Using Multiple Cameras

Switching the Driver Views

If you’re interested in just switching what the driver sees, and are using SmartDashboard, the SmartDashboard CameraServer Stream Viewer has an option (“Selected Camera Path”) that reads the given NetworkTables key and changes the “Camera Choice” to that value (displaying that camera). The robot code then just needs to set the NetworkTables key to the correct camera name. Assuming “Selected Camera Path” is set to “CameraSelection”, the following code uses the joystick 1 trigger button state to show camera1 and camera2.

UsbCamera camera1;
UsbCamera camera2;
Joystick joy1 = new Joystick(0);
NetworkTableEntry cameraSelection;
@Override
public void robotInit() {
    camera1 = CameraServer.startAutomaticCapture(0);
    camera2 = CameraServer.startAutomaticCapture(1);
    cameraSelection = NetworkTableInstance.getDefault().getTable("").getEntry("CameraSelection");
}
@Override
public void teleopPeriodic() {
    if (joy1.getTriggerPressed()) {
        System.out.println("Setting camera 2");
        cameraSelection.setString(camera2.getName());
    } else if (joy1.getTriggerReleased()) {
        System.out.println("Setting camera 1");
        cameraSelection.setString(camera1.getName());
    }
}
cs::UsbCamera camera1;
cs::UsbCamera camera2;
frc::Joystick joy1{0};
nt::NetworkTableEntry cameraSelection;
void RobotInit() override {
  camera1 = frc::CameraServer::StartAutomaticCapture(0);
  camera2 = frc::CameraServer::StartAutomaticCapture(1);
  cameraSelection = nt::NetworkTableInstance::GetDefault().GetTable("")->GetEntry("CameraSelection");
}
void TeleopPeriodic() override {
  if (joy1.GetTriggerPressed()) {
    std::cout << "Setting Camera 2" << std::endl;
    cameraSelection.SetString(camera2.GetName());
  } else if (joy1.GetTriggerReleased()) {
    std::cout << "Setting Camera 1" << std::endl;
    cameraSelection.SetString(camera1.GetName());
  }
}

Note

Python requires you to place your image processing code in a separate file from your robot code. You can create robot.py and vision.py in the same directory.

robot.py contents:

import wpilib
from ntcore import NetworkTableInstance
class MyRobot(wpilib.TimedRobot):
    def robotInit(self):
        self.joy1 = wpilib.Joystick(0)
        self.cameraSelection = NetworkTableInstance.getDefault().getTable("").getEntry("CameraSelection")
        wpilib.CameraServer.launch("vision.py:main")
    def teleopPeriodic(self):
        if self.joy1.getTriggerPressed():
            print("Setting camera 2")
            self.cameraSelection.setString("USB Camera 1")
        elif self.joy1.getTriggerReleased():
            print("Setting camera 1")
            self.cameraSelection.setString("USB Camera 0")

vision.py contents:

from cscore import CameraServer
def main():
    CameraServer.enableLogging()
    camera1 = CameraServer.startAutomaticCapture(0)
    camera2 = CameraServer.startAutomaticCapture(1)
    CameraServer.waitForever()

pyproject.toml contents (this only shows the portions you need to update):

[tool.robotpy]
...
# Add cscore to the robotpy-extras list
robotpy_extras = ["cscore"]

If you’re using some other dashboard, you can change the camera used by the camera server dynamically. If you open a stream viewer nominally to camera1, the robot code will change the stream contents to either camera1 or camera2 based on the joystick trigger.

UsbCamera camera1;
UsbCamera camera2;
VideoSink server;
Joystick joy1 = new Joystick(0);
@Override
public void robotInit() {
    camera1 = CameraServer.startAutomaticCapture(0);
    camera2 = CameraServer.startAutomaticCapture(1);
    server = CameraServer.getServer();
}
@Override
public void teleopPeriodic() {
    if (joy1.getTriggerPressed()) {
        System.out.println("Setting camera 2");
        server.setSource(camera2);
    } else if (joy1.getTriggerReleased()) {
        System.out.println("Setting camera 1");
        server.setSource(camera1);
    }
}
cs::UsbCamera camera1;
cs::UsbCamera camera2;
cs::VideoSink server;
frc::Joystick joy1{0};
bool prevTrigger = false;
void RobotInit() override {
  camera1 = frc::CameraServer::StartAutomaticCapture(0);
  camera2 = frc::CameraServer::StartAutomaticCapture(1);
  server = frc::CameraServer::GetServer();
}
void TeleopPeriodic() override {
  if (joy1.GetTrigger() && !prevTrigger) {
    std::cout << "Setting Camera 2" << std::endl;
    server.SetSource(camera2);
  } else if (!joy1.GetTrigger() && prevTrigger) {
    std::cout << "Setting Camera 1" << std::endl;
    server.SetSource(camera1);
  }
  prevTrigger = joy1.GetTrigger();
}
# Setting the source directly via joystick isn't possible in Python, you
# should use NetworkTables as shown above instead

Keeping Streams Open

By default, the cscore library is pretty aggressive in turning off cameras not in use. What this means is that when you switch cameras, it may disconnect from the camera not in use, so switching back will have some delay as it reconnects to the camera. To keep both camera connections open, use the SetConnectionStrategy() method to tell the library to keep the streams open, even if you aren’t using them.

UsbCamera camera1;
UsbCamera camera2;
VideoSink server;
Joystick joy1 = new Joystick(0);
@Override
public void robotInit() {
    camera1 = CameraServer.startAutomaticCapture(0);
    camera2 = CameraServer.startAutomaticCapture(1);
    server = CameraServer.getServer();
    camera1.setConnectionStrategy(ConnectionStrategy.kKeepOpen);
    camera2.setConnectionStrategy(ConnectionStrategy.kKeepOpen);
}
@Override
public void teleopPeriodic() {
    if (joy1.getTriggerPressed()) {
        System.out.println("Setting camera 2");
        server.setSource(camera2);
    } else if (joy1.getTriggerReleased()) {
        System.out.println("Setting camera 1");
        server.setSource(camera1);
    }
}
cs::UsbCamera camera1;
cs::UsbCamera camera2;
cs::VideoSink server;
frc::Joystick joy1{0};
bool prevTrigger = false;
void RobotInit() override {
  camera1 = frc::CameraServer::StartAutomaticCapture(0);
  camera2 = frc::CameraServer::StartAutomaticCapture(1);
  server = frc::CameraServer::GetServer();
  camera1.SetConnectionStrategy(cs::VideoSource::ConnectionStrategy::kConnectionKeepOpen);
  camera2.SetConnectionStrategy(cs::VideoSource::ConnectionStrategy::kConnectionKeepOpen);
}
void TeleopPeriodic() override {
  if (joy1.GetTrigger() && !prevTrigger) {
    std::cout << "Setting Camera 2" << std::endl;
    server.SetSource(camera2);
  } else if (!joy1.GetTrigger() && prevTrigger) {
    std::cout << "Setting Camera 1" << std::endl;
    server.SetSource(camera1);
  }
  prevTrigger = joy1.GetTrigger();
}

Note

Python requires you to place your image processing code in a separate file from your robot code. You can create robot.py and vision.py in the same directory.

robot.py contents:

import wpilib
from ntcore import NetworkTableInstance
class MyRobot(wpilib.TimedRobot):
    def robotInit(self):
        self.joy1 = wpilib.Joystick(0)
        self.cameraSelection = NetworkTableInstance.getDefault().getTable("").getEntry("CameraSelection")
        wpilib.CameraServer.launch("vision.py:main")
    def teleopPeriodic(self):
        if self.joy1.getTriggerPressed():
            print("Setting camera 2")
            self.cameraSelection.setString("USB Camera 1")
        elif self.joy1.getTriggerReleased():
            print("Setting camera 1")
            self.cameraSelection.setString("USB Camera 0")

vision.py contents:

from cscore import CameraServer, VideoSource
    def main():
    CameraServer.enableLogging()
    camera1 = CameraServer.startAutomaticCapture(0)
    camera2 = CameraServer.startAutomaticCapture(1)
    camera1.setConnectionStrategy(VideoSource.ConnectionStrategy.kConnectionKeepOpen)
    camera2.setConnectionStrategy(VideoSource.ConnectionStrategy.kConnectionKeepOpen)
        CameraServer.waitForever()

pyproject.toml contents (this only shows the portions you need to update):

[tool.robotpy]
...
# Add cscore to the robotpy-extras list
robotpy_extras = ["cscore"]

Note

If both cameras are USB, you may run into USB bandwidth limitations with higher resolutions, as in all of these cases the roboRIO is going to be streaming data from both cameras to the roboRIO simultaneously (for a short period in options 1 and 2, and continuously in option 3). It is theoretically possible for the library to avoid this simultaneity in the option 2 case (only), but this is not currently implemented.

Different cameras report bandwidth usage differently. The library will tell you if you’re hitting the limit; you’ll get this error message:

could not start streaming due to USB bandwidth limitations;
try a lower resolution or a different pixel format
(VIDIOC_STREAMON: No space left on device)

If you’re using Option 3 it will give you this error during RobotInit(). Thus you should just try your desired resolution and adjusting as necessary until you both don’t get that error and don’t exceed the radio bandwidth limitations.