Technical report: The design and evaluation of a basin‐scale wireless sensor network for mountain hydrology

Autor:	Steven D. Glaser, Danny Marks, Robert Rice, Roger C. Bales, Ziran Zhang, Martha H. Conklin
Rok vydání:	2017
Předmět:	Engineering Environmental Engineering 010504 meteorology & atmospheric sciences Meteorology 0208 environmental biotechnology Clock drift 02 engineering and technology Civil Engineering 01 natural sciences Physical Geography and Environmental Geoscience Physical Sciences and Mathematics Sierra Nevada 0105 earth and related environmental sciences Water Science and Technology Remote sensing water-information system Hydrology business.industry Elevation Humidity Lapse rate Wireless-sensor network Snowpack Snow snow observation 020801 environmental engineering Applied Economics mountain hydrology business Wireless sensor network Multipath propagation
Zdroj:	Zhang, Ziran; Glaser, Steven D; Bales, Roger C; Conklin, Martha; Rice, Robert; & Marks, Danny G. (2017). Technical report: the design and evaluation of a basin-scale wireless sensor network for mountain hydrology. Water Resources Research. UC Office of the President: Research Grants Program Office (RGPO). Retrieved from: http://www.escholarship.org/uc/item/6b8846ff Zhang, Z; Glaser, SD; Bales, RC; Conklin, M; Rice, R; & Marks, DG. (2017). Technical report: The design and evaluation of a basin-scale wireless sensor network for mountain hydrology. Water Resources Research, 53(5), 4487-4498. doi: 10.1002/2016WR019619. UC Merced: Retrieved from: http://www.escholarship.org/uc/item/24f413p3 Water Resources Research, vol 53, iss 5
ISSN:	1944-7973 0043-1397
DOI:	10.1002/2016wr019619
Popis:	© 2017. American Geophysical Union. All Rights Reserved. A network of sensors for spatially representative water-balance measurements was developed and deployed across the 2000 km2snow-dominated portion of the upper American River basin, primarily to measure changes in snowpack and soil-water storage, air temperature, and humidity. This wireless sensor network (WSN) consists of 14 sensor clusters, each with 10 measurement nodes that were strategically placed within a 1 km2area, across different elevations, aspects, slopes, and canopy covers. Compared to existing operational sensor installations, the WSN reduces hydrologic uncertainty in at least three ways. First, redundant measurements improved estimation of lapse rates for air and dew-point temperature. Second, distributed measurements captured local variability and constrained uncertainty in air and dew-point temperature, snow accumulation, and derived hydrologic attributes important for modeling and prediction. Third, the distributed relative-humidity measurements offer a unique capability to monitor upper-basin patterns in dew-point temperature and characterize elevation gradient of water vapor-pressure deficit across steep, variable topography. Network statistics during the first year of operation demonstrated that the WSN was robust for cold, wet, and windy conditions in the basin. The electronic technology used in the WSN-reduced adverse effects, such as high current consumption, multipath signal fading, and clock drift, seen in previous remote WSNs.
Databáze:	OpenAIRE
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