Explore Defense Toolbox

First, you will create a new project, add a custom Defense Toolbox tab, change display coordinates, and add a layer package with military symbols representing the Meuse-Argonne battlefield on October 7, 1918. When complete, you can begin exploring the battle of Meuse-Argonne.

Create a new project

ArcGIS Pro contains a list of blank templates for creating 2D maps, 3D scenes, and other types of projects. A map project template includes maps, a project database, toolboxes, and more.

  1. Start ArcGIS Pro. If prompted, sign in using your licensed ArcGIS organizational account.
    Note:

    If you don't have access to ArcGIS Pro or an ArcGIS organizational account, see options for software access.

    When you open ArcGIS Pro, you're given the option to create a new project or open an existing one. If you've created a project before, you'll see a list of recent projects.

  2. Under New Project, click Map.

    New map blank template

  3. In the Create a New Project window, set the following parameters:

    • For Name, type Meuse-Argonne.
    • For Location, browse to a location on your computer where you want to save the project.

    Create a New Project window

  4. Click OK.

    A new project is created. Next we will create a tab to add the Defense tools.

Create a tab for Defense Toolbox

The Defense Toolbox is a collection of mission-focused enhancements that simplifies defense and intelligence workflows in ArcGIS. The collection includes the following tools:

  • Coordinate Conversion - Shows simultaneous coordinates (Decimal Degrees, Military Grid Reference System, and so on) in the same window.
  • Distance and Direction - Creates geodesic lines, circles, and ellipses. You can select a feature on the map and calculate range rings.
  • Visibility - Calculates fields of view from a given point and determines line of sight from observer to target.
  • Military Symbology Editor - Creates military symbols and adds them to the map.

In this step, you will customize the ribbon on ArcGIS Pro to include a tab for Defense Toolbox.

  1. On the ribbon, click the Project tab.

    Project Tab

  2. In the list pane, click Options.

    Options button

    The Options window appears.

  3. In the Options window, under Application, click the Customize the Ribbon tab.
  4. In the Customize the Ribbon section, under the scrolling window for tabs, click the New Tab drop-down menu and click New Tab.

    Adding a New Tab under scrolling window

    A new tab and group are added under the other core tabs, above the first contextual tab set.

    A new tab and a group is added
  5. With the New Tab (Custom) selected, click Rename.

    Rename button

    The Rename window appears.

  6. In the Rename window, for Display name, type Defense Toolbox, and click OK.

    Rename the tab to Defense Toolbox

  7. Similarly, under Defense Toolbox (Custom), click New Group (Custom) to select it. Rename the new group to Defense Tools.
  8. Select the Defense Tools (Custom) group to add commands.
  9. In the Choose commands from drop-down menu at the top, select the All Commands option and search for Coordinate Conversion.
    Search the Coordinate Conversion tool
  10. From the search results, select Coordinate Conversion and click Add.

    Add Coordinate Conversion command in Defense Tools group

    The Coordinate Conversion tool is now added to the Defence Tools (Custom) group.

  11. Similarly, add Distance and Direction, Visibility Analysis and Military Symbology Editor commands to the group.

    Defense Tools List

  12. When finished, click OK and click the Back button.

    Back button

    The Defense Toolbox tab appears on the ribbon, to the right of other core tabs by default. You will use some of these tools later in the tutorial.

    Defense Toolbox tab

Change the coordinate system

Projecting the round 3D earth onto a 2D map creates distortions in shape, area, distance, or direction. Different projections preserve some properties while distorting others, and it is the job of the spatial analyst to identify which coordinate system is most appropriate. The current coordinate system of your map is probably WGS 1984 Web Mercator Auxiliary Sphere to match the basemap layer. You will change it to a local projection, UTM Zone 31N, to preserve local distances and directions. Both properties are essential to efficiently move soldiers and equipment across the battlefield.

  1. In the Contents pane, right-click Map and choose Properties.

    Properties option

    The Map Properties: Map window appears.

  2. In the Map Properties: Map window, click the Coordinate Systems tab.

    Coordinate Systems properties

  3. In the search box, type WGS 1984 UTM Zone 31N and press Enter.
  4. Under XY Coordinate Systems Available, expand Projected Coordinate System. Continue expanding folders until you see WGS 1984 UTM Zone 31N. Click the coordinate system to select it.

    WGS 1984 UTM Zone 31N selected as the Current XY coordinate system

  5. Click the General tab.

    Currently, the map's display units are set to Decimal Degrees. This determines the formatting of the coordinate values shown at the bottom of the map view, which correspond with the pointer's location on the map. However, decimal degrees are not used by most militaries. The Military Grid Reference System (MGRS) is the standard geographical referencing system used by the North Atlantic Treaty Organization (NATO). Adopted by the United States military after World War II, MGRS consolidated and simplified a variety of conflicting reference systems used during the war. MGRS covers the entire world and can communicate precise locations down to one square meter.

  6. Change Display units to MGRS.

    Display units set to MGRS in the Layer Properties window

  7. Click OK.

    The map changes to reflect the new projection. When zoomed out you can see the distorted shape of the world, but once you are zoomed in to the battlefield, distortions will be negligible. The coordinate values displayed beneath the map view are now formatted using MGRS.

    Map displayed with the new projection and MGRS coordinates

    Note:

    If you do not see the map, in the Contents pane, right-click World Topographic Map and choose Zoom To Layer.

  8. On the Quick Access toolbar, click Save.

    Save project button

Locate the battlefield

You will locate the Meuse-Argonne battlefield and use the Coordinate Conversion tool to specify the location with an MGRS coordinate.

  1. On the ribbon, click the Map tab. In the Inquiry group, click the Locate button.

    Locate button

    The Locate pane appears.

  2. In the Locate pane, in the search box, type Chatel-Chehery, Ardennes and press Enter.

    Several points are added to the map. Chatel-Chehery is at the center of the Meuse-Argonne battlefield.

    Requested location on the map

  3. On the ribbon, click the Defense Toolbox tab. In the Defense Tools group, click the Coordinate Conversion tool.

    Coordinate Conversion button on the ribbon

    The Coordinate Conversion tool converts coordinates between several common formats, including Decimal Degrees and MGRS, when you click a point on the map or type coordinates into an input parameter. To perform the conversion, you will configure the tool to output into MGRS.

  4. In the Coordinate Conversion pane, for Output formats, click the Add button.

    Add button in the Coordinate Conversion pane

  5. In the Add New Output Coordinate window, under Category, click MGRS.

    MGRS in the Category list of the Add New Output Coordinate window

    You will configure the advanced settings of the MGRS coordinates into a more easily readable format.

  6. Expand Advanced and add a space after the X and before the Y.

    A Custom coordinate formatting in the Advanced box

  7. Click OK.

    In the Coordinate Conversion pane, MGRS is set as the output coordinate type.

  8. In the Coordinate Conversion pane, for Enter a coordinate, click the Edit Properties button.

    Edit Properties button in the Coordinate Conversion pane

  9. In the Edit Properties window, on the Display Coordinate tab, choose MGRS.

    MGRS in the Display Coordinate Category list of the Edit Properties window

  10. Click OK.

    Next, you will add some points.

  11. For Enter a coordinate, click the Map Point Tool button.

    Map Point Tool button

    You will use this tool to convert the coordinates of Chatel-Chéhéry to MGRS.

  12. On the map, click near Chatel-Chéhéry label.

    The converted MGRS coordinate value is output to the List box.

    New coordinate added to the list in the Coordinate Conversion tool

    In this way, you can collect a list of important coordinates and export them to spatial or tabular data.

  13. Close the Coordinate Conversion and Locate panes.
  14. On the ribbon, on the Map tab, in the Navigate group, click Explore.
  15. Save your project.

You created a custom tab for Defense Toolbox, changed the coordinate system to meet military standards, and explored the Coordinate Conversion tool to discover the MGRS location of the battle. Next, you will create map features to represent the German and American units that participated in the battle.


Draw military symbols

Previously, you adjusted your map's settings to meet military standards and familiarized yourself with some of the military tools. Next, you will use the Military Symbol Editor to re-create the battlefield of Meuse-Argonne on October 7, 1918, by mapping and creating symbols representing American and German infantry regiments that fought in the battle.

This module begins with an explanation of the military decision making process (MDMP) to better understand your role as a planning staff officer.

Understand the military decision making process

The United States Army has developed the MDMP as a seven-step, synchronized planning process that convert a commander's order into military action. The commander begins the process by stating the mission intent in writing, which prompts the staff officers to organize, analyze, and war-game the operation. The entire workflow for this module falls within Mission Analysis, the second step of MDMP.

Seven steps of the MDMP
Graphic derived from ADP 5-0, The Operations Process, page 8 (May 2012)

Mission Analysis is the most important step. The analysis and reports produced in this step conclude with writing an attack preparation order, known as a warning order. The warning order converts the commander's intent in Receipt of the Mission into the concrete details staff need for the third step, Course of Action Development. The timeline for completing the decision making process depends on when the mission was received and how soon it must be carried out. The American Expeditionary Force broke the Meuse-Argonne Offensive into three phases:

  • September 26 through October 3—The initial phase, which was met with stiff resistance
  • October 4 to October 28—The middle phase, discussed in this tutorial, which cleared the Argonne Forest and created breakthroughs in German lines
  • October 28 through November 11—The final phase, which captured the most ground and concluded with the Germans seeking an armistice

The U.S. Eighty-Second Infantry Division (the division depicted in this tutorial) was initially held in reserve until called upon on October 7, 1918, when it was issued attack orders at 9:30 p.m., less than eight hours before the final phase of the offensive began at 5:00 a.m. The tasks you'll accomplish in this module would have likely occurred within those eight hours.

Add military symbols to the map

To add symbols representing regiments, you will first download data that contains layers of the battlefield's geography. Then, you will add the data to your project.

  1. Download the MeuseArgonneData compressed folder and extract it to your ArcGIS Pro Meuse-Argonne project folder.
  2. If necessary, open your Meuse-Argonne project in ArcGIS Pro.
  3. On the ribbon, on the Map tab, in the Layer group, click the Add Data button.
  4. In the Add Data window, browse to your project's folder.
  5. Click Railroad.lpkx and click OK.
    Note:

    If you do not see the layer, in the Add Data window, click the Refresh button.

    Railroad.lpkx

    The Railroads layer is added in the Contents pane. These railroads represent a portion of the German rail network, and capturing them was a primary objective.

  6. Similarly, add the BattlePlan.lpkx layer.

    The BattlePlan layer displays the location of Allied and German units and their trench fortifications, attack objectives, and unit boundary markers. In the Contents pane, the layer is listed as Military Overlay 2525B Change 2, the standard name for military symbology. To avoid confusion, you will rename the layer.

  7. In the Contents pane, click Military Overlay 2525B Change 2 once to select it. Click it a second time to make the layer name editable. Rename it Battle Plan and press Enter.
  8. Expand the Battle Plan layer.

    The layer consists of several sublayers of features useful in battle planning. Specifically, the Land and Control Measures group layers are important for this tutorial.

  9. If necessary, zoom to make all features of the Battle Plan group layer visible on your map.
  10. On the Map tab, in the Navigate group, click Bookmarks and choose New Bookmark.
  11. In the Create Bookmark window, for Name, type Meuse-Argonne battlefield. Click OK.

    Next, you will familiarize yourself with some of the sublayers in the Battle Plan layer.

  12. In the Contents pane, under the Battle Plan layer, turn the Land sublayer off and on.

    Land group layer within the Battle Plan group layer

    Notice which features the layer corresponds to in the Map pane. In this sublayer, blue rectangles represent the Allied units and red diamonds represent German units.

  13. Under Battle Plan, turn the Control Measures group layer off and on.

    In this sublayer, red lines represent German trenches and black lines represent Allied trenches. The two square features labeled OBJ CORNAY and OBJ HILL 233 are the Allied objectives.

  14. In the Contents pane, collapse the Battle Plan layer.

Add United States infantry symbols

The United States military uses standardized map symbols for operations and planning. In the Military Symbol Editor, you can create symbols for military units and other important features that are colored to represent friendly, enemy, or neutral entities. The editor includes the older military standard symbology MIL-STD2525D and the newer MIL-STD2525B.

  1. On the ribbon, click the Defense Toolbox tab. In the Defense Tools group, click Military Symbology Editor.

    The Military Symbol Editor pane appears which by default is disabled.

  2. In the Military Symbol Editor pane, click Enable.

    The Application Settings window appears. You will add a symbol to represent friendly infantry.

  3. In the Application Settings window, set the following parameters:
    • For Military Symbology Standard, choose MIL-STD-2525B w/ Change 2.
    • For Layers To Add, check Select All.

    Change Military Symbology Standard in Application Settings to MIL-STD-2525B w/ Change 2

  4. Click OK to add the schema to the database.
  5. In the Military Symbol Editor pane, on the Search tab, type infantry and press Enter.

    Different kinds of combat infantry unit symbols are returned. You may have to expand the Military Symbol Editor pane to read the full names.

  6. In the list of results, choose the second Movement and Maneuver: Infantry option.

    The second Movement and Maneuver : Infantry item has a wide X symbol.

  7. Check the Contents pane on the left.

    A second Military Overlay layer has been added above the Battle Plan layer. This layer will include the new units you'll add to your map.

  8. Rename the Military Overlay layer to Attacking units.
  9. In the Military Symbology Editor pane, click the Symbol tab.

    You will edit the symbol's attributes to build the appropriate infantry marker. So far, Identity/Affiliation is set to Friendly. Blue is the color for friendly forces and red is the color for hostile units.

    Next, you will add the unit's echelon, a military term that refers to a unit's size.

  10. For Echelon/Mobility, choose Regiment.

    Regiment markings

    The symbol is updated with three vertical bars to reflect the echelon setting.

  11. In the Military Symbology Editor pane, click the Label tab.
  12. On the Label tab, change the following parameters:

    • Unique Designation327
    • Higher Formation82
    • Country CodeUnited States

    The Label tab

    You have created a symbol for the U.S. 327th Infantry Regiment, of the U.S. Eighty-Second Infantry Division. Next, you will add your symbol to the map near Exermont Ardennes, a village close to where the regiment was positioned.

  13. On the ribbon, in the Map tab, in the Inquiry group, click Locate.
  14. In the Locate pane, search for and navigate to Exermont Ardennes.
  15. Navigate back to the Military Symbology Editor pane.
  16. In the Military Symbology Editor pane, click Add to Map.

    Add to map

  17. Click the map near Exermont to add your military symbol.

    Add the symbol to the map.

    Note:

    Depending on your version of ArcGIS Pro, your basemap may have different symbology.

    The symbol is plotted between two black lines that serve as boundary markers for other regiments. You will bookmark this location to navigate to it later.

  18. On the ribbon, on the Map tab, in the Navigate group, click Bookmarks and choose New Bookmark. Create a bookmark named U.S. 327 Infantry Regiment.

    Note:

    Battlefields can become confusing when many units are concentrated in one location, as was the case with the Meuse-Argonne battlefield in 1918. When listing order of battle (references that include unit size, type, personnel, and equipment), it's best to add country, unit designation, type of unit, and echelon rather than a single number. That way, you can quickly distinguish the unit you want from similar-sounding units.

    Now you will create the U.S. 328th Infantry Regiment symbol near Apremont. The last symbol was added by searching the geographic location, but you can also add symbols using the coordinate location. For the next symbol, all the information is the same, so you will only change the label, and then add it using the MGRS coordinate.

  19. In the Military Symbology Editor pane, on the Label tab, for Unique Designation, type 328.
  20. On the Enter Coordinates tab, for Coordinates, type 31UFQ4532760127.
  21. Click Add Coordinate(s) to Map.

    Add Coordinate(s) to Map button

    A new regiment symbol is added to the map north of the railway line near Apremont.

    New blue symbol on the map

  22. Zoom to the new symbol and create a new bookmark named U.S. 328 Infantry Regiment.

    Next, you will add the last American unit, U.S. 321st Artillery Regiment, part of the U.S. 164th Artillery Brigade. Most of the information is the same, but you need to change Identity/Affiliation to an artillery symbol and add additional information about the range of its guns.

  23. In the Military Symbology Editor pane, on the Search tab, search for artillery and select Fires: Field Artillery.
  24. On the Symbol tab, set the following parameters:
    • For Identity/Affiliation, choose Friendly.
    • For Echelon/Mobility, choose Regiment.
  25. On the Label tab, set the following parameters:
    • For Unique Designation, type 321.
    • For Additional Information, type (75mm).
    • For Higher Formation, type 164.
    • For Country Code, choose United States.

    The additional information indicates the caliber of the guns the regiment fires.

  26. On the Enter Coordinates tab, type 31UFQ4690157748 and click Add Coordinate(s) to Map.

    The artillery regiment appears near the southeast area of the battlefield.

  27. Click Mark/Pan to Coordinate to locate the symbol.

    New artillery symbol added to map

  28. Create a bookmark named U.S. 321 Artillery Regiment.
  29. Save the project.

Add German infantry symbols

On October 7, 1918, the U.S. Eighty-Second Infantry Division faced the Imperial German Army's 2nd Landwehr Division. You will add three hostile German infantry regiments represented by red diamonds, starting with the regiment near Fléville.

  1. In the Military Symbology Editor pane, on the Search tab, search for infantry.
  2. From the results, select the fourth Movement and Maneuver: Infantry item.
  3. On the Symbol tab, confirm that Identity/Affiliation is set to Hostile. Set Echelon/Mobility to Regiment.
  4. On the Label tab, configure the following parameters:
    • For Unique Designation, type 125.
    • For Higher Formation, type 2.
    • For Country Code, choose Germany.
  5. In the Locate pane, search for and navigate to Fléville.
  6. In the Military Symbology Editor pane, click Add to Map. Click the map near Fléville and west of the railway line to add the symbol.

    Location of German infantry

  7. Bookmark this location as German 125 Landwehr Regiment.

    The next unit is the 120th Landwehr Regiment, which is also part of the 2nd Landwehr Division.

  8. In the Military Symbology Editor pane, on the Label tab, change Unique Designation to 120.
  9. In the Locate pane, search for and navigate to Ferme du Mesnil, Chatel-Chehery.
  10. Add the regiment marker near the town.

    Second regiment symbol added to the map

  11. Close the Locate pane.
  12. Bookmark this location as German 120 Landwehr Regiment.

    The final regiment, 122 Landwehr, has no geographic name, but can be located using MGRS coordinates.

  13. Zoom out until you see the red line boundary markers.
  14. In the Military Symbology Editor pane, change the symbol's Unique Designation to 122.
  15. On the Enter Coordinates tab, for Coordinates, copy and paste 31UFQ4265458429.
  16. Click Add Coordinate(s) to Map.

    A new red diamond symbol is added to the south of the symbol at Ferme du Mensil.

  17. Bookmark this location as German 122 Landwehr Regiment.

    The last unit you added is selected by default. You'll clear your selected features next.

  18. On the ribbon, click the Map tab. In the Selection group, click Clear.
  19. Navigate to the Meuse-Argonne battlefield bookmark.

    Meuse-Argonne battlefield

  20. Save your project.

Manage overlays and map data

You have added six military symbols representing German and American infantry regiments to the battlefield. These military symbols are point features stored in an associated feature class in a geodatabase. As a result, each of the symbols has related location and attribute properties that can be updated and edited as needed. Next, you will manage your data and familiarize yourself with its attribute information.

  1. In the Catalog pane, expand Databases.
    Note:

    If the Catalog pane is not visible, in Command Search, type Catalog and choose Catalog pane. The Catalog pane appears.

  2. Expand Meuse-Argonne.gdb.

    Note:

    If the database is empty, right-click Meuse-Argonne.gdb and choose Refresh.

    Meuse-Argonne geodatabase expanded in the Catalog pane

    The Meuse-Argonne geodatabase was created as part of your project. The militaryOverlay2525b2 schema was generated when you set the military symbology standard.

  3. Expand the militaryOverlay2525bc2 feature dataset.

    The collection of feature classes contains the various point, line, and polygon features you create and maintain using the Military Symbol Editor. These include Installations, LandEquipment, Activities, and ControlMeasures. The Units feature class stores the point features representing your infantry regiments.

    Next, you will explore the layers in the Contents pane derived from the feature classes in the geodatabase.

  4. If necessary, in the Contents pane, expand the Attacking units group layer.

    This group layer contains several subgroup layers that organize important features for units, equipment, installations, and operations, as well as for stability operations, emergency management, and weather features. The sublayers and features of importance for the Meuse-Argonne Offensive are all located in the Land and Control Measures group layers.

  5. If necessary, expand the Land subgroup.
  6. Right-click Units and choose Attribute Table.

    Attribute Table in the layer's context menu

    The Units table contains six records corresponding to the number of regiments you added using the Military Symbology Editor. The Affiliation field denotes units as either Friendly or Hostile. These attribute values correspond directly to the symbol properties you set while creating the new symbols for regiments in the Meuse-Argonne Offensive.

    Next, you will select the three German infantry regiments belonging to the 2nd Landwehr Division and update their Higher Formation attributes.

  7. On the Map tab, in the Selection group, click the Select button.

    Select button on the ribbon

  8. On the map, select one of the German regiments you added and press Shift while selecting the other two regiments.

    Three selected German Landwehr regiments

    Once selected, the regiments on the map and their associated records in the attribute table are highlighted.

  9. If necessary, in the attribute table, scroll right until you see the Higher Formation field.

    The current value for Higher Formation is 2. In this case, you want to add the name of the higher formation of the three German infantry regiments opposing the U.S. Eighty-Second Infantry Division. Unlike Allied units, the name of the German units reflected unit characteristics and capabilities. In World War I, German Landwehr units were composed of older soldiers who had already completed service with the active and reserve armies. Landwehr units were designed for rear-echelon defense, but as personnel shortages increased as the war dragged on, Landwehr units were assigned to front-line combat. Allied intelligence classified Landwehr units as inferior.

  10. Double-click each selected record and change the value to 2 Landwehr.

    Updated name of Landwehr units in the attribute table

  11. On the Attribute Table toolbar, click Clear to clear the selection.

    Clear selection

  12. On the ribbon, click the Edit tab. In the Manage Edits group, click Save. In the Save Edits window, click Yes.
  13. Close the attribute table.
  14. On the Map tab, in the Navigate group, click Explore.
  15. On the map, zoom to the German regiments you edited.

    The labels have been updated to indicate the new attribute values.

    Landwehr regiment symbols on the map with their new labels

Draw graphic control measures

On the morning of October 7, 1918, two of the U.S. Eighty-Second Infantry Division's regiments began their assault. You will illustrate their attacks by creating axis of advance arrows, graphic control measures used to organize and coordinate battlefield activity. An axis of advance shows the general area where the bulk of an advancing unit's combat power will travel toward an objective. Your arrows will represent the U.S. 327th Infantry Regiment moving toward OBJ CORNAY and the U.S. 328th Infantry Regiment advancing toward OBJ HILL 223.

First, you will create the axis of advance for the U.S. 327th Infantry Regiment.

  1. Navigate to the U.S. 327 Infantry Regiment bookmark. If necessary, zoom out so you can see both the regiment and the rectangle labeled as OBJ CORNAY.
  2. In the Military Symbology Editor pane, on the Search tab, type advance in the search box and press Enter.
  3. In the Result Count list, choose Maneuver Areas: Axis of Advance: Main Attack.

    The axis of advance arrow initially appears in yellow, but the color will change when you build your symbol.

    Axis of Advance: Main Attack symbol

  4. On the Symbol tab, for Identity/Affiliation, choose Friendly. For Echelon/Mobility, choose Regiment.
  5. On the Label tab, for Unique Designation, type CHARLIE. For Country Code, choose United States.
  6. Click Add to Map.

    Your pointer turns into crosshairs.

  7. Click the center of the U.S. 327th Infantry Regiment and double-click the center of the OBJ CORNAY box.

    An arrow, representing the axis of advance, appears on the map.

    Advance Charlie on the map.

  8. Navigate to the U.S. 328 Infantry Regiment bookmark and zoom out until you can also see the rectangle labeled OBJ HILL 223.
  9. On the Label tab, for Unique Designation, replace the text with CHAPLIN.
  10. Click Add to Map and create an axis of advance from the U.S. 328th Infantry Regiment to OBJ HILL 223.

    Advance Chaplin on the map.

  11. Close the Military Symbology Editor pane.
  12. Save the project.

You downloaded a layer package containing a military overlay showing the battle frontline, trenches, and other strategic installations. You then used the Military Symbol Editor to create six military symbols and drew attack advances for the U.S. Eighty-Second Infantry Division's attack in the Meuse-Argonne Offensive. Next, you will use the Military Analyst extension geospatial tools to further analyze the battle.


Determine distance and direction

Previously, you created the military symbols needed to prepare the battlefield. Next, you will use the Distance and Direction tool to illustrate how tanks and artillery could support the U.S. 328th Infantry Regiment during its attack toward OBJ HILL 223. First, you will create range rings revealing whether the U.S. 344th Tank Battalion could keep up with the attacking infantry. Then, you will use rings to determine whether the 75-mm guns of the U.S. 321st Artillery Regiment could bombard the objective.

Create circles using speed and time

Tanks were first used by the British Army during the Battle for the Somme in 1916 in an effort to break the trench warfare stalemate. The tanks of the World War I era, compared with today's, were slow and clumsy. During the Meuse-Argonne Offensive, the Americans were equipped with French Renault FT-17 tanks, which had a maximum speed of 7 kilometers per hour (4.3 mph) in optimal conditions.

On your map, the U.S. 344th Tank Battalion is located near the town of Apremont. You will determine how long it would take for the battalion's FT-17 tanks to reach Hill 223. You want to find out whether the tanks could arrive in time to help the infantry overcome barbed wire, trenches, and machine guns. To determine travel time, you will use the Distance and Direction tool to plot lines, ellipses, and range rings used to compute the distance between two geographic locations. The tool's accuracy is enhanced by snapping, which ensures features are coincident with each other.

  1. If necessary, open your Meuse-Argonne project.
  2. If necessary, below the map, next to the scale, click Snapping to turn it on.

    Enable Snapping for features

    The button turns blue to indicate that it is active. You will also set a parameter to specifically snap point features, such as your military symbols.

  3. Point to the Snapping button. In the Snapping window, confirm that Point snaps to the nearest point or LAS point feature is turned on.

    Snapping points

  4. On the map, zoom to the U.S. 344th Tank Battalion (the blue rectangle with an oval inside).

    The Tank Battalion symbol is a blue rectangle with an oval inside

  5. On the ribbon, click the Defense Toolbox tab. Click the Distance and Direction tool.

    Distance and Direction button on the ribbon

  6. In the Distance and Direction pane, click the Circle tab.
  7. Click the Edit Properties button. In the Edit Properties window, choose MGRS. Click OK.
  8. Click the Map Point Tool button.

    Map Point tool button in the Distance and Direction pane

  9. Click the U.S. 344th Tank Battalion.

    A snapping indicator ensures your click coincides with the exact location of the tank unit.

    Snapping to the tank unit on the map

    The military uses kilometers instead of miles for distance measurements, so you will change the Radius/Diameter parameter to reflect military usage.

  10. Under Radius/Diameter, choose Kilometers.

    The Distance Calculator enables you to plot rings based on how fast an object can travel. Specifically, you want to know whether the FT-17 tanks can keep up with the infantry and reach Hill 223 within two hours.

  11. Expand Distance Calculator.
  12. For Time, type 2 and choose Hours.

    FT-17 tanks can travel up to 7 kilometers per hour (kph). However, because of rain and mud, as well as battlefield obstacles such as artillery craters and barbed wire, you estimate the tanks could advance at 2 kph.

  13. For Rate, type 2 and choose Kilometers/Hour.

    Distance and Direction pane

    The map adjusts to show a circle. This circle indicates that the U.S. 344th Tank Battalion is capable of reaching the base of Hill 223 along with the infantry. Your command can increase the range of the tanks by moving the U.S. 344th Tank Regiment as close as possible to the trenches when the attack commences.

    Red circle around the tank battalion on the map

  14. On the ribbon, click the Map tab. In the Navigate group, click Explore.
  15. In the Distance and Direction pane, delete the text from the Center Point box.
  16. Create a bookmark named October 7, 1918.

Create range rings interactively

You will use the Distance and Direction tool again, but this time you will use it to map the range of the U.S. 321st Artillery Regiment from its current position near Mounblainville. The unit's 75-mm guns are needed to support the attack on Hill 223.

You want to know whether the guns' effective range for shrapnel artillery rounds (6.5 kilometers) and high-explosive rounds (7.4 kilometers) can reach both the OBJ HILL 223 and the railroad tracks, the objective following the attack on Hill 223. Shrapnel rounds are designed to neutralize enemy personnel, while high-explosive rounds are designed to destroy obstacles and fortifications, such as barbed wire and machine gun nests.

  1. Navigate to the U.S. 321 Artillery Regiment bookmark.
  2. If necessary, zoom out until you can also see OBJ HILL 223.
  3. In the Distance and Direction window, click the Rings tab.
  4. If necessary, set Ring Type to Interactive.
  5. Click the Map Point Tool button and click the U.S. 321st Artillery Regiment.

    Snapping to the artillery regiment on the map

  6. Change Distance Unit to Kilometers.
  7. On the map, point to the center of OBJ HILL 223.

    As you move the pointer, a gray diameter ring moves on the map and the distance is reflected in the Radius box in the Distance and Direction pane.

  8. Move your pointer so the circle completely covers the OBJ HILL 223 objective box. Take note of the Radius value and click the map.

    A red circle around the artillery regiment stretches to the outside of Hill 223.

    The circle changes color. The radius is approximately 7.5 kilometers, which means the 75-mm guns are just outside of the maximum range for both shrapnel (6.5 kilometers) and high-explosive rounds (7.4 kilometers).

  9. On the Map tab, click the Explore button.
  10. If necessary, zoom out so you can see the entire red circle.

    The unit, from its current location, needs to move closer to the trenches so its guns can support the infantry attack on Hill 223.

  11. At the bottom of the Rings tab, click the Delete Rings button to remove the graphics.
  12. Navigate to the October 7, 1918 bookmark.

Reposition a unit

Next, you will reposition the U.S. 321st Artillery Regiment to better support the U.S. 328th Infantry Regiment.

  1. On the ribbon, click the Edit tab. In the Tools group, click the Move tool.

    Move button on the ribbon

  2. Click the U.S. 321st Artillery Regiment.

    Artillery unit selected on the map

    The unit is highlighted and a yellow dot appears on the point feature.

    Note:

    If the red distance circle is still on your map, delete it before selecting the U.S. 321st Artillery Regiment. Delete the circle by selecting it and, on the Edit tab, choosing Delete from the Features group.

  3. Drag the unit to the high ground northeast of the U.S. 328th Infantry Regiment.

    Move the artillery symbol.

  4. On the Edit tab, in the Manage Edits group, click Save.
  5. In the Selection group, click the Clear button.

    Clear selection button on the ribbon

  6. Optionally, use the Direction and Distance tool to verify the relocated U.S. 321st Artillery Regiment is within range of OBJ HILL 223.
  7. Save your edits and save the project.

You used the Distance and Direction tool to estimate the distances tanks could travel and to see whether an artillery unit was within range of its targets. Although the guns of the U.S. 321st Artillery Regiment are within range of Hill 223, that unit still needs soldiers who can watch the target during the attack and report to the gunners as the infantry advances toward its objective. By staying in communication, these specialized soldiers, known as forward observers, can adjust fire so the artillery gunners can hit the intended target with the fewest rounds possible. To do their job, forward observers need to position themselves on high ground with the fewest obstructions possible between the objectives and themselves.

Next, you will use the Visibility tool to ensure these forward observers have an unobstructed view of Hill 223, the attack objective.


Calculate viewshed

Previously, you determined the distance Allied units needed to be within to provide support to the infantry. Next, you will calculate a viewshed to determine what the army's forward observers could see leading up to the battle. A viewshed calculates the visibility of an area from one or more observer locations, and the results show what areas are visible (or not) to one or more observers. First, you'll define the area where you want to locate your forward observer. Then, you will create views of different lines of sight with the Linear Line Of Sight (LLOS) and Radial Line Of Sight (RLOS) tools. LLOS illustrates whether an observer has an obstructed or unobstructed view of a specific spot, such as a bridge or checkpoint. RLOS illustrates everything an observer can and cannot see.

The elevation data used in this map is courtesy of the National Aeronautics and Space Administration (NASA). Elevation data can differ significantly depending on its source, so your results may differ when you use a different elevation set.

Add elevation data

You need to find the highest location within the area of operations for the U.S. Eighty-Second Infantry Division to locate a forward observer team. First, you will add the elevation layer.

  1. If necessary, open your Meuse-Argonne project.
  2. On the ribbon, click the Map tab. In the Layer group, click Add Data.
  3. Browse to your Meuse-Argonne folder, click Elevation.tif, and click OK. (You may need to refresh the window to see the elevation data.)

    Elevation.lpkx

    The elevation layer is added to your map above the World Topographic Map basemap.

    Terrain can dictate strategy, so realizing the impacts of elevation on the battlefield will improve your understanding about how and why enemy and friendly units move and behave. In this case, the high ground explains why the German 2nd Division Landwehr regiments occupied their positions. The high vantage points gave their machine gunners and forward observers commanding views of the American trenches below.

    The various shades of gray reflect the terrain characteristics by displaying the higher elevations as lighter and the lower elevations as darker. You will change the color scheme so the elevations are easier to visually interpret.

  4. In the Contents pane, scroll down and right-click the Elevation.tif layer symbology. In the symbol selector, click the arrow to display additional color schemes.
  5. At the bottom of the list of color schemes, check Show Names.
  6. Click the arrow to display additional color schemes again and choose Elevation #1.

    Elevation #1 color scheme

    The Elevation 1 color scheme is applied, and the elevation is displayed with green representing lowland and yellows and browns representing high ground.

    Elevation layer on the map

    This image better explains why the U.S. Eighty-Second Infantry Division suffered so many casualties during the attack. The American soldiers were forced to move across open ground, under the clear view of the Germans, and attack uphill. The Germans set up their positions so the Americans would have few terrain advantages.

  7. In the Contents pane, drag the Elevation.tif layer below the World Hillshade layer.

    The elevation layer, although masked by the basemap, will serve as an elevation source for geospatial tools used in this tutorial.

Find the highest elevation

Next, you will determine the highest location within an area where you might want to locate your observer team so its members can clearly see OBJ HILL 223. You will use the Highest Points tool, one of the geospatial tools you downloaded in the first module. Ideally, you will locate your forward observers as far forward as possible.

  1. In the Contents pane, turn off the Elevation.tif layer.
  2. In the Command Search, type Find Highest or Lowest Point and click on the tool.

    Search for the Find Highest Or Lowest Point tool.

    The Find Highest Or Lowest Point pane appears.

  3. In the Find Highest Or Lowest Point pane, set the following:

    • For Input Surface, choose Elevation.tif.
    • For Output Feature Class, type HighestPoint82INFDIV.
    • For Highest or Lowest Point, in the drop-down menu, select Highest points.
    • For Input Area, click the edit button to create a new Highest Points Input Area layer in the and choose Polygons.

    Polygon tool selected in the Highest Points tool

    You will draw a polygon for your forward observers. Within that polygon, the Highest Points tool will find the highest elevation.

  4. For the upper left corner of the polygon, click the American trench line where it intersects with the Corps boundary marker, marked with XXX.
  5. Follow the American trench south to the divisional Control Measure line, marked with XX, and click.
  6. Continue right along Control Measure line XX to its end and click.
  7. Continue north to Control Measure line XXX and click.
  8. Continue along Control Measure line XXX to the original starting point in the upper left corner. Double-click to complete your polygon.

    A transparent blue polygon fills the allied territory between Control Measure lines XXX and XX.

  9. In the Geoprocessing pane, click Run.

    A gold triangle in the middle of the pink polygon is labeled as 231 Meters.

    A series of gold symbols mark the highest elevation point, within the area you defined, for the U.S. Eighty-Second Infantry Division's area of operations. They are labeled as 231 (meters). This elevation represents the single highest position within the area you defined for a forward observer.

  10. In the Contents pane, uncheck the Find Highest Or Lowest Points Input Area (Polygons) layer.

    The Highest Point layer is a temporary layer. To use this data in a geoprocessing tool, you will transform it into a permanent feature class.

  11. In the Contents pane, right-click HighestPoint82INFDIV, point to Data, and choose Export Features.
  12. In the Export Features dialog box, for Output Name, type ForwardObservers and click OK.

    Feature Class to Feature Class tool

    The ForwardObservers point feature class is added to the Contents pane. Next, you will change the symbol to represent a forward observer.

  13. Right-click the ForwardObservers layer and choose Symbology.
  14. In the Symbology pane, click the point symbol.
  15. In the search box on the Gallery tab, type observer friend and press Enter.
  16. In the list of results, click Fires: Field Artillery Observer.

    Fires: Field Artillery symbol in the symbol gallery

    The feature symbology updates.

  17. Close the Symbology pane.
  18. In the Contents pane, uncheck the HighestPoint82INFDIV layer.

    Now that you know the position of the forward observers, you will determine whether team members can see OBJ HILL 223. Next, you will find the highest point within the objective box, using steps that are similar to those you used to locate the forward observer team.

  19. If necessary, reopen the Find Highest or Lowest Points tool.
  20. For Input Area, click the edit button and select Polygons.

    As before, you will define an area, except now you will use a rectangle to match the size of the objective box.

  21. Click the Rectangle symbol.

    Rectangle tool

  22. Click the upper left corner of OBJ HILL 223 and then double-click the lower right corner.

    Completed rectangle on the map

    The rectangle is completed and a new layer, Find Highest Or Lowest Points Input Area (Polygons) 2, is added to the Contents pane. You will again find the highest point within the objective box for Hill 223.

  23. In the Geoprocessing pane, for Input Surface, choose Elevation.tif.
  24. For Output Feature Class, type HighestPointOBJHILL223.
  25. Select Highest points in the drop-down
  26. Click Run.

    A new layer, HighestPointOBJHILL223, is added to the Contents pane and the map. There are several clustered points with the highest elevation value of 254 meters. As before, you will convert the points into a permanent feature class.

    Cluster of highest point symbols in the northwest corner of the objective box, all labeled as 254 Meters

  27. In the Contents pane, right-click the HighestPointOBJHILL223 layer, point to Data, and choose Export Features.
  28. In the Export Features dialog box, for Output Feature Class, type HighestPoint_Hill223.
  29. Click OK. In the Contents pane, uncheck HighestPointOBJHILL223 and Find Highest Or Lowest Points Input Area (Polygons) 2.

Create linear lines of sight

Linear lines of sight illustrate whether an observer can see a specific point on the ground. You will determine whether your forward observer has an unobstructed view of OBJ HILL 223.

  1. On the ribbon, click the Defense Toolbox tab. Click Visibility Analysis.
  2. The Visibility Analysis pane appears. If necessary, click the Linear Line of Sight tab.

    The tool automatically identifies and sets the Elevation.tif layer as an elevation source.

  3. Under Observer Points, in the drop-down menu and choose Enter Manually. Click the Edit Properties button and choose MGRS. Click OK.
  4. Click the Observer Map Point Tool button.

    Observer Map Point Tool button

  5. Click on of the ForwardObservers point symbols.

    A blue dot appears on the symbol.

    Forward Observer point symbol on the map

  6. In the Visibility tool, under Target Points choose Enter Manually and click the Target Map Point Tool button.
  7. On the map, click one of the highest points on Hill 223.

    Highest points of Hill 223

  8. For Output Linear Line of Sight, type ForwardObserver.

    In the Visibility Analysis pane, the Height Above Surface parameter assumes the observer's view is two meters above the measured surface, approximately the height of a typical soldier. You can adjust the height of the observer, as well as the target, if needed.

  9. Expand Observer Options. Under Height Above Surface and for Target, type 2.
  10. On the Visibility Analysis pane, click OK.

    The tool takes a few moments to run. When complete, several supporting layers are added to the Contents pane.

  11. In the Contents pane, expand the new ForwardObserver group layer and locate the ForwardObserver_LLOS_Output layer. Turn the layer off and on to identify the line features added to the map by the tool.

    The ForwardObserver_LLOS_Output layer displays a line of sight between the observer and the target you identified. The resulting line segments are colored green to denote locations along the line that are visible to the observer and red to denote locations that are not visible.

    ForwardObserver_LLOS_Output layer features on the map

    Your forward observer has a semiobstructed view of OBJ HILL 223.

  12. In the Contents pane, locate the ForwardObserver_LLOS_Targets layer. Turn the layer off and on to identify the point feature added to the map by the tool.

    ForwardObserver_LLOS_Targets layer symbols in the Contents pane

    The target location is green and is thus visible to the observer, but the line of sight to that target can be made more visible. Next, you will rerun the tool, placing the observer at a height of 10 meters. On the ground, this elevation can be achieved by placing the observer on a building or tree.

  13. In the Contents pane, right-click the ForwardObserver group layer and choose Remove.
  14. In the Visibility Analysis pane, under Height Above Surface, for Observer, change 2 to 10.
  15. Click OK.

    Line of sight on the map after changing the height of the observer

    Stationing the observer at 10 meters eliminates some, but not all, of the blind spots. Improving the view of forward observers would help them adjust fire, a move that could save lives and ammunition.

Create a radial line of sight

Your forward observer is unlikely to use only one direction to view the target. Observers typically scan a 180-degree radius or more ranging from their immediate vicinity to the intended target. It could be beneficial to identify all visible and nonvisible locations within the field of view for your forward observer while positioned 10 meters above the surface. This is where the Radial Line Of Sight (RLOS) tool is useful, as it calculates the visibility of an area from one or more observer locations. The results show what areas are visible to one or more observers.

  1. In the Contents pane, uncheck the ForwardObserver_1 group layer.
  2. In the Visibility Analysis pane, click the Radial Line of Sight tab.
  3. Under Observer Points, click the Map Point Tool and click your Forward Observer location.
  4. Check the Symbolize Non-Visible Data in Output box.
  5. Expand Observer Options.
  6. For Observer, change the height value from 2 to 10.
  7. Change Distance to 0 to 5000.
  8. For Field of View, change Horizontal to 0 to 360.

    OK button on the visibility tools RLOS tab

  9. Click OK.

    When complete, the RLOS tool adds a new group layer to your Contents pane. This layer represents which locations are visible or nonvisible by your observer positioned 10 meters above the surface.

  10. On the map, zoom in to the area in front of your forward observer.

    The color scheme applied to the layer is random. To simplify identification of visible and nonvisible areas, you'll modify the layer symbology to use green for visible and red for nonvisible locations.

  11. In the Contents pane, expand RLOS. For the RLOS_RLOS_Visibility layer, right-click the symbol for Visible by 1 Observer and choose a light green color.
  12. For Not Visible, choose a light red.

    Map with transparent green and red areas

  13. If necessary, zoom out so that you can observe the axis of advance for both the U.S. 327th and U.S. 328th Infantry Regiments.

    This viewshed reveals that both the 327th and 328th Infantry Regiments would be advancing through large blind spots, as represented by the light red areas. It also shows that the 2nd Landwehr Division maximized the value of its defensive positions by finding low-lying areas below the line of sight of observers. Knowing this in advance means the Eighty-Second Infantry Division could improve visibility during the attacks by placing observers in observation balloons, a method deployed during World War I. This method, however, would have had limited success during the Meuse-Argonne Offensive because much of the battle took place during rain and fog.

    As a result of this knowledge, the division could also take measures to improve mobile communications between the artillery gunners and the advancing infantry. In World War I, this often meant using soldiers as messengers or releasing carrier pigeons.

  14. In the Contents pane, uncheck and collapse the RLOS group layer.
  15. Save the project.

Convert a battlefield 2D map into a 3D scene

Next, you will convert your 2D map into a 3D scene to explore visualization of the regimental locations and enemy fortifications, as well as the viewshed for forward observers.

  1. In the Contents pane, turn on the ForwardObersver_1 group layer.
  2. In the Catalog pane, expand Maps.
  3. Right-click Map, point to Convert, and choose To Local Scene.

    Convert To Local Scene in the context menu

    A 3D scene is created using the same layers in your 2D map.

  4. On the scene, locate the white line of sight between Hill 223 and the forward observer.

    Line of sight between Hill 223 and the forward observer

    Note:

    If the basemap appears dark, this is due to the illumination settings in your scene. To change this, in the Contents pane, double-click Map_3D. Click the Illumination tab. Under Illumination defined by, choose Noon at camera position and click OK.

  5. Click the mouse wheel button to rotate the scene toward the top of the map. Zoom to the line of sight.

    Rotated scene

    Note:

    For help with moving within a scene, see Navigation in 3D.

    The white tube illustrates the direct line of sight between the forward observer and the highest point on Hill 223. This lateral view better illustrates how the rolling terrain of the Meuse-Argonne battlefield creates blind spots, shown in red, for the forward observer, whose task includes adjusting artillery fire as the infantry advances. Advancing under the cover of a rolling barrage became a common tactic in the later years of World War I.

    The green and red line of sight appears to be buried under the ground in places. Next, you will make it more visible by changing the Elevation Surface to match the Elevation.tif layer that you used to create the line of sight.

  6. In the Contents pane, drag Elevation.tif into the Ground layer category, above WorldElevation3D/Terrain3D. Turn on the Elevation.tif layer.

    Elevation Surfaces layer category in the Contents pane

    Note:

    The Elevation Surfaces layer category in the Contents pane defines how the 3D terrain will draw. In this scene, the ground will be shaped based on the Elevation.tif layer. For areas beyond the extent of that DEM, the ground will be shaped based on the default World Elevation surface.

    It is still hard to see the line at some angles.

  7. In the Contents pane, expand ForwardObserver_1 and then double-click ForwardObserver_1_LLOS_Output to open the Layer Properties window.

    In the Contents pane, symbols in the 2D Layers category draw draped on the Elevation Surface. Symbols in the 3D Layers category draw at defined elevations, usually floating in the air. You can adjust those elevation values in the Layer Properties window.

  8. Click the Elevation tab. For Cartographic Offset, type 10.

    Cartographic offset set to 10 meters in the Layer Properties window

    This property will raise the green and red line of sight 10 meters higher and make it easier to see.

  9. Click OK.
  10. Rotate and tilt the scene so your own point of view is close to that of the forward observer.

    Tilted scene

    The closer you get to the viewer's position, the fewer red areas are visible to you, since those areas are hidden from this vantage point. Changing the basemap will also give you a better perspective of the terrain.

  11. On the Map tab, in the Layer group, click Basemap and choose Imagery.

    Imagery basemap

    It looks like both the viewer and the target are on wooded hills, with mostly farmland in between.

  12. Navigate the scene to explore the area.

    3D view of the line of sight

    Changing basemaps gives you more information about the terrain. In this case, the open farm fields would provide flat routes for the advancing tanks. The streams and trees could help camouflage the advancing infantry. However, the dense woods near OBJ CORNAY and OBJ HILL 223 would provide excellent camouflage for entrenched German machine gunners. You are viewing modern imagery, not the battle-scarred landscape that existed in this area during the Meuse-Argonne offensive, but it offers an illustration of how imposing an imagery layer can provide the context needed to analyze the terrain and how it could affect combat operations. During World War I, aerial photography was used extensively for reconnaissance.

  13. Save the project.
  14. Close ArcGIS Pro.

In this tutorial, you applied Defense Toolbox to the Meuse-Argonne Offensive, a battle that, to this day, is still the bloodiest battle in American history. First, you converted a new project into a mission-ready map. Then, you used the Military Symbology Editor to create the American and German regiments that engaged on the morning of October 7, 1918. With Distance and Direction, you discovered critical information about the range of the 75-mm artillery and FT-17 tanks supporting the attack of the U.S. 328th Infantry Regiment. The Visibility tools allowed you to make simple adjustments to increase the viewshed of the forward observers acting as the eyes of the artillery.

The tools introduced in this tutorial could be adapted to a wide variety of civilian careers ranging from firefighters and cartographers to police officers and communication specialists. Search and rescue officials could use these tools to establish the viewsheds needed to efficiently find lost hikers.

You can find more tutorials in the tutorial gallery.