New opportunities in ecological sensing using wireless sensor networks

Collins, Scott L.; Bettencourt, Luís M. A.; Hagberg, Arie; Brown, Renée F; Moore, Douglas I.; Bonito, Greg; Delin, K. A.; Jackson, Shannon P.; Johnson, David W.; Burleigh, Scott; Woodrow, Richard R.; McAuley, J. M.

doi:10.1890/1540-9295(2006)4[402:noiesu]2.0.co;2

Cited by 90 publications

(72 citation statements)

References 3 publications

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“…Emerging sensor technology and networks are improving capabilities for environmental monitoring (6,8). These technologies hold considerable promise for data-intensive and spatially extensive studies of ecosystem processes, such as metabolism, ecosystem stability, resilience, and threshold detection.…”

Section: Resultsmentioning

confidence: 99%

Changes in ecosystem resilience detected in automated measures of ecosystem metabolism during a whole-lake manipulation

Batt

Carpenter

Cole

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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Environmental sensor networks are developing rapidly to assess changes in ecosystems and their services. Some ecosystem changes involve thresholds, and theory suggests that statistical indicators of changing resilience can be detected near thresholds. We examined the capacity of environmental sensors to assess resilience during an experimentally induced transition in a wholelake manipulation. A trophic cascade was induced in a planktivoredominated lake by slowly adding piscivorous bass, whereas a nearby bass-dominated lake remained unmanipulated and served as a reference ecosystem during the 4-y experiment. In both the manipulated and reference lakes, automated sensors were used to measure variables related to ecosystem metabolism (dissolved oxygen, pH, and chlorophyll-a concentration) and to estimate gross primary production, respiration, and net ecosystem production. Thresholds were detected in some automated measurements more than a year before the completion of the transition to piscivore dominance. Directly measured variables (dissolved oxygen, pH, and chlorophyll-a concentration) related to ecosystem metabolism were better indicators of the approaching threshold than were the estimates of rates (gross primary production, respiration, and net ecosystem production); this difference was likely a result of the larger uncertainties in the derived rate estimates. Thus, relatively simple characteristics of ecosystems that were observed directly by the sensors were superior indicators of changing resilience. Models linked to thresholds in variables that are directly observed by sensor networks may provide unique opportunities for evaluating resilience in complex ecosystems.regime shift | alternative stable states | early warning signals | sonde | high-frequency time series

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Section: Resultsmentioning

confidence: 99%

Changes in ecosystem resilience detected in automated measures of ecosystem metabolism during a whole-lake manipulation

Batt

Carpenter

Cole

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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“…They can collect data on various environmental variables which can be used to describe complex ecosystem forest processes continually in a non-invasive, cost-effective, automated and real-time manner [53,[79][80][81]. The design of the network, e.g., the spatial separation of the network nodes (sensor nodes), depends on the spatial variability of the environmental variables and ranges from centimetres to a maximum of about 1km depending on the wireless communication technology used.…”

Section: Close-range Rs Approaches-wireless Sensor Network (Wsn)mentioning

confidence: 99%

Understanding Forest Health with Remote Sensing-Part II—A Review of Approaches and Data Models

et al. 2017

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Stress in forest ecosystems (FES) occurs as a result of land-use intensification, disturbances, resource limitations or unsustainable management, causing changes in forest health (FH) at various scales from the local to the global scale. Reactions to such stress depend on the phylogeny of forest species or communities and the characteristics of their impacting drivers and processes. There are many approaches to monitor indicators of FH using in-situ forest inventory and experimental studies, but they are generally limited to sample points or small areas, as well as being time-and labour-intensive. Long-term monitoring based on forest inventories provides valuable information about changes and trends of FH. However, abrupt short-term changes cannot sufficiently be assessed through in-situ forest inventories as they usually have repetition periods of multiple years. Furthermore, numerous FH indicators monitored in in-situ surveys are based on expert judgement. Remote sensing (RS) technologies offer means to monitor FH indicators in an effective, repetitive and comparative way. This paper reviews techniques that are currently used for monitoring, including close-range RS, airborne and satellite approaches. The implementation of optical, RADAR and LiDAR RS-techniques to assess spectral traits/spectral trait variations (ST/STV) is described in detail. We found that ST/STV can be used to record indicators of FH based on RS. Therefore, the ST/STV approach provides a framework to develop a standardized monitoring concept for FH indicators using RS techniques that is applicable to future monitoring programs. It is only through linking in-situ and RS approaches that we will be able to improve our understanding of the relationship between stressors, and the associated spectral responses in order to develop robust FH indicators.

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“…Ecology is increasingly becoming a data-intensive science (see Glossary) [1,2], relying on massive amounts of data collected by both remote-sensing platforms [3] and sensor networks that are embedded in the environment [4][5][6][7]. New observatory networks, such as the US National Ecological Observatory Network (NEON) [8] and Global Lake Ecological Observatory Network (GLEON) [9], provide research platforms that enable scientists to examine phenomena across diverse ecosystem types through access to thousands of sensors collecting diverse environmental observations.…”

Section: Ecology As An Evolving Disciplinementioning

confidence: 99%

“…Decreases in the size, cost and power requirements of sensors have revolutionized their use to monitor biota and environmental processes [4,5] and provide access to those data in real or near-real time [9]. New environmental observing systems, such as NEON [8] and the Ocean Observatories Initiative (OOI) [23], will provide access to data collected by aerial, ground-based and underwater sensor networks encompassing tens of thousands of sensors that, when combined, will generate terabytes to petabytes of data annually.…”

Section: What Is Ecoinformatics?mentioning

confidence: 99%