private void Window_Loaded(object sender, RoutedEventArgs e)
        {
            Room room = new Room();

            Tracker tracker = new Tracker("kinect", new Point(10, 10), 225, 15);
            room.AddTracker(tracker);

            //double angle = 180.0;
            //double fov = 190;

            //room.AddDevice(new Device("one", new Point(5, 0), angle, fov));
            //room.AddDevice(new Device("two", new Point(10, 0), angle, fov));
            //room.AddDevice(new Device("three", new Point(15, 0), angle, fov));
            //room.AddDevice(new Device("four", new Point(10, 5), angle, fov));
            //room.AddDevice(new Device("five", new Point(10, -5), angle, fov));

            //Debug.WriteLine(room.GetDevicesInViewOf(room.GetDevice("one")).Count);
            //Debug.WriteLine(room.GetDevicesInViewOf(room.GetDevice("two")).Count);
            //Debug.WriteLine(room.GetDevicesInViewOf(room.GetDevice("three")).Count);
            //Debug.WriteLine(room.GetDevicesInViewOf(room.GetDevice("four")).Count);
            //Debug.WriteLine(room.GetDevicesInViewOf(room.GetDevice("five")).Count);

            Device dev = new Device("dev");
            room.AddDevice(dev);
            tracker.UpdatePositionForDevice(dev, new Vector(-20,0));
            Debug.Write(dev.Location.X + " " + dev.Location.Y);
        }
Exemplo n.º 2
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        public List<Device> GetDevicesInViewOf(Device observer)
        {
            // We imagine the field of view as two vectors, pointing away from the observing device. Targets between the vectors are in view.
            // We will use angles to represent these vectors.
            double leftFieldOfView = Util.NormalizeAngle(observer.Orientation + observer.FieldOfView / 2);
            double rightFieldOfView = Util.NormalizeAngle(observer.Orientation - observer.FieldOfView / 2);

            List<Device> returnDevices = new List<Device>();

            if (observer.FieldOfView == 0.0)
                return returnDevices;

            foreach (Device target in devices.Values)
            {
                if (target.Name == observer.Name)
                    continue;

                // Atan2 is the inverse tangent function, given lengths for the opposite and adjacent legs of a right triangle, it returns the angle
                double angle = Util.NormalizeAngle(Math.Atan2(target.Location.Y - observer.Location.Y, target.Location.X - observer.Location.X) * 180/Math.PI);

                // Ordinarily, the angle defining the left boundary of the field of view will be larger than the angle for the right.
                // For example, if our devices has orientation of 90.0 and a field of view of 15 degrees, then the left and right FoVs are 97.5 and 82.5 degrees
                // In this case, the target must be at an angle between left and right to be in view.
                if (leftFieldOfView > rightFieldOfView && angle < leftFieldOfView && angle > rightFieldOfView)
                {
                    returnDevices.Add(target);
                }
                // If the field of view includes the X axis, then the left field of view will be smaller than the right field of view.
                // For example, if our device has an orientation of 0.0 and a field of view of 15 degrees, then the left FoV vector will be at 7.5 degrees
                // and the right FoV will be at 352.5 degrees.
                else if (leftFieldOfView < rightFieldOfView)
                {
                    if(angle < leftFieldOfView || angle > rightFieldOfView)
                        returnDevices.Add(target);
                }

            }

            return returnDevices;
        }
        /// <summary>
        /// Initializes a new instance of the MainWindow class.
        /// </summary>
        public MainWindow()
        {
            InitializeComponent();

            nearX = 1000;
            nearY = 1000;
            nearZ = 1000;

            farX = 0;
            farY = 0;
            farZ = 0;

            myRoom = new Room();

            myTracker = new Tracker("myKinect", new Point(0, 2.5), 0.0, 15);
            myRoom.AddTracker(myTracker);

            myDevice = new Device("me");
            myRoom.AddDevice(myDevice);
        }
Exemplo n.º 4
0
 public void RemoveDevice(Device device)
 {
     devices.Remove(device.Name);
 }
Exemplo n.º 5
0
 public void AddDevice(Device device)
 {
     devices.Add(device.Name, device);
 }
 public void UpdatePositionForDevice(Device device, SkeletonPoint skeletonPoint)
 {
     Vector updatedPosition = Util.TranslateFromCoordinateSpace(new Vector(skeletonPoint.Z, skeletonPoint.X), Orientation, new Vector(Location.X, Location.Y));
     device.Location = new Point(updatedPosition.X, updatedPosition.Y);
 }
 // Accepts a point in the Tracker's coordinate space, translates this into the room's coordinate space using the Tracker's position and orientation, and updates the location of the device with it.
 // In the Tracker's coordinate space, it is at the origin and with orientation 0 (facing down the X axis).
 // In the Kinect's coordinate space, it is at 0.0, and faces down the Z axis.
 // Left-right movement in front of the camera is mapped to the X axis, and vertical movement is mapped to the Y axis.
 // So, the Kinect's Z axis corresponds to the Tracker's X axis, and the Kinect's X axis corresponds to the Tracker's Y axis.
 // To translate from the Kinect's coordinate space, you want to pass a new Vector(SkeletonPoint.Z, SkeletonPoint.X).
 public void UpdatePositionForDevice(Device device, Vector vector)
 {
     Vector updatedPosition = Util.TranslateFromCoordinateSpace(vector, Orientation, new Vector(Location.X, Location.Y));
     device.Location = new Point(updatedPosition.X, updatedPosition.Y);
 }
        private void Window_Loaded(object sender, RoutedEventArgs e)
        {
            // Create the drawing group we'll use for drawing
            this.drawingGroup = new DrawingGroup();

            // Create an image source that we can use in our image control
            this.imageSource = new DrawingImage(this.drawingGroup);

            // Display the drawing using our image control
            Image.Source = this.imageSource;

            // Look through all sensors and start the first connected one.
            // This requires that a Kinect is connected at the time of app startup.
            // To make your app robust against plug/unplug,
            // it is recommended to use KinectSensorChooser provided in Microsoft.Kinect.Toolkit
            foreach (var potentialSensor in KinectSensor.KinectSensors)
            {
                if (potentialSensor.Status == KinectStatus.Connected)
                {
                    this.sensor = potentialSensor;
                    break;
                }
            }

            if (null != this.sensor)
            {
                // Turn on the skeleton stream to receive skeleton frames
                this.sensor.SkeletonStream.Enable();

                // Add an event handler to be called whenever there is new color frame data
                this.sensor.SkeletonFrameReady += this.SensorSkeletonFrameReady;

                // Start the sensor!
                try
                {
                    this.sensor.Start();
                }
                catch (IOException)
                {
                    this.sensor = null;
                }
            }

            if (null == this.sensor)
            {
                MessageBox.Show("No Kinect");
                //this.statusBarText.Text = Properties.Resources.NoKinectReady;
            }

            room = new Room();
            tracker = new Tracker("kinect", new Point(2.25, yRange), 270.0);
            room.AddTracker(tracker);

            devices = new Device[6];
            for (int i = 0; i < 6; i++)
            {
                devices[i] = new Device(i.ToString());

                if (i % 2 == 1)
                    devices[i].Orientation = 0;
                else
                    devices[i].Orientation = 180.0;

                room.AddDevice(devices[i]);
            }
        }
        public void CoordinateTranslationTest()
        {
            Room r = new Room();

            Tracker t = new Tracker("myKinect", new Point(5, 5), 270);
            r.AddTracker(t);

            Device one = new Device("one");
            Device two = new Device("two");
            Device three = new Device("three");

            r.AddDevice(one);
            r.AddDevice(two);
            r.AddDevice(three);

            t.UpdatePositionForDevice(one, new Vector(1, 1));
            t.UpdatePositionForDevice(two, new Vector(5, 0));
            t.UpdatePositionForDevice(three, new Vector(3, -3));

            Assert.AreEqual(one.Location.X, 6, 0.001);
            Assert.AreEqual(one.Location.Y, 4, 0.001);

            Assert.AreEqual(two.Location.X, 5, 0.001);
            Assert.AreEqual(two.Location.Y, 0, 0.001);

            Assert.AreEqual(three.Location.X, 2, 0.001);
            Assert.AreEqual(three.Location.Y, 2, 0.001);

            // test of translation alone
            Tracker t2 = new Tracker("kinect2", new Point(0, -10), 0.0);
            r.AddTracker(t2);

            t2.UpdatePositionForDevice(one, new Vector(6, 14));
            t2.UpdatePositionForDevice(two, new Vector(5, 10));
            t2.UpdatePositionForDevice(three, new Vector(2, 12));

            Assert.AreEqual(one.Location.X, 6, 0.001);
            Assert.AreEqual(one.Location.Y, 4, 0.001);

            Assert.AreEqual(two.Location.X, 5, 0.001);
            Assert.AreEqual(two.Location.Y, 0, 0.001);

            Assert.AreEqual(three.Location.X, 2, 0.001);
            Assert.AreEqual(three.Location.Y, 2, 0.001);

            //test of rotation alone
            Tracker t3 = new Tracker("kinect3", new Point(0, 0), 135);

            t3.UpdatePositionForDevice(one, new Vector(-1.425, -7.0678));
            t3.UpdatePositionForDevice(two, new Vector(-3.535, -3.535));
            t3.UpdatePositionForDevice(three, new Vector(0, -Math.Sqrt(8)));

            Assert.AreEqual(one.Location.X, 6, 0.01); // to deal with horrible horrible rounding error introduced by hardcoded positions just above
            Assert.AreEqual(one.Location.Y, 4, 0.01);

            Assert.AreEqual(two.Location.X, 5, 0.001);
            Assert.AreEqual(two.Location.Y, 0, 0.001);

            Assert.AreEqual(three.Location.X, 2, 0.001);
            Assert.AreEqual(three.Location.Y, 2, 0.001);
        }