Sage Journals: Discover world-class research

Abstract

Water resource managers and scientists have recognized the need for data at spatial and temporal resolutions relevant to the hydrological cycle. The dearth of hydrological data sets has been noted as a critical barrier to developing effective water resource management strategies. Limited funding has been noted as a major contributing factor to the limited establishment of sustainable environmental monitoring networks to capture these data sets. To address these concerns, an inexpensive real-time hydrological monitoring station (RTHS) was designed to collect data with similar performance to existing commercially available sensors. The RTHS was built with both commercially available and custom-engineered components, using enabling technology to reduce capital and operations and maintenance costs. The RTHS incorporated a modular design for easy integration of multiple sensors and implementation of upgrades with less expensive and more reliable components as emerging technologies become available. Inexpensive stage height, water temperature, and all-season precipitation sensors were designed, fabricated, and tested in house. Integration of components into a comprehensive hydrological monitoring system required custom hardware designs and software routines. Controlled laboratory and field evaluations with a colocated research-grade sensor indicated that the designed precipitation gauge provides a low-cost alternative with comparable performance to commercially available off-the-shelf sensors. The designed stage height sensor performed well in laboratory evaluations and interobservatory comparisons at independently operated stations in the Hudson River watershed as demonstrated by strong correlations (R² = 0.99, root mean square discrepancy = 1.4–3.2 cm) between stage height data sets.

Get full access to this article

View all access options for this article.

References

Andreassian

, Perrin

, Michale

, Usart-Sanchez

, and Lavabre

(2001). Impact of imperfect rainfall knowledge on the efficiency and the parameters of wateshed model. J. Hydrol., 250, 206.

Barnett

T.P.

, Adam

J.C.

, and Lettenmaier

D.P.

(2005). Potential impacts of a warming climate on water availability in snow dominated regions. Nature. 438, 303.

Basara

J.B.

, Illston

B.G.

, Winning

T.E.

, and Fiebrich

C.A.

(2009). Evaluation of rainfall measurements from the WXT510 Sensor for use in the Oklahoma City Micronet. Open Atmos. Sci. J., 3, 39.

Becker

, Schiebelsberger

, Weber

, Vodermayer

, Zehner

, and Kummerle

(2006). An Approach to the Impact of Snow on the Yield of Grid Connected PV Systems. Munich: Bavarian Association for the Promotion of Solar Energy.

Ciach

G.J.

(2003). Local random errors in tipping-bucket rain gauge measurements. J. Atmos. Oceanic Technol., 20, 752.

DeWalle

, and Rango

(2008). Principles of Snow Hydrology. New York: Cambridge University Press.

Dunkerley

(2008). Identifying individual rain events from pluviograph records: A review with analysis of data from an Australian dryland site. Hydrol. Process., 22, 5024.

Emerson

D.G.

, and Macek-Rowland

K.M.

(1990). Solid-precipitation (snowfall) measurement intercomparison, Bismarck, North Dakota. U.S. Geological Survey, Open-File Report 90–124.

Gilbert

(2010). A dearth of data on water resources is holding up improved management practices. Nature. (published online 4 Oct. 2010) DOI: 10.1038/news.2010.490.

10.

Gordon

J.D.

(2003). Evaluation of candidate rain gauges for upgrading precipitation measurement tools for the national atmospheric deposition program. U.S. Geological Survey, Water-Resources Investigations Report 02–4302.

11.

Harmancioglu

N.B.

, and Alpaslan

(1992). Water quality monitoring network design: A problem of multi-objective decision making. J. Am. Water Res. Assoc., 28, 179.

12.

HRECOS. (2016a). Hudson River Environmental Conditions Observing System. Schodack Island Hydrologic Station data. Available at: www.hrecos.org/ (accessed July 24, 2016).

13.

HRECOS (2016b). Hudson River Environmental Conditions Observing System. Piermont Pier Hydrologic Station data. Available at: www.hrecos.org/ (accessed July 24, 2016).

14.

Hubbart

, Link

, Campbell

, and Cobos

(2005). Evaluation of a low-cost temperature measurement system. Hydrol. Process., 19, 1517.

15.

Huntington

T.G.

(2006). Evidence for intensification of the global water cycle: Review and synthesis. J. Hydrol., 319, 83.

16.

Jackson

R.B.

, Carpenter

S.R.

, Dahm

C.N.

, McKnight

D.M.

, Naiman

R.J.

, Postel

S.L.

, and Running

S.W.

(2001). Water in a changing world. Ecol. Applic., 11, 1027.

17.

Jordan

(2000). Sampling errors in radar estimates of rainfall. J. Geophys. Res. Atmos., 105, 2247.

18.

Maidment

D.R.

(1993). Handbook of Hydrology. New York: McGraw-Hill, Inc.

19.

Montgomery

J.L.

, Harmon

, Haas

C.N.

, Hooper

, Clesceri

N.L.

, Graham

, Kaiser

, Sanderson

, Minsker

, Schnoor

, and Brezonik

(2007). The WATERS network: An integrated environmental observatory network for water research, Environ. Sci. Technol., 41, 6642.

20.

Mui

C.K.

, Royem

A.A.

, and Walter

M.T.

(2010). Low-Cost Stream Gaging Through Analysis of Stage Height Using Digital Photography, AGU Fall Meeting (Abstract No. H51D- 0930). San Francisco, CA. Available at http://adsabs.harvard.edu/abs/2010AGUFM.H51D0930M (accessed July 15, 2016).

21.

NOAA. (2016) National Climate Data Center. Available at: www.ncdc.noaa.gov/cdo (accessed June 24, 2016).

22.

Parry

M.L.

, Canziani

O.F.

, Palutikof

J.P.

, van der Linden

P.J.

, and Hanson

C.E

. eds. (2007). Climate Change 2007: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the 4th Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge, U.K.: Cambridge University Press.

23.

Piasecki

, Ames

, Goodall

, Hooper

, Horsburgh

, Maidment

, Tarboton

, and Zaslavsky

(2010). Development of an Information System for the Hydrologic Community, 9th International Conference on Hydroinformatics (HIC 2010). Tianjin, China.

24.

Raghunath

H.M.

(2006). Hydrology: Principles, Analysis and Design. New Delhi: New Age International. 2006- Hydrology, p. 476.

25.

Revenga

, Campbell

, Abell

, de Villiers

, and Bryer

(2005). Prospects for monitoring freshwater ecosystems towards the 2010 targets. Phil. Trans. R. Soc. Lond. B., 360, 397.

26.

Sauer

V.B.

, and Turnipseed

D.P.

(2010). Stage Measurement at Gaging Stations. U.S. Geological Survey Techniques and Methods Book 3, Chapter A7, p. 45. Available at http://pubs.usgs.gov/tm/tm3-a8/ (accessed July 15, 2016).

27.

Schuurmans

J.M.

and Bierkens

M.F.P.

(2007). Effect of spatial distribution of daily rainfall on interior catchment response of a distributed hydrological model. Hydrol. Earth Syst. Sci., 11, 677.

28.

Tabler

R.D.

, Berg

N.H.

, Trabant

D.C.

, Santeford

H.S.

, and Richard

P.A.

(1990). Measurement and evaluation of winter precipitation. In Ryan

W.L.

and Crissman

R.D.

, Eds., Cold Regions Hydrology and Hydraulics Monograph. New York: American Society of Civil Engineers, pp. 9–38.

29.

U.S.G.S. (2016). National Water Information System: Web Interface. Available at: http://waterdata.usgs.gov/nwis/rt (accessed June 24, 2016).

30.

U.S. National Weather Service. (1989). Cooperative Station Observations NWS Observing Handbook No. 2. Silver Spring, MD. Available at http://www.nws.noaa.gov/os/coop/Publications/coophandbook2.pdf (accessed July 15, 2016).

31.

Villarni

, Mandapaka

P.V.

, Krajewski

W.F.

, and Moore

R.J.

(2008). Rainfall and sampling uncertainties: A rain gauge perspective. J. Geophys. Res., 113, D11102.

32.

Vladisauskas

, and Jakevivius

(2004). Absorption of Ultrasonic waves in Air, Ultragaesas, Nr.1(50), ISSN 1392–2114.

33.

Wang

, Xie

, Sharif

, and Zeitler

(2008). Validating NEXRAD MPE and Stage III precipitation products for uniform rainfall on the upper Guadalupe river basin of the Texas Hill Country. J. Hydrol., 348, 73.

34.

Warner

J.C.

, Geyer

W.R.

, and Lerczak

J.A.

(2005). Numerical modeling of an estuary: A comprehensive skill assessment. J. Geophys. Res., 110, C05001.

35.

World Meteorological Organization. (2008). Guide to Meteorological Instruments and Methods of Observation. Available at https://www.wmo.int/pages/prog/gcos/documents/gruanmanuals/CIMO/CIMO_Guide-7th_Edition-2008.pdf (accessed July 15, 2016).

36.

Yang

, Goodison

B.E.

, and Metcalfe

J. R.

(1998). Accuracy of NWS 8″ standard nonrecording precipitation gauge: Results and application of WMO intercomparison. J. Atmos. Oceanic Technol., 15, 54.

37.

Yang

, Goodison

B.E.

, Metcalfe

J.R.

, Louie

, Leavesley

, Emerson

, et al. (1999). Quantification of precipitation measurement discontinuity induced by wind shields on national gauges. Water Resour. Res., 35, 491.

Low-Cost Stand-Alone System for Real-Time Hydrological Monitoring

Abstract

Abstract

Get full access to this article

References