ecology. Curr Landscape Ecol Rep 1, 98–105 (2016). https://doi.org/10.1007/s40823-016-0011-z
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DOI: https://doi.org/10.1007/s40823-016-0011-z