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Java Sample TensorFlow Object Detection Op Mode
Note: A Freight Frenzy update to this page's Sample Op Mode is available here.
You can use the sample "ConceptTensorFlowObjectDetection" as a template to create your own Java op mode that uses the TensorFlow technology to "look for" any game elements, and determine the relative location of any identified elements.
- If you are using a REV Control Hub with an externally connected webcam as your Robot Controller, select "ConceptTensorFlowObjectDetectionWebcam" as the sample op mode from the dropdown list in the New File dialog box.
- If you are using an Android smartphone as your Robot Controller, select "ConceptTensorFlowObjectDetection" as the sample op mode from the dropdown list in the New File dialog box.
Press "OK" to create the new op mode.
Create an Op Mode with ConceptTensorFlowObjectDetection as its template.
Your new op mode should appear in the editing pane of the OnBot Java screen.
Your newly created op mode should be available for editing through OnBot Java.
Let's take a look at the initial statements in the op mode. Before you start, you must first make sure you have a valid Vuforia developer license key to initialize the Vuforia software. You can obtain a key for free from https://developer.vuforia.com/license-manager. Once you obtain your key, replace the VUFORIA_KEY static String with the actual license key so the Vuforia software will be able to initialize properly.
private static final String VUFORIA_KEY =
" -- YOUR NEW VUFORIA KEY GOES HERE --- ";
Also, by default the op mode is disabled. Comment out the "@Disabled" annotation to enable your newly created op mode.
@TeleOp(name = "Concept: TensorFlow Object Detection", group = "Concept")
//@Disabled
public class MyTensorFlowExample extends LinearOpMode {
Since TensorFlow will receive image data from Vuforia, the op mode attempts to create and initialize a VuforiaLocalizer object by calling the function called "initVuforia()":
// The TFObjectDetector uses the camera frames from the VuforiaLocalizer, so we create that
// first.
initVuforia();
initTfod();
You can initialize both the Vuforia and the TensorFlow libraries in the same op mode. This is useful, for example, if you would like to use the TensorFlow library to determine the ring stack and then use the Vuforia library to help the robot autonomously navigate on the game field to navigate to the appropriate target zone from its starting position.
In this example op mode, however, the initVuforia() function does not load any trackable image targets.
/**
* Initialize the Vuforia localization engine.
*/
private void initVuforia() {
/*
* Configure Vuforia by creating a Parameter object, and passing it to the Vuforia engine.
*/
VuforiaLocalizer.Parameters parameters = new VuforiaLocalizer.Parameters();
parameters.vuforiaLicenseKey = VUFORIA_KEY;
parameters.cameraDirection = CameraDirection.BACK;
// Instantiate the Vuforia engine
vuforia = ClassFactory.getInstance().createVuforia(parameters);
// Loading trackables is not necessary for the TensorFlow Object Detection engine.
}
After the Vuforia localizer is initialized, the op mode calls a method initTfod(). This method initializes the TensorFlow Object Detection engine.
/**
* Initialize the TensorFlow Object Detection engine.
*/
private void initTfod() {
int tfodMonitorViewId = hardwareMap.appContext.getResources().getIdentifier(
"tfodMonitorViewId", "id", hardwareMap.appContext.getPackageName());
TFObjectDetector.Parameters tfodParameters = new TFObjectDetector.Parameters(tfodMonitorViewId);
tfodParameters.minResultConfidence = 0.8f;
tfod = ClassFactory.getInstance().createTFObjectDetector(tfodParameters, vuforia);
tfod.loadModelFromAsset(TFOD_MODEL_ASSET, LABEL_FIRST_ELEMENT, LABEL_SECOND_ELEMENT);
}
Note that by default, when you create a new TensorFlow object detector, an object tracker is used, in addition to the TensorFlow interpreter, to keep track of the locations of detected objects. The object tracker interpolates object recognitions so that results are smoother than they would be if the system were to solely rely on the TensorFlow interpreter.
If you want to turn off the object tracker, then you can set the useObjectTracker variable of the tfodParameters object to false before you create the TensorFlow object detector.
// set useObjectTracker to false to disable object tracker.
tfodParameters.useObjectTracker = false;
Also note that the by default, the minimum detection confidence level is set to 80%. This means that the TensorFlow library needs to have a confidence level of 80% or higher in order to consider an object as being detected in its field of view. You can adjust this parameter to a higher value if you would like the system to be more selective in identifying an object.
tfodParameters.minResultConfidence = 0.8f;
After the TensorFlow Object Detector is created it loads the TensorFlow model data
tfod.loadModelFromAsset(TFOD_MODEL_ASSET, LABEL_FIRST_ELEMENT, LABEL_SECOND_ELEMENT);
The arguments TFOD_MODEL_ASSET, LABEL_FIRST_ELEMENT, LABEL_SECOND_ELEMENT are defined earlier in the op mode and are season specific.
private static final String TFOD_MODEL_ASSET = "UltimateGoal.tflite";
private static final String LABEL_FIRST_ELEMENT = "Quad";
private static final String LABEL_SECOND_ELEMENT = "Single";
If a camera monitor window is enabled for the TensorFlow library, then the confidence level for a detected target will be displayed near the bounding box of the identified object (when the object tracker is enabled). For example, a value of "0.92" indicates a 92% confidence that the object has been identified correctly.
When an object is identified by the TensorFlow library, the op mode can read the "Left", "Right", "Top" and "Bottom" values associated with the detected object. These values correspond to the location of the left, right, top and bottom boundaries of the detection box for that object. These values are in pixel coordinates of the image from the camera.
The origin of the coordinate system is in the upper left-hand corner of the image. The horizontal (x) coordinate value increases as you move from the left to the right of the image. The vertical (y) coordinate value increases as you move from the top to the bottom of the image.
The origin of the image coordinate system is located in upper left hand corner.
In the landscape image above, the approximate coordinate values for the Left, Top, Right, and Bottom boundaries are 455, 191, 808, and 547 respectively (pixel coordinates). The width and height for the landscape image above is 1280 and 720 respectively.
In this example, the op mode activates the TensorFlow object detector before waiting for the start command from the Driver Station. This is done so that the user can access the "Camera Stream" preview from the Driver Station menu while it waits for the start command. Also note that in this example, the op mode does not activate the Vuforia tracking feature, it only activates TensorFlow object detection. If you want to incorporate Vuforia image detection and tracking you will also need to activate (and later deactivate when you are done) the Vuforia tracking feature.
/**
* Activate TensorFlow Object Detection before we wait for the start command.
* Do it here so that the Camera Stream window will have the TensorFlow annotations visible.
**/
if (tfod != null) {
tfod.activate();
// The TensorFlow software will scale the input images from the camera to a lower resolution.
// This can result in lower detection accuracy at longer distances (> 55cm or 22").
// If your target is at distance greater than 50 cm (20") you can adjust the magnification value
// to artificially zoom in to the center of image. For best results, the "aspectRatio" argument
// should be set to the value of the images used to create the TensorFlow Object Detection model
// (typically 16/9).
tfod.setZoom(2.5, 16.0/9.0);
}
When TensorFlow receives an image from the robot's camera, the library downgrades the resolution of the image (presumably to achieve a higher detection rate). As a result, if a target is at a distance of around 24" (61cm) or more, the detection accuracy of the system tends to diminish. This degradation can occur, even if you have a very accurate inference model.
You can specify a zoom factor in your op mode to offset the effect of this automatic scaling by the TensorFlow library. If you specify a zoom factor, the image will be cropped by this factor and this artificially magnified image will be passed to the TensorFlow library. The net result is that the robot is able to detect and track an object at a significantly larger distance. The webcams and built-in Android cameras that are typically used by FTC teans have high enough resolution to allow TensorFlow to "see" an artificially magnified target clearly.
// The TensorFlow software will scale the input images from the camera to a lower resolution.
// This can result in lower detection accuracy at longer distances (> 55cm or 22").
// If your target is at distance greater than 50 cm (20") you can adjust the magnification value
// to artificially zoom in to the center of image. For best results, the "aspectRatio" argument
// should be set to the value of the images used to create the TensorFlow Object Detection model
// (typically 16/9).
tfod.setZoom(2.5, 16.0/9.0);
If a zoom factor has been set, then the Camera Stream preview on the Driver Station will show the cropped area that makes up the artificially magnified image.
Camera stream preview indicating magnified area (at a distance of about 4 feet or 1.2 meters).
The op mode will then iterate until a Stop command is received. At the beginning of each iteration, the op mode will check with the object detector to see how many objects it recognizes in its field of view. In the screenshot below, the variable "updatedRecognitions" is set to a list of objects that were recognized using the TensorFlow technology.
if (opModeIsActive()) {
while (opModeIsActive()) {
if (tfod != null) {
// getUpdatedRecognitions() will return null if no new information is available since
// the last time that call was made.
List<Recognition> updatedRecognitions = tfod.getUpdatedRecognitions();
if (updatedRecognitions != null) {
telemetry.addData("# Object Detected", updatedRecognitions.size());
// step through the list of recognitions and display boundary info.
int i = 0;
for (Recognition recognition : updatedRecognitions) {
telemetry.addData(String.format("label (%d)", i), recognition.getLabel());
telemetry.addData(String.format(" left,top (%d)", i), "%.03f , %.03f",
recognition.getLeft(), recognition.getTop());
telemetry.addData(String.format(" right,bottom (%d)", i), "%.03f , %.03f",
recognition.getRight(), recognition.getBottom());
}
telemetry.update();
}
}
}
}
If the list is not empty, then the op mode iterates through the list and sends information via telemetry about each detected object.
Let's modify the sample op mode so it will indicate which target zone the robot should drive to. Using the OnBot Java editor, modify the example code so it looks like the following sample. Specifically, you want the op mode to check the size of the updatedRecognitions list. If the size is zero, then no objects were detected and the op mode should send a telemetry message indicating that no objects were detected and the target zone is zone A.
if (opModeIsActive()) {
while (opModeIsActive()) {
if (tfod != null) {
// getUpdatedRecognitions() will return null if no new information is available since
// the last time that call was made.
List<Recognition> updatedRecognitions = tfod.getUpdatedRecognitions();
if (updatedRecognitions != null) {
telemetry.addData("# Object Detected", updatedRecognitions.size());
if (updatedRecognitions.size() == 0 ) {
// empty list. no objects recognized.
telemetry.addData("TFOD", "No items detected.");
telemetry.addData("Target Zone", "A");
} else {
// list is not empty.
// step through the list of recognitions and display boundary info.
int i = 0;
for (Recognition recognition : updatedRecognitions) {
telemetry.addData(String.format("label (%d)", i), recognition.getLabel());
telemetry.addData(String.format(" left,top (%d)", i), "%.03f , %.03f",
recognition.getLeft(), recognition.getTop());
telemetry.addData(String.format(" right,bottom (%d)", i), "%.03f , %.03f",
recognition.getRight(), recognition.getBottom());
// check label to see which target zone to go after.
if (recognition.getLabel().equals("Single")) {
telemetry.addData("Target Zone", "B");
} else if (recognition.getLabel().equals("Quad")) {
telemetry.addData("Target Zone", "C");
} else {
telemetry.addData("Target Zone", "UNKNOWN");
}
}
}
telemetry.update();
}
}
}
}
Also, when an object is detected, the op mode should check the object's label to see which target zone is associated with that object. If the label reads "Single" then send a telemetry message to indicate target zone B. If the label reads "Quad" then send a telemetry message to indicate target zone C. If the label is neither "Single" or "Quad" send a telemetry message indicating that the target zone is unknown.
Note that in this example, since the op mode iterates through the list of recognized objects, the target zone will be displayed for each recognized object in the list.
Rebuild the OnBot Java op mode and re-run it. The op mode should display the target zone for each object in its list of recognized objects. Note that if you test this op mode with multiple ring stacks, the order of the detected objects can change with each iteration of your op mode.
The modified op mode should indicate target zone for each recognized object in its list.
If you are using a webcam with your Robot Controller, then the camera orientation is fixed in landscape mode. However, if you are using a smartphone camera, the system will interpret images based on the phone's orientation (Portrait or Landscape) at the time that the TensorFlow object detector is created and initialized.
Note that for the Ultimate Goal presented by QualComm Challenge, the default TensorFlow inference model is optimized for a camera in landscape mode. This means that it is better to orient your camera in landscape mode if you use this default inference model because you will get more reliable detections.
In our example, if you execute the TensorFlowObjectDetectionUltimateGoal.initialize block while the phone is in Portrait mode, then the images will be processed in Portrait mode.
If you initialize the detector in Portrait mode, then the images are processed in Portrait mode.
The "Left" and "Right" values of an object's bounding box correspond to horizontal coordinate values, while the "Top" and "Bottom" values of an object's bounding box correspond to vertical coordinate values.
The "Left" and "Top" boundaries of a detection box when the image is in Portrait mode.
If you want to use your smartphone in Landscape mode, then make sure that your phone is in Landscape mode when the TensorFlow object detector is initialized. Landscape mode is preferable for this season's game since it offers a wider field of view so that all three minerals can fit in a single image.
The system can also be run in Landscape mode.
If the phone is in Landscape mode when the object detector is initialized, then the images will be interpreted in Landscape mode.
The "Left" and "Top" boundaries of a detection box when the image is in Landscape mode.
Note that Android devices can be locked into Portrait Mode so that the screen image will not rotate even if the phone is held in a Landscape orientation. If your phone is locked in Portrait Mode, then the TensorFlow object detector will interpret all images as Portrait images. If you would like to use the phone in Landscape mode, then you need to make sure your phone is set to "Auto-rotate" mode. In Auto-rotate mode, if the phone is held in a Landscape orientation, then the screen will auto rotate to display the contents in Landscape form.
Auto-rotate must be enabled in order to operate in Landscape mode.
When the example op mode is no longer active (i.e., when the user has pressed the stop button on the Driver Station) the op mode will attempt to deactivate the TensorFlow library before it's done. It's important to deactivate the library to free up system resources.
if (tfod != null) {
tfod.shutdown();
}
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