int wam_main(int argc, char** argv, ProductManager& pm, systems::Wam<DOF>& wam) {
	wam.gravityCompensate();
	printMenu();

	std::string line;
	bool going = true;
	while (going) {
		printf(">>> ");
		std::getline(std::cin, line);

		switch (line[0]) {
		case 'j':
			printf("Holding joint positions.\n");
			wam.moveTo(wam.getJointPositions());
			break;

		case 'p':
			printf("Holding tool position.\n");
			wam.moveTo(wam.getToolPosition());
			break;

		case 'o':
			printf("Holding tool orientation.\n");
			wam.moveTo(wam.getToolOrientation());
			break;

		case 'b':
			printf("Holding both tool position and orientation.\n");
			wam.moveTo(wam.getToolPose());
			break;

		case 'i':
			printf("WAM idled.\n");

			// Note that this use of the word "idle" does not mean "Shift-idle".
			// Calling Wam::idle() will disable any of the controllers that may
			// be connected (joint position, tool position, tool orientation,
			// etc.) leaving only gravity compensation. (More specifically,
			// Wam::idle() disconnects any inputs that were connected using
			// Wam::trackReferenceSignal().)
			wam.idle();
			break;

		case 'q':
		case 'x':
			printf("Quitting.\n");
			wam.moveHome();
			going = false;
			break;

		default:
			if (line.size() != 0) {
				printf("Unrecognized option.\n");
				printMenu();
			}
			break;
		}
	}

	// Release the WAM if we're holding. This is convenient because it allows
	// users to move the WAM back to some collapsed position before exiting, if
	// they want.
	wam.idle();

	// Wait for the user to press Shift-idle
	pm.getSafetyModule()->waitForMode(SafetyModule::IDLE);
	return 0;
}
  int wam_main(int argc, char** argv, ProductManager& pm, systems::Wam<DOF>& wam)
  {
    BARRETT_UNITS_TEMPLATE_TYPEDEFS(DOF);

    cp_type cartSetPoint;
    wam.gravityCompensate();

    /////////////////////////////////////////////////////////////////////////////////////
    // Add the following to our system to make our Cartesian controller much more robust.
    /////////////////////////////////////////////////////////////////////////////////////

    // Set up singularity avoidance springs
    jp_type joint_center(0.0); // Initialize our joint centers to 0.0 on all joints
    std::vector<double> spring_constants(DOF); // create spring constants
    std::vector<double> damping_constants(DOF); // create damping constants
    joint_center[0] = 0.0;
    joint_center[1] = 0.0;
    joint_center[2] = 0.0;
    joint_center[3] = 1.1; // J4 Joint Range Center at 1.1 Radians
    spring_constants[0] = 15.0;
    spring_constants[1] = 5.0;
    spring_constants[2] = 5.0;
    spring_constants[3] = 5.0;
    damping_constants[0] = 10.0;
    damping_constants[1] = 20.0;
    damping_constants[2] = 10.0;
    damping_constants[3] = 6.0;

    if (DOF == 7)
    {
      joint_center[4] = -1.76; // J5 Joint Range Center at -1.76 Radians
      joint_center[5] = 0.0;
      joint_center[6] = 0.0;
      spring_constants[4] = 0.5;
      spring_constants[5] = 0.25;
      spring_constants[6] = 0.25;
      damping_constants[4] = 0.05;
      damping_constants[5] = 0.05;
      damping_constants[6] = 0.0;
    }

    printf("Press Enter to Turn on Haptic Singularity Avoidance.\n");
    detail::waitForEnter();

    //Initialization Move
    jp_type wam_init = wam.getHomePosition();
    wam_init[3] -= .35;
    wam.moveTo(wam_init); // Adjust the elbow, moving the end-effector out of the haptic boundary and hold position for haptic force initialization.

    // Change decrease our tool position controller gains slightly
    cp_type cp_kp, cp_kd;
    for (size_t i = 0; i < 3; i++)
    {
      cp_kp[i] = 1500;
      cp_kd[i] = 5.0;
    }
    wam.tpController.setKp(cp_kp);
    wam.tpController.setKd(cp_kd);

    //Torque Summer from our three systems
    systems::Summer<jt_type, 4> singJTSum(true);

    // Our singularity avoidance system
    SingularityAvoid<DOF> singularityAvoid(joint_center);
    systems::connect(wam.jpOutput, singularityAvoid.input);
    systems::connect(singularityAvoid.output, singJTSum.getInput(0));

    // Attach our joint stop springs
    JointStopSprings<DOF> jointStopSprings(joint_center, spring_constants);
    systems::connect(wam.jpOutput, jointStopSprings.input);
    systems::connect(jointStopSprings.output, singJTSum.getInput(1));

    // Joint velocity damper for kinematic solutions causing velocity faults
    JVDamper<DOF> jvDamper(damping_constants);
    systems::connect(wam.jvOutput, jvDamper.input);
    systems::connect(jvDamper.output, singJTSum.getInput(2));

    // Haptic collision avoidance boundary portion
    HapticCollisionAvoid<DOF> hapticCollisionAvoid(2000);
    systems::ToolForceToJointTorques<DOF> tf2jt;
    systems::connect(wam.kinematicsBase.kinOutput, tf2jt.kinInput);
    systems::connect(wam.toolPosition.output, hapticCollisionAvoid.input);
    systems::connect(hapticCollisionAvoid.output, tf2jt.input);
    systems::connect(tf2jt.output, singJTSum.getInput(3));

    systems::connect(singJTSum.output, wam.input);

    // New system watchdogs to monitor and stop trajectories if expecting a fault
    TorqueWatchdog<DOF> torqueWatchdog;
    VelocityWatchdog<DOF> velocityWatchdog;
    pm.getExecutionManager()->startManaging(torqueWatchdog);
    pm.getExecutionManager()->startManaging(velocityWatchdog);

    systems::connect(wam.jtSum.output, torqueWatchdog.input);
    systems::connect(wam.jvOutput, velocityWatchdog.input);

    /////////////////////////////////////////////////////////////////////////////////////
    // End of robust cartesian setup
    /////////////////////////////////////////////////////////////////////////////////////

    printf("Press Enter to start test.\n");
    detail::waitForEnter();

    int i;
    for (i = 1; i < 31; i++) //from random.cc
    {
      srand(time(NULL));
      double x = -1 + 2 * ((double)rand()) / RAND_MAX;
      double y = -1 + 2 * (((double)rand()) / ((double)RAND_MAX));
      double z = ((double)rand()) / ((double)RAND_MAX);
      cartSetPoint[0] = x;
      cartSetPoint[1] = y;
      cartSetPoint[2] = z;

      double reach = sqrt(x * x + y * y + z * z);

      if (reach < 0.95)
      {
        std::cout << i << ": Moving to coordinate " << x << ", " << y << ", " << z << ".\n";
        std::cout << reach << "\n";
        wam.moveTo(cartSetPoint, false);
        torqueWatchdog.activate();
        velocityWatchdog.activate(); // The situation here is interesting. A velocity fault can present itself from Cartesian end-effector or elbow velocities,
        // However, in its current capacity, we can only monitor joint velocities, or end-effector velocities.
        bool faulted = false;
        while (!wam.moveIsDone() && !faulted)
        {
          //Check our velocity and torque output to see if crossing threshold (approaching a fault situation)
          jt_type curJT = torqueWatchdog.getCurrentTorque();
          jv_type curJV = velocityWatchdog.getCurrentVelocity();
          for (size_t i = 0; i < DOF; i++)
          {
            if (curJT[i] > 30.0 || curJV[i] > 0.9)
            {
              wam.idle();
              printf("Stopping Move - Fault presented on Joint %zu - Torque: %f, Velocity: %f\n", i, curJT[i],
                     curJV[i]);
              faulted = true;
              wam.moveTo(wam.getJointPositions());
            }
          }
          btsleep(0.01);
        }
        torqueWatchdog.deactivate();
        velocityWatchdog.deactivate();
        continue;
      }
      else
        i--;

      continue;

    }

    systems::disconnect(wam.input);
    wam.moveHome();
    pm.getSafetyModule()->waitForMode(SafetyModule::IDLE);
    return 0;

  }
Exemple #3
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int wam_main(int argc, char** argv, ProductManager& pm, systems::Wam<DOF>& wam) {
	BARRETT_UNITS_TEMPLATE_TYPEDEFS(DOF);

	wam.gravityCompensate();
	bool gComp = true;
	pm.getSafetyModule()->setVelocityLimit(0.3);

	jp_type jp;
	size_t joint = 0;
	systems::ExposedOutput<jp_type> setPoint;

	std::string line;
	bool going = true;
	while (going) {
		printf(">>> ");
		std::getline(std::cin, line);

		if (line.size() == 0) {
			wam.moveTo(jp);

			libconfig::Config config;
			config.readFile("tuning.conf");
			systems::PIDController<jp_type, jt_type> jpc(config.lookup(pm.getWamDefaultConfigPath())["joint_position_control"]);
			systems::connect(setPoint.output, jpc.referenceInput);
			systems::connect(wam.jpOutput, jpc.feedbackInput);

			wam.idle();
			usleep(100000);
			systems::connect(jpc.controlOutput, wam.input);
			printf("Controller updated.\n");

			printf("Press enter for step.\n");
			std::getline(std::cin, line);
			jp[joint] += 0.02;
			setPoint.setValue(jp);

			std::getline(std::cin, line);
			systems::disconnect(wam.input);
			wam.moveTo(jp);
			printf("Original controller now in use.\n");

			continue;
		}

		switch (line[0]) {
		case 'h':
			printf("Set point updated.\n");
			jp = wam.getJointPositions();
			wam.moveTo(jp);
			setPoint.setValue(jp);
			break;

		case 'i':
			printf("WAM idled.\n");
			wam.idle();
			break;

		case 'j':
			joint = (joint + 1) % DOF;
			printf("Step joint %zu.\n", joint+1);
			break;

		case 'g':
			gComp = ! gComp;
			wam.gravityCompensate(gComp);
			break;

		case 'q':
		case 'x':
			printf("Quitting.\n");
			going = false;
			break;

		default:
			printf("Unrecognized option.\n");
			break;
		}
	}


	wam.idle();
	pm.getSafetyModule()->waitForMode(SafetyModule::IDLE);
	return 0;
}