Refined NIDIS Application for the Upper Colorado River Basin

Andrew Barney

CEE 6440 – GIS in Water Resources

December 3, 2010

 

 

 

 

 

 

 

Contents

 

 

Introduction

Background

The National Drought Policy Act of 1998 established a commission to ensure a collaborative effort to address drought related issues. The National Integrated Drought Information System (NIDIS) was envisioned to improve drought monitoring and forecasting capabilities.

The U.S. Drought Portal currently provides early warning about droughts and provides various stakeholders with information to help prepare for them and mitigate negative impacts. Warning systems currently predict drought conditions on a regional scale.

Figure 1: NIDIS Drought Monitor Portal

Objective

A more refined drought forecasting system would greatly benefit the public by offering drought forecasts at a much smaller scale. Less guesswork regarding drought conditions in a particular area will allow stakeholders to make more informed decisions on how to adjust activities based on these conditions. A user interface for observing refined drought conditions would demonstrate the utility of higher resolution drought forecasting.

Numerous drought forecasting techniques and models exist and researchers continue to refine them in an effort to predict droughts with greater reliability. An interface that provides relevant spatial data and connections to appropriate web services would be an excellent aid for such researchers.

Creating a complete user interface at a scale that would be useful for drought forecasting research far exceeds the scope of this project. A task of a much smaller scale but still significant value involves creating a GIS framework of limited scope for visualization of drought conditions. The project will demonstrate the general processes, requirements and challenges involved with creating a more ambitious refined NIDIS application for visualization of drought conditions.

Scope

Research is currently being performed on a refined NIDIS application for the Upper Colorado River Basin (UCRB) at the Utah Water Research Laboratory (UWRL). Thus, a great deal of data required for drought forecasting has already been determined for this study area. Using a subset of this area would take advantage of these previous efforts.

The revised Surface Water Supply Index authored by David Garen is currently used by the state of Colorado as the method of choice for their seasonal water supply forecasts. This method is suited well for the mountain west where snowmelt is a large component of runoff and frequent reservoirs dot the landscape.

A small area around Gunnison, Colorado serves as a good location to focus on for this project. The area borders the edges of the UCRB which provides a logical outer boundary for the study area. The area also contains numerous stream gages and reservoirs collecting relevant data. The region is a good example of the type of terrain, climate and hydrologic conditions expected across the remainder of the UCRB. The total size of the study area was reduced over the course of the project to reduce the time needed for drought index calculations.

The spatial units used to display drought index calculations for this analysis are Hydrologic Unit Code (HUC) 10-digit watersheds. This scale is far more refined than what forecasts are currently shown at but not so small that scarcity of local data inhibits the utility of the calculations, computational times become excessive, or visualization of the spatial units becomes problematic.      

Description: NIDISNew

Figure 2: Upper Colorado River Basin and Project Study Area

Method

Data Collection 

Both spatial and tabular data are required for the analysis. Descriptions, sources and preparation of these data are listed below.

Spatial Data

HUC 10 Polygons:  The Watershed Boundary Dataset (WBD) provides watershed boundary shapefiles at different scales. These scales are referred to by how many digits of an ID code is required to identify them. For example, the Upper Colorado River Basin is represented by the 2-digic HUC code (HUC 2) 14. The WBD has shapefiles at scales of HUC 12 and HUC 8 polygons. However, the HUC 12 shapefile contains a HUC 10 watershed field. Using the Dissolve operation within ArcGIS a HUC 10 feature class is easily obtained.

River Network:  The river network is required for delineating which areas are associated with particular runoff data. A flowline shapefile was obtained from NHDPlus, a source for a large collection of accurate hydrologic spatial data.

Catchments:   Catchments are the smallest watersheds delineated as part of the NHDPlus. This shapefile was used in conjunction with the river network to delineate areas associated with runoff data. 

Stream Gage Locations:  Streamflow forecasts are required by the revised SWSI calculations. The Colorado Basin River Forecast Center (CBRFC) produces streamflow forecasts for this area and provided a shapefile of gage locations. Upon further research, this list was reduced to include only those stations with published streamflow forecasts.

Reservoir Locations:  Reservoir storage is required as part of the revised SWSI calculations. The US Bureau of Reclamation (USBR) does not offer prepared GIS spatial data. Thus, a reservoir location shapefile was created using spatial data found at the USBR website. Only reservoir locations currently reporting data were collected.

Description: spatialdata

Figure 3: Study Area Showing HUC 10 Watersheds, River Network, USBR Reservoirs and Forecast Stream Gages

Tabular Data

Streamflow Forecasts: Streamflow forecasts were obtained from reports found through the CRBFC.

Historic Streamflow Data: Historic monthly streamflow data (required to find non-exceedance probabilities required by the revised SWSI method) were obtained from the US Geological Survey (USGS).

Reservoir Storage Data:  Reservoir storage data were obtained through a USBR portal.

Revised SWSI Method

Background

The revised SWSI method was developed by David Garen as an attempt to fine tune the SWSI method which relied greatly on subjective weighting coefficients and did not facilitate the comparison of conditions in different watersheds. The revised SWSI is intended (as was the original SWSI) to reflect drought conditions in snow dominated regions indicative of the American Mountain West. Drought forecasting using this method uses total runoff as the sum of streamflow and water captured in reservoirs. Snowpack is indirectly figured into calculations through the use of streamflow forecasts.

While streamflow and the change in reservoir storage reflects actual runoff conditions, streamflow forecasts represent expected runoff volumes. The CRBFC uses snowpack, previous streamflow and other hydrologic and climate data to make these predictions. Forecasted streamflows represent total natural runoff, not the flows recorded at stream gages. This is important as it means that changes in reservoir storage do not need to be forecasted.

Process

The calculations required to determine the revised SWSI index value are relatively straightforward. Streamflow and reservoir storage data represent known runoff data and are used to determine non-exceedance criteria at each gaging station. This is a common statistical process in the field of hydrology, the steps of which are outlined below.

Streamflow forecasts for the gages in the study area give predictions of total streamflow volume in acre-feet for April through July. Monthly statistical data downloaded from USGS is converted from cubic feet per second to a total volume in acre-feet over the four summer months for the period of record. Reservoir storage data downloaded from USBR is used to find the change of storage of all reservoirs associated with the streamflow gage (see section on interpolation) between April 1 and July 31 for the period of record. The sum of total streamflow and change of reservoir volume represents the total runoff for each forecast gage location (note that records are only used for years when the streamflow gage and all reservoirs associated with it are reporting data).

Table 1: Sample of Total Runoff Results for Taylor (below Taylor Reservoir) Streamflow Gage

Year

Apr - Jul SF (kaf)

Δ S Reservoirs (kaf)

Total Runoff (kaf)

2010

32.922

25.2

58

2009

84.888

25.1

110

2008

119.172

16.3

135

2007

66.618

13.7

80

2006

55.122

18.2

73

2005

61.458

22.6

84

2004

48.726

16.6

65

2003

39.996

36.6

77

2002

42.912

-8.02

35

2001

55.2

15.4

71

2000

64.068

12.9

77

 

Total runoff values for the period of record are ranked, and non-exceedance probabilities calculated. The SWSI index is calculated using the formula below, where P is the probability of non-exceedance of the streamflow forecast value (found by interpolation of the forecast runoff using the ranked values). The formula is designed to produce an index between -4.1 (extreme drought) and 4.1 (extremely wet). 

 


 

Equation 1: Revised SWSI Equation

 

Table 2: Table Translating Total Runoff to SWSI Value for Taylor (below Taylor Reservoir) Streamflow Gage

Rank

Q tot (acft)

Non-exceedance (%)

SWSI

25

86.116

47.16981132

-0.23585

26

90.725

49.05660377

-0.07862

27

92.729

50.94339623

0.078616

28

93.125

52.83018868

0.235849

29

94.394

54.71698113

0.393082

30

96.317

56.60377358

0.550314

31

101.089

58.49056604

0.671666

32

101.416

60.37735849

0.86478

33

103.422

62.26415094

1.022013

34

105.2111

64.1509434

1.179245

 

The table below shows a sample of results for several calculations of revised SWSI indexes, including calculations using actual, instead of forecast, values. Drought index calculations are generally made when streamflow forecasts are published at the beginning of each month from January to June.  

Table 3: Sample of Final SWSI Values for Gage Watersheds

USGS ID

Name

Year

Month

Forecast Runoff (kaf)

Actual Runoff (kaf)

Forecase SWSI

Actual SWSI

Difference

9109000

Taylor Blw Taylor Park Res

2005

Jan

100

83

0.68

-0.25

0.93

Feb

110

83

1.70

-0.25

1.95

Mar

110

83

1.70

-0.25

1.95

Apr

105

83

1.16

-0.25

1.41

May

100

83

0.68

-0.25

0.93

Jun

90

83

-0.06

-0.25

0.19

9110000

Taylor @ Almont

2005

Jan

160

100

2.53

-0.40

2.93

Feb

177

100

2.60

-0.40

3.00

Mar

177

100

2.60

-0.40

3.00

Apr

168

100

2.24

-0.40

2.64

May

160

100

2.13

-0.40

2.53

Jun

138

100

1.60

-0.40

2.00

9112500

East @ Almont

2005

Jan

190

188

0.81

0.61

0.19

Feb

220

188

2.00

0.61

1.38

Mar

215

188

1.95

0.61

1.34

Apr

205

188

1.31

0.61

0.70

May

160

188

-0.71

0.61

1.32

Jun

192

188

0.91

0.61

0.30

 

Interpolation

Concept

 

The most difficult consideration involved in the development of this GIS framework involves interpolation of data. The spatial units chosen to visualize drought index values (in this case, HUC 10 watersheds) do not generally exhibit an obvious association with gages reporting the data necessary for calculations. Some thought and study must go into an interpolation process which accurately associates the correct data (or combination of data) with each spatial unit.  

 

Streamflow at any point along a network can be described as the accumulation of all runoff upstream from that point minus losses and storage. Thus, streamflow data is relevant as an indicator of conditions upstream from a gage. In other words, the closest downstream gage gives the most relevant data for a particular area. Likewise, reservoir storage should be associated with the closest downstream streamflow gage. Reservoirs create a reduction in runoff that would otherwise be attributed to this gaging station. 

 

Process

 

A watershed delineated between gaging stations represents an area over which a particular drought index value (calculated using data from a particular gaging station) is the most relevant. To create polygons over these areas the following process was followed:

 

 

Description: GWSCreation

Figure 4: Gage Watershed Creation - Trace Upstream Using Utility Network Analyst & Assign Gage ID to Stream Network Elements

Description: catch

Figure 5: Catchments and River Network

The result is a polygon feature class or gage watersheds (GWS) with each polygon associated with a stream gage (Figure 6). Note that reservoirs associated with a gage are contained within the corresponding GWS.

Description: GWS

Figure 6: Delineated Gage Subwatersheds

 

Next, SWSI values (calculated using excel) are assigned to each GWS and interpolated using area weighted averages so they can be associated with the HUC 10 watersheds. Because this process must be performed many times, a simple model was created to accomplish this step.

 

The model (shown below) completes these steps:

 

 

Description: Model

 

 

 

With some symbology changes, SWSI drought index values can be visualized at the level of HUC 10 watersheds (Figure 7).

 

Results

Figure 7 shows an example of the visualization expected from a refined NIDIS application.

Description: final

Figure 7: HUC 10 Catchments with Symbology Showing SWSI Values for Jan 2005

As would be expected, variance from actual conditions decreases the later in the year the SWSI value is calculated (Figure 8).

 

Description: JanVarianceDescription: junevariance

Figure 8: Variance from Actual Conditions for January and June forecasts

The process performed to achieve these results (gathering data, preprocessing, interpolation and visualization) sheds light on many techniques that would be useful for developing a fully functional NIDIS GIS framework. Also, many issues were uncovered that require further attention in order for a larger scale project to proceed.      

 

Discussion

The manner of interpolation presented in this report is a good case study for interpolation of other data values. For example, if someone wanted to use Thiessen polygons to assign precipitation values to HUC 10 watersheds in preparation for a drought index calculation, much the same process as above could be followed. With some adjustments other interpolation techniques such as inverse distance weighted, nearest neighbor, or elevation weighted interpolation (appropriate for snowpack data) could be used to assign appropriately weighted values to HUC 10 catchments. Whether calculations are performed before or after interpolation of variables depends on what the calculations call for. For the revised SWSI method, index values were found for the GWS areas then interpolated to the spatial units because there was essentially only one set of values to interpolate. If there are many difference variables requiring different types of interpolation, it would be necessary to interpolate the values separately then compute index values using the field calculator. Another option for this situation would be converting different variables interpolated over the study area to raster datasets, compute index values using raster calculations, then interpolate to the spatial units.  

 

Data collection was one of the most problematic and time consuming parts of this project. An initial set of forecast streamflow gages provided by the CBRFC proved to be deceptive, with just over half of these gages providing publicly available river forecasts. Reservoir data is likely not complete  (see below), and even the data available is very difficult and slow to obtain. More streamlined webservices for providing the data necessary for drought forecasting analysis is essential in order to create an effective system.  

 

As shown in Table 3, forecast streamflows almost always exceeded calculations of actual runoff (forecasts on average predict 20% more runoff than actual conditions show). Overestimating water supply is not erring on the side of safety, and thus there must be some discrepancies in the data. There is likely a large discrepancy because streamflow forecasts add “adjustments” to make up for diversions from the stream. Although the large reservoirs were accounted for in the calculations presented in this report, there are many other adjustments made to the runoff calculations of which the general public is not aware. The process for determining streamflow forecasts should be made more transparent to allow data to be used correctly in drought forecast analysis.

 

 

Conclusion

Many of the difficulties and encountered during the completion of this project were associated with data collection and tedious, time-consuming computations. In the context of a larger NIDIS project, however, these two issues do not fall within the scope of a GIS framework. An understanding of drought forecasting techniques, interpolation, hydrologic processes and relevant variables is necessary for completing this portion of the project. Some techniques demonstrated above will form the foundation for a larger scale NIDIS project. The process of completing this project was valuable in developing a more in depth plan of action for a larger project and for realizing the biggest barriers and most important dimensions to focus on.

 

 

References

 

Alcorn, Brenda. “Water Supply Forecasting Tools and Processes”, Colorado River Commission Technical Workshop. 5 Dec, 2008.

“CBRFC Conditions”, National Weather Service Colorado Basin River Forecast Center. < http://www.cbrfc.noaa.gov/>

Garen, David C. 1993. “Revised Surface Water Supply Index (SWSI) for Western United States.” Journal of Water Resources Planning and Mangement 119, no. 4 (July/Aug): 437-454.

“National Hydrography Dataset Plus” Horizon Systems Corporation. < http://www.horizon-systems.com/nhdplus/>

 “Upper Colorado Region Reservoir Operations”, Bureau of Reclamation <http://www.usbr.gov/uc/crsp/GetSiteInfo>

U.S. Drought Portal, National Integrated Drought Information System. <http://www.drought.gov/portal/server.pt/community/drought_gov/202>

“USGS Real-Time Water Data for the Nation” USGS. < http://waterdata.usgs.gov/nwis/rt>

 “Water Supply Forecasting Tools”, Colorado Basin River Forecast Center. <http://www.cbrfc.noaa.gov/wsup/doc/cbrfc_ws_tools.pdf> 29 Nov, 2010.