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Remote sensing acquires and interprets small or large-scale data about the Earth from a distance. Using a wide range of spatial, spectral, temporal, and radiometric scales remote sensing is a large and diverse field for which this Handbook will be the key research reference. This Handbook is organized in four key sections: • Interactions of Electromagnetic Radiation with the Terrestrial Environment: chapters on Visible, Near-IR and Shortwave IR; Middle IR (3-5 micrometers); Thermal IR; Microwave • Digital sensors and Image Characteristics: chapters on Sensor Technology; Coarse Spatial Resolution Optical Sensors; Medium Spatial Resolution Optical Sensors; Fine Spatial Resolution Optical Sensors; Video Imaging and Multispectral Digital Photography; Hyperspectral Sensors; Radar and Passive Microwave Sensors; Lidar • Remote Sensing Analysis: Design and Implementation: chapters on Image Pre-Processing; Ground Data Collection; Integration with GIS; Quantitative Models in Remote Sensing; Validation and accuracy assessment; • Remote Sensing Analysis: Applications: LITHOSPHERIC SCIENCES: chapters on Topography; Geology; Soils; PLANT SCIENCES: Vegetation; Agriculture; HYDROSPHERIC and CRYSOPHERIC SCIENCES: Hydrosphere: Fresh and Ocean Water; Cryosphere; GLOBAL CHANGE AND HUMAN ENVIRONMENTS: Earth Systems; Human Environments & Links to the Social Sciences; Real Time Monitoring Systems and Disaster Management; Land Cover Change Illustrated throughout, an essential resource for the analysis of remotely sensed data, The SAGE Handbook of Remote Sensing provides researchers with a definitive statement of the core concepts and methodologies in the discipline.

Remote Sensing Scale and Data Selection Issues

Timothy A. Warner M. Duane Nellis Giles M. Foody

Keywords

  • remote sensing data
  • scale
  • spectral scale
  • spatial scale
  • temporal scale
  • radiometric scale.

Introduction

Remote sensing can be termed a mature discipline, in the sense that the underlying physical principles are well understood, and applications are beginning to appear in operational contexts spanning a diverse array of applications. In addition, the supporting technology has evolved to the extent that image acquisition, field work, and digital analysis are today much more sophisticated than in the early days of analog imaging, computer mainframe-based processing, and qualitative analysis. However, with the wide range of remotely sensed data that is now available, the rapid and continued advances in the power and storage capacity of modern desktop computers, and the sophistication of the many software packages available, remote sensing is far from a static field. Indeed, the last decade has seen the development of commercial fine resolution remote sensing from space (Toutin, in this volume), the exponential growth of lidar (also known as airborne laser scanning) (Hyyppä et al., in this volume), and the increasing sophistication and automation of image processing, to name just a few examples. This rapid evolution of remote sensing technology suggests that there is a need for a periodic and relatively comprehensive review of the field of remote sensing. This book is an attempt to address that need.

In this introductory chapter we lay the groundwork for a theme that is common throughout many of the chapters in this book, namely, the trade-offs and issues that should be considered in selecting data for a specific problem. For example, in Chapter 25 Wulder et al. consider data selection within the context of vegetation characterization, and in Chapter 31, Crews and Walsh review data selection from the perspective of social scientists. This introductory chapter provides a broad perspective on this important topic.

Ironically, selecting data is today more challenging than in the past, a consequence of the wide range of data currently available. In the past, few remotely sensed data sets were available, and consequently the properties of the available data tended to determine the nature of the problems that could be addressed. Thus, an important part of early remote sensing research using the Earth Resources Technology Satellite (ERTS, later renamed Landsat) was simply to ask the question, ‘What can we do with these new data?’ Today, we have a vast array of data to select from in remote sensing, and so a new problem has emerged – how do we optimize the data characteristics that we use, so that the data will most effectively address a particular application or research problem? It should thus be clear that the definition of an optimal data set is entirely dependent on the aims of the project for which the data are intended.

Adding to the complexity of choosing data attributes are three related issues. Firstly, there are fundamental physical and engineering tradeoffs that limit the nature and detail of the data that can be collected using an imaging system (Kerekes, in this volume; Figure 1.1). These constraints help explain the design choices made in satellite-borne sensors, and likewise need to be considered by those planning their own custom acquisitions of aerial imagery (Stow, in this volume).

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