The map opens in Map Viewer Classic to the state of Colorado.

The map contains data on existing wind farms in Colorado. Before exploring the map and the layers that you'll query and analyze, you'll create a personal copy of the map.

A copy of the map is now saved to your Content folder. You can access it at any time through the Content tab on the home page. Now that you've saved your map, you'll look at the data you have available to work with.

The Counties layer has population data for all 64 counties in Colorado. Some counties have higher population densities than others, which means higher energy demands. Because building new transmission lines is costly and detrimental to the environment, you want to identify locations with high demand for power to reduce the need to build additional transmission lines. This layer contains data that will allow you to check the first and second criteria: that the wind farm site is in the state of Colorado and has a high enough population density.

Pop-ups appear as you click the counties with additional information about each county, such as population density.

The counties along the Front Range, including Boulder and Denver, have the highest population densities in the state.

The turbines are now visible.

The legend for Wind Power Class appears in the Contents pane.

The Wind Power Class layer data is classified into seven classes. These classes represent average (mean) wind speed as calculated for heights of 10 meters (33 feet) and 50 meters (164 feet). Wind speed is a good indicator of the power generating capacity of wind. Generally, the higher the wind speed, the greater the power generating capacity at a location.

The following table illustrates wind speed for heights at 10 meters (33 feet) and 50 meters (164 feet):

A certainty rating was assigned to each grid cell based on these three factors and is included in the National Renewable Energy Laboratory (NREL) Renewable Energy (RE) Atlas for the United States Department of Energy (DOE).

Notice that the wind power class is generally light to moderate in the western part of the state, with a narrow windy zone on the lee (east) side of the continental divide (running generally north-south in the central part of the state), a lower wind power class in a band to the east of this, and then changing to windier conditions as you get closer to the borders of Kansas and Nebraska.

The attribute table appears for the layer.

All the attributes in the layer are now visible in the table.

Wind power class is stored in an attribute named GRIDCODE, and the corresponding mean wind speeds are given in miles per hour.

• Areas designated as Gridcode 1 (Class 1) are generally not suitable, although a few locations with adequate wind resource for wind turbine applications may exist in some Class 1 areas.
• Areas designated as Gridcode 2 (Class 2) are marginal for utility-scale applications but may be suitable for rural applications.
• Areas designated as Gridcode 3 (Class 3) or greater are suitable for most utility-scale wind turbine applications.

The prevalence of high wind speeds indicates that you have the wind power needed to satisfy the third requirement.

Bookmarks allow you to zoom quickly to various parts of the state where there are existing turbines. The Wind Turbines in Colorado layer shows the location of several large installations of turbines within the state boundaries. To build the infrastructure that these wind farms need to run and to have a staff to keep them running, it is easiest to clump them together. Most of these clumps are in the eastern part of the state, where you saw greater wind speeds.

The map zooms to Limon, a small community in northeastern Colorado that has a sizable number of wind turbines located nearby.

The turbines near Limon tend to be between 0.18 and 0.25 miles apart. Newer high-efficiency wind turbines have a very long rotor diameter, sometimes more than 100 meters (328 feet), and require extra logistical and spatial considerations. Next, you'll examine the rotor diameter of installed turbines represented in the Wind Turbines in Colorado layer.

Several existing turbines have rotor diameters of 100 feet. This, along with the many clusters you observed in the state, signifies that there are several areas that may satisfy the fourth criterion.

In the layer, transmission lines have been symbolized by voltage capacity. Lines with a capacity of 138 to 500 kV have the thickest line symbol, while lines with a capacity of 10 kV or less have the thinnest line symbol.

These high-voltage lines are present throughout the state, but they are especially concentrated toward the eastern half. This suggests that the criterion for sites to be within 10 miles of an existing power line could be met.

Now that you have explored the data layers necessary to identify potential sites for high-efficiency wind turbines, you are ready to perform the analysis to identify specific sites. The Public Energy Commission has defined several site-specific criteria that you should consider.

An ideal site should meet these conditions:

• Located in the state of Colorado
• In counties where the population as of 2010 is at least 20,000, to ensure an adequate demand
• In areas where the wind power class is at least 4 (Annual wind speeds in these areas at 10 meters off the ground are generally at least 5.6 meters per second [12.5 mph], and at 50 meters off the ground are generally 7.0 meters per second [15.7 mph].)
• Within 10 miles of existing power lines that have a capacity of at least 400 kilovolts (kV)
• Within 5 miles of existing wind farms containing turbines where the rotor diameters span at least 100 feet

The Perform Analysis pane appears.

The resulting layer shows the combination of the Counties and Wind Power Class features.

This combined layer allows you to select all locations with wind power classes greater than and equal to 4 and counties with populations greater than 20,000.

Next, you'll buffer the transmission lines layer. Since the transmission line data shows all lines in the state, you'll need to apply a filter. The first of your analysis criteria is to filter out transmission lines with a voltage of at least 400 kilovolts.

The Filter window appears.

Filter expressions use the general form of <Field_name> <Operator> <Value, Field or Unique>.

The filtered view is displayed on the map.

The layer has now been filtered to only display transmission lines that have a voltage of 400. Now, to verify that locations you choose are within 10 miles from existing power lines you'll generate a 10-mile buffer zone around these transmission lines using the Create Buffers tool.

The tool may take a moment to complete. When the operation finishes, the Transmission Lines 10 Mi Zone layer is added to the map.

The Transmission Lines 10 Mi Zone layer represents both the location of high-capacity transmission lines and a 10-mile zone around them. The location of your new wind farm should be within one of these 10-mile zones close to a high-capacity transmission line.

Your layer now displays only existing wind turbines with a rotor diameter of 100 meters or greater. There are four turbine clusters.

Next, you'll generate 5-mile zones around the filtered turbines.

• For Choose layer containing features to buffer, ensure the layer is set to Wind Turbines in Colorado.
• For Enter buffer size, change the buffer size to 5 miles.
• Expand Options and set Buffer type to Dissolve.
• For Result layer name, type Turbine 5 Mile Zone and add your initials.

The Turbine 5 Mile Zone layer is added to your map.

There are four turbine clusters, three of which appear to meet your criteria so far. To finalize your selection, look at the populations of the counties in which these clusters are located. Now you'll combine the buffered transmission lines and the buffered wind turbines into a separate layer using the Union tool.

• For Choose input layer, confirm the Turbine 5 Mile Zone layer is selected.
• For Choose overlay layer, choose Transmission Lines 10 Mi Zone.
• For Choose overlay method, choose Union.
• For Result layer name, type Union of Turbine 5 Mile Zone and Transmission Lines 10 Mi Zone and add your initials.

The resultant layer now contains all the buffered features for the transmission lines as well as the buffered wind turbine locations.

Using this layer, you'll be able to select all locations within 10 miles of a 400-volt transmission line as well as within 5 miles of wind turbines with a rotor diameter of 100 feet.

• Verify that Choose input layer is set to Union of Turbine 5 Mile Zone and Transmission Lines 10 Mi Zone.
• For Choose overlay layer, choose Union of Wind Power Class and Counties.
• For Choose overlay method, choose Union.
• For Result layer name, type TargetSites and add your initials.

The resulting TargetSites layer displays the combination of all features and their attributes that you would need to include in your analysis to determine suitable locations for your client.

Now you'll use the Find Existing Locations tool, which allows you to combine the attribute and spatial selections in a single statement by adding a set of expressions, one at a time. These selection criteria can be based on attribute queries (for example, counties with a population greater than 20,000) and spatial queries (locations 10 miles from transmission lines).

• Verify that the layer for Choose layer containing features you want to find using attribute and spatial queries is set to TargetSites.
• In Build a query to find features, click Add Expression.

The Add Expression window appears.

You can add multiple expressions to the query box as needed. When they are all entered in the Find Existing Locations tool pane, clicking the Run Analysis button will execute the list of expressions. Features in your input layer are then filtered through each expression, and those features that satisfy the expressions are written to a results layer.

As you did earlier, you'll build expressions, but these will query the TargetSites layer. You'll start with two spatial expressions to locate suitable sites within the 5-mile zone of turbines and the 10-mile zones of transmission lines. A spatial expression establishes a relationship between two layers. In this case, you're searching for all target sites in the first layer that are completely within the second layer, the 5-mile buffer zone of 100-foot rotor diameter wind turbines.

The analysis layer (TargetSites) represents the source layer you are selecting from.

Choosing completely within specifies that if a feature in the first layer is completely within a feature in the second layer, the location is included in the output. Once you establish a spatial relationship to other layers, they will be listed in the drop-down menu.

The first expression has been added to the expressions query box in the Find Existing Locations pane.

Now you'll build the expression to locate target sites completely within the Transmission Lines 10 Mi Zone layer.

The second spatial expression is added to the expression query box and is combined with the first expression by the connector and. In queries, the operator and requires that each expression or condition must be true for a location to be selected. The other operator, or, requires that one or the other condition, but not both conditions, can be true for a location to be selected.

Now you'll add a series of attribute selection expressions to further refine the locations that will be selected within the 5- and 10-mile zones.

The third expression is added to the expression query box and is combined with the first and second expressions by the and connector.

There will be four expressions in the query box list. The final expression you need to add will filter only the highest wind speeds.

The final expression is added to the query box.

The two final sites are in the northeast corner of the state.

There is also a smaller third site near Pueblo, but for the purposes of this tutorial, you'll focus on the two larger sites. One is in the northeast corner of the state and the other is southeast of Denver and northeast of Colorado Springs, near a town called Limon.

These sites both meet the criteria you need:

• Located in the state of Colorado
• In counties where the population as of 2010 is at least 20,000
• In areas where the wind power class is at least 4 (Annual wind speeds in these areas at 10 meters off the ground are generally at least 5.6 meters per second [12.5 mph], and at 50 meters off the ground are generally 7.0 meters per second [15.7 mph].)
• Within 10 miles of existing power lines that have a capacity of at least 400 kilovolts (kV)
• Within 5 miles of existing wind farms containing turbines where the rotor diameters span at least 100 feet

The Map Notes template allows you to create basic shapes and symbols.

When you have placed the pushpin, a pop-up window appears with additional options to input location information.

A symbol style window appears.

The symbol changes to a windmill.

The point feature is now symbolized as a windmill.

Now you will add another point for the Fleming site.

The map zooms to northeast Colorado and the Fleming site is visible.

In the symbol style window that appears, the custom shape you uploaded for the Limon site is available.

The symbol for the Fleming site is changed to the windmill.

You now have point locations for each site and are ready to perform a drive-time analysis.

The Plan Routes tool determines how to efficiently route a vehicle to the stops that you specify.

The map zooms in to the State Capitol building in Denver.

• For Maximum number of vehicles to route, type 1.
• For Maximum number of stops per vehicle, type 2.
• For Time spent at each stop, type 120 minutes.
• Uncheck the box next to Limit the total route time per vehicle.

You anticipate that it will take you 2 hours, or 120 minutes, to inspect each site, but depending on the time of day you're using, the traffic might cause the total route time to vary.

Several layers showing driving routes to the wind farms are added to your map. Next, you will change the basemap to more clearly show driving routes.

The basemap updates on your map.

The assigned stops for the route are numbered 1 to 4. The first and fourth stops are both located at the State Capitol. Since you set the Route end at stops option to Return to start, your route will visit all stops in sequence and return to the point of origin.

This table contains four records, one for the start and end points, and one for each site under consideration. Your distances and times may vary slightly depending on where you placed your map notes.

This table contains one record for your entire route. Note that it states that two stops are included, and that the total time is approximately 607 minutes. This includes travel time and service time to inspect the sites. Of the 607 minutes, your total travel time is 367 minutes and service time is 240 minutes, making up the 120 minutes you would use to inspect each site.

If you subtracted your end time from your start time, you would notice that completing the route as planned would take around 10 hours. Therefore, even if you take a break from driving for 30 minutes, you would still be able to complete the travel and the site inspection in under one day.

If you can only choose one of the sites due to budget constraints, and you are told to choose the larger of the two, the southern site, near Limon, much larger than the site in Fleming.

If you are instructed to choose the site that is closer to Denver and its major population, you could use the route results or the measure tool to get a straight-line distance.

Next, you will determine the straight-line distance from both the Limon site and the Fleming site to Denver with the Measure tool.

The Limon site is closer, approximately 70 miles (113 kilometers) straight-line distance, compared to approximately 133 miles (214 kilometers) for the Fleming site. In other respects, such as mean wind speed and population per square miles, the two sites are quite similar.

It is most likely that you would recommend the Limon site, but there are additional considerations. GIS will be critically important in the logistics of transporting large wind turbines to the site. This may be the most difficult part of the operation because wind turbine blades often have to be transported by rail, and then by a convoy of two or three trucks, to accommodate the length. In this respect, the Fleming site may be better, because it is located near a major U.S. Highway (U.S. 6), whereas the Limon site, while near Interstate 70, has no exits directly to the site, and is located largely off unimproved county roads.

Thus, there are pros and cons about both sites. But spatial analysis with GIS helped to narrow the decision to these two sites.

Are other considerations important? Certainly, and if you were truly choosing a site for a client, you would consider additional factors and conduct additional analysis to qualify your recommended site to the client.

• Optimal Wind Farm Sites
• Routes to Optimal Wind Farm Sites - Assigned Stops
• Routes to Optimal Wind Farm Sites
• SuitableSites
• Platts Transmission Lines
• Wind Turbines in Colorado
• State Line

The Create a New Web App window appears. It includes a gallery of configurable apps, organized into categories based on purpose and functionality. You can filter the app templates by category or search for one. You want your map to be the primary focus of your app, but you also want to show the legend and a map description in a side panel.

The gallery of ArcGIS Instant Apps templates is filtered. Sidebar is a good choice.

The web app is created. The ArcGIS Instant Apps configuration window appears for the Sidebar template, which includes several app settings and an interactive preview of your app. By default, this template includes a side panel that displays a legend, map details, and pop-ups.

The app also has a header with sharing options, map navigation tools, and a search tool to find locations on the map.

You want to provide a description in the Details panel that helps app users understand the data in the app.

The Sidebar settings provide options to include the side panels with information about the map. Details is turned on, and there is an option to customize it.

Wind turbine site selection study in Colorado based on the following criteria:

• Located within the state of Colorado.
• In a county where the local or target population is at least 20,000, to ensure an adequate demand.
• Within 10 miles of existing power lines that have a capacity of at least 400 kilovolts (kV), to take advantage of nearby existing energy infrastructure.
• Within 5 miles of existing wind farms containing turbines where the rotor diameters span at least 100 meters.
• Wind power class is at least 4. (Annual wind speeds at 10 meters off the ground are 5.6 meters per second, or 12.5 mph, and at 50 meters off the ground are 7.0 meters per second, or 15.7 mph.)

The app preview updates with your new content in the Details panel. The app automatically saves as noted next to the Draft badge that appears in the configuration panel.

The color scheme of your app changes from the default dark theme to a light theme, which works better with the symbols in your legend.

A success message appears when publishing is completed and the Draft badge changes to a Published badge with the date and time you published. The Share window appears, which includes a link that you can send to your client to access your app.

You could share this app with the company who hired you to show them the potential sites and the driving routes from Denver.

The app's item page appears, where you can add more details such as a description of the app, terms of use, and any necessary data attribution.