示例#1
0
int wam_main(int argc, char** argv, ProductManager& pm, systems::Wam<DOF>& wam){
	BARRETT_UNITS_TEMPLATE_TYPEDEFS(DOF);

	double dW,dL,bF;
	if(argc == 3){
		dL = atof(argv[2]);
		dL = dL*0.0254;
		dW = atof(argv[1]);
	}
	else if(argc == 2){
		dW = atof(argv[1]);
		dL = 0.762;
	}else{
		dW = 30.0;
		dL = 0.762;
	}

	bF = (dW / dL)*1.35581795;
	// Lets prevent the torque fault by limiting acceleration?
	//pm.safetyModule->setVelocityLimit(2.0);

	// Lets instantiate the system calls
	systems::ExposedOutput<cp_type> homePos;
	systems::Summer<cp_type> posErr("+-");
	systems::Gain<cp_type, double, cf_type> gain(bF);
	systems::ToolForceToJointTorques<DOF> tf2jt;

	connect(homePos.output, posErr.getInput(0));
	connect(wam.toolPosition.output, posErr.getInput(1));

	connect(posErr.output, gain.input);

	connect(wam.kinematicsBase.kinOutput, tf2jt.kinInput);
	connect(gain.output, tf2jt.input);

	homePos.setValueUndefined();
	connect(tf2jt.output, wam.input);

	wam.gravityCompensate();
	/*
	std::string line;
	bool active = true,set=false;
	while(active){
		std::getline(std::cin, line);
		switch (line[0]) {
			case 'x':
			case 'q':
				active = false;
				break;
			default:
				if (line.size() != 0) {
					if(set){
						homePos.setValue(wam.getToolPosition());
					}else{
						homePos.setValueUndefined();
					}
					set = !set;
				}
				break;
		}
	}*/

	while(pm.getSafetyModule()->getMode() == SafetyModule::ACTIVE){
		waitForEnter();
		homePos.setValue(wam.getToolPosition());
		printf(">>> Bow Position Locked.");

		waitForEnter();
		homePos.setValueUndefined();
		printf(">>> Bow Position Unlocked.");
	}

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