Wednesday, December 16, 2009

Twitter & ESRI’s Silverlight API

Twitter & ESRI's Silverlight API

Ever wonders what people are talking about at a particular location?  This application, developed by the ESRI’s Applications Prototype Lab, uses Twitter’s search API and ESRI’s Silverlight API to request and display geo-referenced tweets.  The application is accessible from the following link.
http://maps.esri.com/sldemos/twittermap/default.aspx

To use, first zoom into an area of interest (preferably an urban area).  Click the Add button in the upper left hand corner of the application and then click once on the map.  The ten most recent tweets within the search radius will be added to the map using the tweeter’s profile image.  Mouse-over the profile images to read the tweets themselves.  Next, try refining your search with a smaller (or larger) search radius and the inclusion of a search keyword like #esri.

The following technologies were used to develop this application:

  1. Microsoft Silverlight 3
    http://silverlight.net/
  2. ESRI’s ArcGIS API for Silverlight version 1.1
    http://resources.esri.com/arcgisserver/apis/silverlight/
  3. Microsoft Silverlight Toolkit (November 2009)
    http://www.codeplex.com/Silverlight
  4. Linq to Twitter
    Comprehensive LINQ provider to Twitter’s API
    http://linqtotwitter.codeplex.com/
  5. Orbifold’s Graphite for Silverlight
    Simple framework for presenting spring-enabled node-edge diagrams.
    http://www.orbifold.net/default/?page_id=1270

Monday, November 23, 2009

Silverlight Coverflow with Reflection

This post describes how to create an attractive and compelling cover flow control using Silverlight as illustrated below.

Silverlight Coverflow with Reflection

The basis of this sample is the excellent work done by Darick C with his Silverlight Cover Flow project published on CodePlex.  To begin, download Darick’s Cover Flow contribution.  Create a new Silverlight application called “CoverFlowWithReflection” in Microsoft Visual Studio 2008, and add reference to either the Coverflow project or binary.

Below is the XAML for MainPage.xaml.  Each cover flow item is defined with an image and a textbox.

<UserControl
    x:Class="CoverFlowWithReflection.MainPage"
    xmlns="http://schemas.microsoft.com/winfx/2006/xaml/presentation" 
    xmlns:x="http://schemas.microsoft.com/winfx/2006/xaml"
    xmlns:d="http://schemas.microsoft.com/expression/blend/2008"
    xmlns:mc="http://schemas.openxmlformats.org/markup-compatibility/2006" 
    mc:Ignorable="d"
    d:DesignWidth="640"
    d:DesignHeight="480"
    xmlns:c="clr-namespace:ControlLibrary;assembly=ControlLibrary"
    >
    <Grid>
        <c:CoverFlowControl x:Name="CoverFlow" Margin="0,10,0,0">
            <c:CoverFlowControl.ItemTemplate>
                <DataTemplate>
                    <Grid>
                        <Image Source="{Binding Path=Picture, Mode=OneWay}"
                               Height="300"
                               Stretch="UniformToFill"
                               />
                        <TextBlock Text="{Binding Path=Name, Mode=OneWay}"
                                   Foreground="White"
                                   HorizontalAlignment="Center"
                                   FontSize="12"
                                   />
                    </Grid>
                </DataTemplate>
            </c:CoverFlowControl.ItemTemplate>
        </c:CoverFlowControl>
    </Grid>
</UserControl>

The following snippet is for the MainPage.xaml code-behind (or MainPage.xaml.cs).  The code defines a new generic collection and assigns it to the coverflow control.  Please excuse the crazy formatting, this is required to squeeze the text into the blog.

using System.Collections.ObjectModel;
using System.Windows.Controls;

namespace CoverFlowWithReflection {
    public partial class MainPage : UserControl {
        private const string PREFIX =
             "http://upload.wikimedia.org/wikipedia/commons/thumb/";
        private ObservableCollection<Thumbnail> _thumbnails =
            new ObservableCollection<Thumbnail>();
        //
        // CONSTRUCTOR
        //
        public MainPage() {
            InitializeComponent();

            // Populate thumbnail collection
            this._thumbnails.Add(
                new Thumbnail {
                    Name = "Albert Einstein",
                    Picture = PREFIX +
                        "7/78/Einstein1921_by_F_Schmutzer_4.jpg" +
                        "/225px-Einstein1921_by_F_Schmutzer_4.jpg"
                }
            );
            this._thumbnails.Add(
                new Thumbnail {
                    Name = "Isaac Newton",
                    Picture = PREFIX +
                        "3/39/GodfreyKneller-IsaacNewton-1689.jpg" +
                        "/225px-GodfreyKneller-IsaacNewton-1689.jpg"
                }
            );
            this._thumbnails.Add(
                new Thumbnail {
                    Name = "Gottfried Leibniz",
                    Picture = PREFIX +
                        "6/6a/Gottfried_Wilhelm_von_Leibniz.jpg" +
                        "/200px-Gottfried_Wilhelm_von_Leibniz.jpg"
                }
            );
            this._thumbnails.Add(
                new Thumbnail {
                    Name = "Niels Bohr",
                    Picture = PREFIX + 
                        "6/6d/Niels_Bohr.jpg" +
                        "/180px-Niels_Bohr.jpg"
                }
            );
            this._thumbnails.Add(
                new Thumbnail {
                    Name = "Ernest Rutherford",
                    Picture = PREFIX +
                        "5/57/Ernest_Rutherford2.jpg" +
                        "/200px-Ernest_Rutherford2.jpg"
                }
            );
            this._thumbnails.Add(
                new Thumbnail {
                    Name = "Stephen Hawking",
                    Picture = PREFIX +
                        "e/eb/Stephen_Hawking.StarChild.jpg" +
                        "/200px-Stephen_Hawking.StarChild.jpg"
                }
            );
            this._thumbnails.Add(
                new Thumbnail {
                    Name = "Galileo Galilei",
                    Picture = PREFIX +
                        "c/cc/Galileo.arp.300pix.jpg" +
                        "/225px-Galileo.arp.300pix.jpg"
                }
            );
            this._thumbnails.Add(
                new Thumbnail {
                    Name = "Carl Friedrich Gauss",
                    Picture = PREFIX +
                        "9/9b/Carl_Friedrich_Gauss.jpg" +
                        "/225px-Carl_Friedrich_Gauss.jpg"
                }
            );
            this._thumbnails.Add(
                new Thumbnail {
                    Name = "J. Robert Oppenheimer",
                    Picture = PREFIX +
                        "0/03/JROppenheimer-LosAlamos.jpg" +
                        "/200px-JROppenheimer-LosAlamos.jpg"
                }
            );

            // Assign collection to CoverFlow control
            this.CoverFlow.ItemsSource = _thumbnails;
        }
    }
    public class Thumbnail {
        public string Name { get; set; }
        public string Picture { get; set; }
    }
}

The result of this code is a functional coverflow control as shown below.

Plain cover flow

The control is excellent for presenting a catalog of information and also providing an organic look and feel.  The following two snippet will demonstrate how to add depth to this control.  First, define a transitional background.

<Grid>
    <Grid.Background>
        <LinearGradientBrush StartPoint="0,0" EndPoint="0,1">
            <GradientStop Color="#000000" Offset="0.0"/>
            <GradientStop Color="#000000" Offset="0.6"/>
            <GradientStop Color="#131212" Offset="0.7"/>
            <GradientStop Color="#3A3535" Offset="0.8"/>
            <GradientStop Color="#625A5A" Offset="0.9"/>
            <GradientStop Color="#808080" Offset="1.0"/>
        </LinearGradientBrush>
    </Grid.Background>
    <c:CoverFlowControl x:Name="CoverFlow" Margin="0,10,0,0">
        <!-- omitted for clarity  -->
    </c:CoverFlowControl>
</Grid>

This gives the illusion that the coverflow items (images in this case) are residing on a surface with a little perspective.

Cover flow with background

And lastly, to the complete the visual effect, lets add a reflection.  This is achieved by adding a second image to the coverflow item data template.  A RenderTransfrom and OpacityMask are used to flip and fade the image respectively.

<c:CoverFlowControl x:Name="CoverFlow" Margin="0,10,0,0">
    <c:CoverFlowControl.ItemTemplate>
        <DataTemplate>
            <Grid>
                <Image Source="{Binding Path=Picture, Mode=OneWay}"
                       Height="300"
                       Stretch="UniformToFill"
                       />
                <TextBlock Text="{Binding Path=Name, Mode=OneWay}"
                           Foreground="White"
                           HorizontalAlignment="Center"
                           FontSize="12"
                           />
                <Image Source="{Binding Path=Picture, Mode=OneWay}"
                       Height="300"
                       Stretch="UniformToFill"
                       RenderTransformOrigin="0.5,1.0">
                    <Image.RenderTransform>
                        <TransformGroup>
                            <ScaleTransform ScaleY="-1"/>
                            <TranslateTransform Y="3"/>
                        </TransformGroup>
                    </Image.RenderTransform>
                    <Image.OpacityMask>
                        <LinearGradientBrush StartPoint="0.5,0"
                                             EndPoint="0.5,1">
                            <GradientStop Color="#00000000" Offset="0.0"/>
                            <GradientStop Color="#00000000" Offset="0.7"/>
                            <GradientStop Color="#FFFFFFFF" Offset="1.0"/>
                        </LinearGradientBrush>
                    </Image.OpacityMask>
                </Image>
            </Grid>
        </DataTemplate>
    </c:CoverFlowControl.ItemTemplate>
</c:CoverFlowControl>

The result is an attractive clowflow with reflection.

Cover flow with background and reflection

There are two alternatives to this technique that you may want to consider.  The first is to use a pixel shader in Silverlight 3, Steve from Cellbi describes how to create a reflection pixel shader in this post.  The second is to make use of Silverlight 3’s WriteableBitmap class to generate a reflection.  Jeff Prosise from Wintellect describes the technique in this post.

The source code for this sample application is here:
http://cid-dd16c3f34f4d913e.skydrive.live.com/self.aspx/Kiwigis/CoverFlowWithReflection.zip

Tuesday, October 20, 2009

ESRI launches Mapping For Everyone website

Today ESRI announced the launch of a new website entitled Mapping for Everyone.  The site features an innovative four step web page for creating (and sharing) demographic maps.  Developers can experiment with the free JavaScript, Flex and Silverlight APIs or browse user samples.  Lastly, try ESRI’s free virtual globe called ArcGIS Explorer.
http://www.esri.com/mapping

Mapping for Everyone

Wednesday, October 7, 2009

Tag Map Magnifier for Microsoft Surface

This video demonstrates a new proof-of-concept developed by the Applications Prototype Lab in Redlands, California for the Microsoft Surface.

The application was developed using ESRI’s ArcGIS API for WPF and utilizes Surface-specific tags to act as virtual map magnifiers.  Tags are made up of a collection of domino-like black dots and are uniquely identified by the Surface device.  Developers can retrieve the tag position, identifier code and orientation.

The lab used the tags to add additional Map UIElements to the display.  As the user manipulates the tag, the magnifier map is repositioned and its map extent updated.  The map insets initially have same scale as the base map, a small scrollbar is provided to allow the user to magnify the map (or “zoom in”).

Because tags are uniquely identified, if a user removes a tag and then places it back on the table, we are able to restore previous settings such as the map magnifier’s size and relative scale.

Friday, September 4, 2009

Dynamic Charting for ArcGIS Desktop

This post describes a new sample published by ESRI’s Application Prototype Lab and inspired by Jack Dangermond geodesign presentation at the 2009 ESRI International User Conference.

Dynamic Charting for ArcGIS Desktop is a free sample (with source code) available from the ESRI code gallery.  The sample summarizes a layer’s features based on the length/area and grouped by unique values from the renderer.  The differentiating factor between this sample and the out-of-the-box charting tools is that this sample updates dynamically even in an edit session.

Dynamic Charting for ArcGIS Desktop 

Download

Wednesday, August 26, 2009

How to create a data report with ArcGIS Diagrammer

ArcGIS Diagrammer is productivity tool for ESRI’s ArcGIS Desktop users.  Diagrammer is primarily used to create or view geodatabase designs in a graphical editor.  This post will examine data reporting, a feature of Diagrammer that might be useful to a wide variety of ArcGIS Desktop users.

Let’s say that you or your organization has an existing geodatabase.  You may want to ask:

  1. Does my geodatabase have any empty feature datasets?
  2. Does my geodatabase have any feature classes with no data?
  3. Does my geodatabase have any subtypes with no data?
  4. Does my geodatabase have any feature classes with holes?

Diagrammer’s data reporter will help answer these questions.  Below is a short walk-through of creating a data report for a sample geodatabase that is included with ESRI’s ArcTutor product.

After starting ArcGIS Diagrammer, click Tools > Data Report.

A new tab will be added to the application called Data Report.  If the Properties Window is not visible then click View > Properties.  In the Properties Window, click the ellipsis () button next to the Workspace property.

The ellipsis button will launch a dialog for navigating to (and selecting) a geodatabase or SDE connection.  All geodatabase types are supported.

The selected geodatabase will be scanned for feature datasets, feature classes and subtypes.  This may take a few seconds or minutes depending on the size and complexity of the geodatabase.  When the scanning is complete a HTML report will be presented in the Data Report tab.

The report includes a header table and details about all feature classes, tables and subtypes.  Most useful is the number of features/rows per feature class, table and subtype.  Lastly, the report includes a small thumbnail representation of the data that, by default, hyperlinks to a larger image.

Data reports can be sent to a local printer/plotter or virtual printer should you wish to create a PDF document.  Alternatively, reports can be exported to a new HTML document.  To do so, click File > Export.

The save as dialog that appears will prompt you for the name and type of web document to create.  By default, “web archive” is selected.  We recommend you select “webpage, complete” as this will make a copy of the thumbnail images.  The only disadvantage of exporting a report to HTML is that the larger linked images will not included in the output location.  To prevent this, you can disable the creation of the larger images in the options dialog (see below).

This is an example of an export data report displayed in Windows Explorer.

When the exported HTML data report is viewed in a web browser, it looks identical to the report in ArcGIS Diagrammer.

Some options are provided to change the look and feel of data reports.  To display the Diagrammer options dialog, click Tools > Options.

The data report options are located under the Report > Data tab.  Most options are related to the font and the thumbnail images.

In the screenshot below I modified the font to be “Segoe Print” and increased the size of the small image to 200x200 and removed the larger linked image (Show Large Image = False).

That concludes this brief walkthrough of creating a data report with ArcGIS Diagrammer.  Diagrammer is a free download from ArcScripts and includes full source code.

List of other online tutorials:

Tuesday, August 25, 2009

Site Suitability for Microsoft Surface

During the 2009 ESRI International User Conference, Jack Dangermond introduced his vision of geographic design or “geodesign”.  Click here to view Jack’s presentation of his geodesign vision.  To assist Jack’s presentation a few demonstrations were created to help illustrate his points.  One such demonstration used a Microsoft Surface device to sketch planning areas on an interactive map.

This application was developed using the ArcGIS API for WPF by the Applications Prototype Lab.  The base map is from ArcGIS Online and the overlaid suitability maps were sourced from a local ArcGIS Server.  A very basic application but it demonstrates the interactivity of a multi-user/multi-touch device for planning and communal design.

Friday, July 24, 2009

Ubisoft shows R.U.S.E on Microsoft Surface at E3 2009

R.U.S.E is an upcoming real time strategy (RTS) game developed by Ubisoft for the Xbox360 and PS3.  At this year’s E3 conference, Ubisoft demonstrated the game on a Microsoft Surface table.

Space navigation looks rather complicated but I really like the way that military units are assigned positions and targets.

Related links:
http://gamerblips.dailyradar.com/story/ubisoft_reveals_ruse_surprise/

Friday, July 17, 2009

What would happen if the Earth stopped spinning?

A new post by the Applications Prototype Lab examines what would happen to the world’s oceans if the Earth stopped spinning.

What would happen if the Earth stopped spinning?

Monday, July 6, 2009

New Blog from ESRI’s Applications Prototype Lab

ESRI’s Applications Prototype Lab have just launched a blog which will showcase innovative proof-of-concepts and other interesting research.  Last month the lab released two videos of Surface applications, here and here.  Today the lab released eight new Surface videos here.

For more videos please visit the post here.

Thursday, June 25, 2009

How to Surface-enable the ArcGIS API for WPF

The Applications Prototype Lab at ESRI have created a few proof-of-concepts for the Surface using the ArcGIS API for WPF.  Examples of which can be seen here and here.

Surface applications are essentially WPF applications running in full screen mode.  When a user interacts with an application on a Surface device is not through the standard mouse API but through a specific Surface API.  The code below describes how to Surface-enable the map control that comes with the ArcGIS API for WPF.  This is just a basic implementation and should be treated as a developer sample rather than anything official.

SurfaceMap.xaml

After installing the Microsoft Surface SDK 1.0 (or 1.1) you will see a few extra items in the new projects dialog of Microsoft Visual Studio 2008.  Select Surface Application, add a reference to the ArcGIS API for WPF assemblies and then add a new resource file called SurfaceMap.xaml.  Ensure that the build action is set to page.

<ResourceDictionary
 xmlns="http://schemas.microsoft.com/winfx/2006/xaml/presentation"
 xmlns:local="clr-namespace:ESRI.PrototypeLab.Surface.Ccm"
 xmlns:x="http://schemas.microsoft.com/winfx/2006/xaml"
 xmlns:s="http://schemas.microsoft.com/surface/2008"
 xmlns:esri="clr-namespace:ESRI.ArcGIS.Client;assembly=ESRI.ArcGIS.Client"
    >
    <Style TargetType="{x:Type local:SurfaceMap}">
        <Setter Property="Template">
            <Setter.Value>
                <ControlTemplate TargetType="{x:Type local:SurfaceMap}">
                    <Border
Background="{TemplateBinding Background}" BorderBrush="{TemplateBinding BorderBrush}" BorderThickness="{TemplateBinding BorderThickness}" Width="{TemplateBinding Width}" Height="{TemplateBinding Height}" > <esri:Map Name="PART_map"
PanDuration="0"
ZoomDuration="0" /> </Border> </ControlTemplate> </Setter.Value> </Setter> </Style> </ResourceDictionary>

App.xaml

Next you need to inform the compiler to load SurfaceMap.xaml as a resource.  To do so, add an entry to the App.xaml file as shown below.

<Application x:Class="ESRI.PrototypeLab.Surface.Ccm.App"
    xmlns="http://schemas.microsoft.com/winfx/2006/xaml/presentation"
    xmlns:x="http://schemas.microsoft.com/winfx/2006/xaml"
    StartupUri="SurfaceWindow1.xaml"
    >
    <Application.Resources>
        <ResourceDictionary>
            <ResourceDictionary.MergedDictionaries>
                <ResourceDictionary Source="...generic.xaml"/>
                <ResourceDictionary
Source="/ESRI.PrototypeLab.Surface.Ccm;component/SurfaceMap.xaml"/> </ResourceDictionary.MergedDictionaries> </ResourceDictionary> </Application.Resources> </Application>

SurfaceMap.cs

Add a new code file called SurfaceMap.cs and make sure that the build action is set to compile.  The code below contains the bulk of the logic to interpret contact (i.e. finger) manipulation.  The two key points to note is the manipulation processor and the inertia processor.  The manipulation processor will raise events when users manipulate performs a panning or zooming action.  The inertia processor is used to continue panning if the user flicks map.

using System;
using System.Windows;
using System.Windows.Input;
using ESRI.ArcGIS.Client;
using ESRI.ArcGIS.Client.Geometry;
using Microsoft.Surface.Presentation;
using Microsoft.Surface.Presentation.Controls;
using Microsoft.Surface.Presentation.Manipulations;
using Microsoft.Surface;

namespace ESRI.PrototypeLab.Surface.Ccm {
    public partial class SurfaceMap : SurfaceUserControl {
        private Map m_map = null;
        private Affine2DManipulationProcessor
m_manipulationProcessor = null; private Affine2DInertiaProcessor m_inertiaProcessorMove = null; static SurfaceMap() { FrameworkElement.DefaultStyleKeyProperty.OverrideMetadata(
typeof(SurfaceMap),
new FrameworkPropertyMetadata(typeof(SurfaceMap))); } public SurfaceMap() : base() { // Define manipulation processor used or panning and Zooming this.m_manipulationProcessor =
new Affine2DManipulationProcessor( Affine2DManipulations.TranslateX | Affine2DManipulations.TranslateY | Affine2DManipulations.Scale, this, true); this.m_manipulationProcessor.Affine2DManipulationStarted +=
new EventHandler<Affine2DOperationStartedEventArgs>
(this.ManipulationProcessor_Affine2DManipulationStarted); this.m_manipulationProcessor.Affine2DManipulationDelta +=
new EventHandler<Affine2DOperationDeltaEventArgs>
(this.ManipulationProcessor_Affine2DManipulationDelta); this.m_manipulationProcessor.Affine2DManipulationCompleted +=
new EventHandler<Affine2DOperationCompletedEventArgs>
(this.ManipulationProcessor_Affine2DManipulationCompleted); // Define inertia proceesor for panning this.m_inertiaProcessorMove = new Affine2DInertiaProcessor(); this.m_inertiaProcessorMove.Affine2DInertiaDelta +=
new EventHandler<Affine2DOperationDeltaEventArgs>
(this.InertiaProcessorMove_Affine2DInertiaDelta); this.m_inertiaProcessorMove.Affine2DInertiaCompleted +=
new EventHandler<Affine2DOperationCompletedEventArgs>
(this.InertiaProcessorMove_Affine2DInertiaCompleted); } public override void OnApplyTemplate() { base.OnApplyTemplate(); this.m_map = (Map)this.Template.FindName("PART_map", this); } public Map Map { get { return this.m_map; } set { this.m_map = value; } } protected override void OnContactDown(ContactEventArgs e) { base.OnContactDown(e); if (!e.Contact.IsFingerRecognized) { return; } e.Contact.Capture(this, CaptureMode.SubTree); this.m_manipulationProcessor.BeginTrack(e.Contact); e.Handled = true; } protected override void OnContactChanged(ContactEventArgs e) { base.OnContactChanged(e); if (!e.Contact.IsFingerRecognized) { return; } Point position = e.Contact.GetPosition(this); if (position.X < 0 || position.Y < 0 || position.X > this.ActualWidth || position.Y > this.ActualHeight) { e.Contact.Capture(this, CaptureMode.None); e.Handled = true; return; } e.Contact.Capture(this, CaptureMode.SubTree); this.m_manipulationProcessor.BeginTrack(e.Contact); e.Handled = true; } protected override void OnContactUp(ContactEventArgs e) { base.OnContactUp(e); if (!e.Contact.IsFingerRecognized) { return; } e.Contact.Capture(this, CaptureMode.None); } private void ManipulationProcessor_Affine2DManipulationStarted(
object sender, Affine2DOperationStartedEventArgs e) { if (this.m_inertiaProcessorMove.IsRunning) { this.m_inertiaProcessorMove.End(); } } private void ManipulationProcessor_Affine2DManipulationDelta(
object sender, Affine2DOperationDeltaEventArgs e) { if (this.m_map == null) { return; } if (this.m_map.Extent == null) { return; } if ((e.Delta.X == 0) &&
(e.Delta.Y == 0) &&
(e.ScaleDelta == 0)) { return; } if ((e.Delta.X != 0) || (e.Delta.Y != 0)) { MapPoint center = this.m_map.Extent.GetCenter(); Point screen = this.m_map.MapToScreen(center); Point newScreen; switch(ApplicationLauncher.Orientation){ case UserOrientation.Top: // Surface is upside-down newScreen = Point.Add(screen, e.Delta); break; case UserOrientation.Bottom: // Surface has normal orientation newScreen = Point.Subtract(screen, e.Delta); break; default: return; } MapPoint newCenter = this.m_map.ScreenToMap(newScreen); this.m_map.PanTo(newCenter); Window w = SurfaceWindow.GetWindow(this); } if (e.ScaleDelta != 0) { if (Contacts.GetContactsCaptured(this).Count > 1) { this.m_map.ZoomToResolution(
this.m_map.Resolution / e.ScaleDelta); } } } private void ManipulationProcessor_Affine2DManipulationCompleted(
object sender, Affine2DOperationCompletedEventArgs e) { this.m_inertiaProcessorMove.InitialOrigin = new Point(0, 0); this.m_inertiaProcessorMove.InitialVelocity = e.Velocity * 10; this.m_inertiaProcessorMove.DesiredDeceleration = 0.005; this.m_inertiaProcessorMove.Begin(); } private void InertiaProcessorMove_Affine2DInertiaDelta(
object sender, Affine2DOperationDeltaEventArgs e) { if ((e.Velocity.X == 0) && (e.Velocity.Y == 0)) { return; } MapPoint center = this.m_map.Extent.GetCenter(); Point screen = this.m_map.MapToScreen(center); Point newScreen; switch (ApplicationLauncher.Orientation) { case UserOrientation.Top: // Surface is upside-down newScreen = Point.Add(screen, e.Velocity); break; case UserOrientation.Bottom: // Surface has normal orientation newScreen = Point.Subtract(screen, e.Velocity); break; default: return; } MapPoint newCenter = this.m_map.ScreenToMap(newScreen); this.m_map.PanTo(newCenter); } private void InertiaProcessorMove_Affine2DInertiaCompleted(
object sender, Affine2DOperationCompletedEventArgs e) { } } }

SurfaceWindow1.xaml

The snippet below demonstrates how to add a reference to the SurfaceMap defined in the snippets above.

<s:SurfaceWindow
    x:Class="ESRI.PrototypeLab.Surface.Ccm.SurfaceWindow1"
    xmlns="http://schemas.microsoft.com/winfx/2006/xaml/presentation"
    xmlns:x="http://schemas.microsoft.com/winfx/2006/xaml"
    xmlns:s="http://schemas.microsoft.com/surface/2008"
    xmlns:local="clr-namespace:ESRI.PrototypeLab.Surface.Ccm"
    Title="my Title"
    Height="768"
    Width="1024"
    Loaded="SurfaceWindow_Loaded"
    >
    <Grid>
        <local:SurfaceMap x:Name="surfaceMap" />
    </Grid>
</s:SurfaceWindow>

SurfaceWindow1.xaml.cs (code behind)

In the code-behind of the Surface window, the map extent is defined and the ArcGIS Online world street map layer is added.

private void SurfaceWindow_Loaded(object sender, RoutedEventArgs e) {
    // Add the ArcGIS Online street map
    ArcGISTiledMapServiceLayer streets = new ArcGISTiledMapServiceLayer(){
        ID = "street",
        Url = "http://server.arcgisonline.com/ArcGIS/rest/services" +
"/ESRI_StreetMap_World_2D/MapServer"
, Opacity = 1 }; this.surfaceMap.Map.Extent =
new Envelope(-116.992383, 33.126732, -116.560400, 32.797143); this.surfaceMap.Map.Layers.Add(streets); // Listen to map events this.surfaceMap.Map.ExtentChanging +=
new EventHandler<ExtentEventArgs>(this.Map_ExtentChanging); this.surfaceMap.Map.ExtentChanged +=
new EventHandler<ExtentEventArgs>(this.Map_ExtentChanged); }

This concludes this tutorial on adding Surface support to the ArcGIS API for WPF map control. For more information, please visit the ArcGIS API for Silverlight/WPF home page, support forum and resource center.

Cross Country Mobility for Microsoft Surface

Yesterday the Applications Prototype Lab at ESRI released demonstration videos of two Microsoft Surface applications.  The first was a demonstration of a simulated police dispatcher (announced here) and the second is a cross country mobility application discussed in this post.

This Surface application is built with ESRI’s ArcGIS API for WPF and references map and geoprocessing services from ArcGIS Server.  Cross country mobility is the name giving to an exercise of determining the most efficient path between two locations.  Depending on the data (and parameters) the end user can find a route that is the fastest, shortest, most fuel efficient, avoids urban areas, flattest or any other condition.

The first step illustrated in the video is the rating of three geographic layers: slope, vegetation and transportation.  The user can assign a preference to weight one more than others.  For example, slope could be a larger consideration if moving heavy equipment than the vegetation type.  Secondly, items within each layer can also be rated.  For example, the user can indicate that low slope is preferable to steep slopes and that grades great than 40° are “no go” (or impossible to traverse).

The next step is to indicate the intended target location for the three flagged vehicles/people/units.  In the demonstration video the target is represented by a bulls eye button than can dragged into position.

After the three geographic layer have been rated and the target placed into position, a request is sent to ArcGIS Server to perform a weighted overlay using the user defined parameters.  The result is a new geographic layer called a cost surface.  A cost surface is like an image where each pixel contains a cost value, that is, the cost for an object to traverse it.

The next step, uses the cost surface to find the least cost path from the three flagged objects to the target.

The final step is the creation of a cost corridor.  A cost corridor is an area around the least cost path with a plus or minus one, two and three percent variation.  Basically, what alternative path could the three flagged objects take by sacrificing one to three percent cost (in time, money, fuel etc).

This is a very brief discussion of one of many geoprocessing capabilities in the ArcGIS product suite.  I would encourage you to explore this exciting technology at the ESRI website.

Police Dispatcher on Microsoft Surface

In May 2009, the Applications Prototype Lab published a web application called “Police Dispatcher”.  The application simulated a police dispatch system with real time incidents and the tracking of police vehicles.  The application was built using Silverlight 2 and the ArcGIS API for Silverlight.

Police Dispatcher for Microsoft Silverlight

The police dispatcher demonstration was recently ported to the Microsoft Surface as a Surface application.  Surface applications are similar to standard WPF application except that they target the Surface hardware and include references to a few extra libraries.  The transition was relatively trivial, for example, the application references the ArcGIS API for WPF rather than the ArcGIS API for Silverlight.

In the Surface application we took advantage of some the goodness of WPF such as drop shadows and glow bitmap effects.

Saturday, May 16, 2009

Exploiting the ESRI Projection Engine

The ESRI products ArcGIS Explorer, ArcGIS Desktop and ArcGIS Engine ship with an extremely useful C DLL called the projection engine Library.  The projection engine is used by these products to perform geodetic (or ellipsoidal) computations.

The projection engine is fully documented in the SDE C API and there is a sample VB6 wrapper for two functions on the EDN web site.

The VB6 sample be easily ported to C# using DLLImportAttribute.  However there are two disadvantages of using DLLImport.

  1. DLLs are loaded into memory each time a function is called,
  2. The file and path name to the DLL is hard coded at design time.

However with .NET 2.0 a new method called GetDelegateForFunctionPointer was added to the Marshal class to allow late binding. This meant that external DLLs could be discovered and loaded at runtime.

Below is a C# wrapper to the ESRI Projection Engine.  The wrapper is developed as a singleton so that the DLL is only loaded once per application instance.  Additionally, the location of the projection engine library is discovered at runtime from the registry.

Here is a example using the projection engine singleton for ArcGIS Explorer to calculate the geodetic distance between London and Paris.  The geodetic distance is the shortest distance between two points on the surface of an ellipsoid.

public class ProjectionEngineTest{
    public void Main() {
        double distance = 0d;
        double azimuthForward = 0d;
        double azimuthBack = 0d;
        ProjectionEngine projectionEngine = ProjectionEngineExplorer.GetInstance();
        projectionEngine.GetGeodesicDistance(
            ProjectionEngine.GLOBERADIUS,
            0,
            ProjectionEngine.ToRadians(51.50d),
            ProjectionEngine.ToRadians(-0.12d),
            ProjectionEngine.ToRadians(48.86d),
            ProjectionEngine.ToRadians(2.35d),
            out distance,
            out azimuthForward,
            out azimuthBack);
        MessageBox.Show(string.Format("London to Paris is {0} meters", distance.ToString()));               
    }
}

image

Here is the source code to the wrappers.

Please note that the code and methodology used in this post is not endorsed or supported by ESRI. Use this code at your own risk.

using System;
using System.Collections.Generic;
using System.IO;
using System.Runtime.InteropServices;
using System.Text;
using System.Windows.Forms;
using Microsoft.Win32;

namespace ESRI.ArcGIS.Sample {
    /// <summary>
    /// Projection Engine Abstract Class
    /// </summary>
    public abstract class ProjectionEngine {
        public const double GLOBERADIUS = 6367444.65712259d;
        private GeodesicDistance m_gd = null;
        private GeodesicCoordinate m_gc = null;

        [DllImport("kernel32.dll")]
        private static extern IntPtr LoadLibrary(String dllname);

        [DllImport("kernel32.dll")]
        private static extern IntPtr GetProcAddress(IntPtr hModule, String procname);

        private delegate void GeodesicDistance(
            [In] double semiMajorAxis,
            [In] double eccentricity,
            [In] double longitude1,
            [In] double latitude1,
            [In] double longitude2,
            [In] double latitude2,
            [Out] out double distance,
            [Out] out double azimuthForward,
            [Out] out double azimuthBack);

        private delegate void GeodesicCoordinate(
            [In] double semiMajorAxis,
            [In] double eccentricity,
            [In] double longitude1,
            [In] double latitude1,
            [In] double distance,
            [In] double azimuth,
            [Out] out double longitude2,
            [Out] out double latitude2);
        //
        // CONSTRUCTOR
        //
        protected ProjectionEngine() {
            IntPtr pe = ProjectionEngine.LoadLibrary(this.DLLPath);
            IntPtr gd = ProjectionEngine.GetProcAddress(pe, "pe_geodesic_distance");
            IntPtr gc = ProjectionEngine.GetProcAddress(pe, "pe_geodesic_coordinate");

            this.m_gd = (GeodesicDistance)Marshal.GetDelegateForFunctionPointer(
                gd, typeof(GeodesicDistance));
            this.m_gc = (GeodesicCoordinate)Marshal.GetDelegateForFunctionPointer(
                gc, typeof(GeodesicCoordinate));
        }
        //
        // PUBLIC METHODS
        //
        public abstract string DLLPath { get;}
        //
        // PUBLIC METHODS
        //
        /// <summary>
        /// Returns the geodestic azimuth and distance between two geographic locations.
        /// </summary>
        /// <param name="semiMajorAxis">Semi Major Axis</param>
        /// <param name="eccentricity">Globe Eccentricity</param>
        /// <param name="longitude1">From Longitude (radians)</param>
        /// <param name="latitude1">From Latitude (radians)</param>
        /// <param name="longitude2">To Longitude (radians)</param>
        /// <param name="latitude2">To Latitude (radians)</param>
        /// <param name="distance">Returned Geodetic Distance</param>
        /// <param name="azimuthForward">Returned Forward Azimuth (radians)</param>
        /// <param name="azimuthBack">Returned Reverse Azimuth (radians)</param>
        public void GetGeodesicDistance(
            double semiMajorAxis,
            double eccentricity,
            double longitude1,
            double latitude1,
            double longitude2,
            double latitude2,
            out double distance,
            out double azimuthForward,
            out double azimuthBack) {
            this.m_gd(
                semiMajorAxis,
                eccentricity,
                longitude1,
                latitude1,
                longitude2,
                latitude2,
                out distance,
                out azimuthForward,
                out azimuthBack);
        }
        /// <summary>
        /// Returns the geographic location based on the azimuth and distance from another geographic location
        /// </summary>
        /// <param name="semiMajorAxis">Semi Major Axis</param>
        /// <param name="eccentricity">Globe Eccentricity</param>
        /// <param name="longitude1">From Longitude (radians)</param>
        /// <param name="latitude1">From Latitude (radians)</param>
        /// <param name="distance">Distance from "From Location"</param>
        /// <param name="azimuth">Azimuth from "From Location"</param>
        /// <param name="longitude2">Out Logitude (in radians)</param>
        /// <param name="latitude2">Out Latitude (in radians)</param>
        public void GetGeodesicCoordinate(
            double semiMajorAxis,
            double eccentricity,
            double longitude1,
            double latitude1,
            double distance,
            double azimuth,
            out double longitude2,
            out double latitude2) {
            this.m_gc(
                semiMajorAxis,
                eccentricity,
                longitude1,
                latitude1,
                distance,
                azimuth,
                out longitude2,
                out latitude2);
        }
        /// <summary>
        /// Converts Radians to Decimal Degrees.
        /// </summary>
        /// <param name="degrees">In angle in decimal degrees.</param>
        /// <returns>Returns angle in radians.</returns>
        public static double ToRadians(double degrees) { return degrees * (Math.PI / 180d); }
        /// <summary>
        /// Converts Radians to Decimal Degrees.
        /// </summary>
        /// <param name="radians">In angle in radians.</param>
        /// <returns>Returns angle in decimal degrees.</returns>
        public static double ToDegrees(double radians) { return radians * (180d / Math.PI); }
    }
    /// <summary>
    /// Projection Engine Singleton for ArcGIS Explorer
    /// </summary>
    public sealed class ProjectionEngineExplorer : ProjectionEngine {
        private static ProjectionEngineExplorer projectionEngine;
        //
        // PUBLIC METHODS
        //
        public static ProjectionEngineExplorer GetInstance() {
            if (projectionEngine == null) {
                projectionEngine = new ProjectionEngineExplorer();
            }
            return projectionEngine;
        }
        public override string DLLPath {
            get {
                RegistryKey coreRuntime = Registry.LocalMachine.OpenSubKey(
                    @"SOFTWARE\ESRI\E2\CoreRuntime", false);
                object installDir = coreRuntime.GetValue("InstallDir", null);
                coreRuntime.Close();
                string folder = installDir.ToString();
                string bin = Path.Combine(folder, "bin");
                string pedll = Path.Combine(bin, "pe.dll");
                return pedll;
            }
        }
    }
    /// <summary>
    /// Projection Engine Singleton for ArcGIS Desktop
    /// </summary>
    public sealed class ProjectionEngineDesktop : ProjectionEngine {
        private static ProjectionEngineDesktop projectionEngine;
        //
        // PUBLIC METHODS
        //
        public static ProjectionEngineDesktop GetInstance() {
            if (projectionEngine == null) {
                projectionEngine = new ProjectionEngineDesktop();
            }
            return projectionEngine;
        }
        public override string DLLPath {
            get {
                RegistryKey coreRuntime = Registry.LocalMachine.OpenSubKey(
                    @"SOFTWARE\ESRI\CoreRuntime", false);
                object installDir = coreRuntime.GetValue("InstallDir", null);
                coreRuntime.Close();
                string folder = installDir.ToString();
                string bin = Path.Combine(folder, "bin");
                string pedll = Path.Combine(bin, "pe.dll");
                return pedll;
            }
        }
    }
}