cooperaj · April 17, 2014 08:37 · thomasck · Dec 22, 2016
diff --git a/gistfile1.java b/gistfile1.java
 // I2C device class (I2Cdev) demonstration Processing sketch for MPU6050 DMP output
 // 6/20/2012 by Jeff Rowberg <[email protected]>
 // Updates should (hopefully) always be available at https://github.com/jrowberg/i2cdevlib
 //
 // Changelog:
 //     2012-06-20 - initial release

 /* ============================================
 I2Cdev device library code is placed under the MIT license
 Copyright (c) 2012 Jeff Rowberg

 Permission is hereby granted, free of charge, to any person obtaining a copy
 of this software and associated documentation files (the "Software"), to deal
 in the Software without restriction, including without limitation the rights
 to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 copies of the Software, and to permit persons to whom the Software is
 furnished to do so, subject to the following conditions:

 The above copyright notice and this permission notice shall be included in
 all copies or substantial portions of the Software.

 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
 THE SOFTWARE.
 ===============================================
 */

 import processing.serial.*;
 import processing.opengl.*;
 import toxi.geom.*;
 import toxi.processing.*;

 // NOTE: requires ToxicLibs to be installed in order to run properly.
 // 1. Download from http://toxiclibs.org/downloads
 // 2. Extract into [userdir]/Processing/libraries
 //    (location may be different on Mac/Linux)
 // 3. Run and bask in awesomeness

 ToxiclibsSupport gfx;

 Serial port;                         // The serial port
 char[] teapotPacket = new char[14];  // InvenSense Teapot packet
 int serialCount = 0;                 // current packet byte position
 int aligned = 0;
 int interval = 0;

 float[] q = new float[4];
 Quaternion quat = new Quaternion(1, 0, 0, 0);

 float[] gravity = new float[3];
 float[] euler = new float[3];
 float[] ypr = new float[3];

 void setup() {
    // 300px square viewport using OpenGL rendering
    size(640, 480, OPENGL);
    gfx = new ToxiclibsSupport(this);

    // setup lights and antialiasing
    lights();
    smooth();
  
    // display serial port list for debugging/clarity
    println(Serial.list());

    // get the first available port (use EITHER this OR the specific port code below)
    String portName = Serial.list()[5];
    
    // get a specific serial port (use EITHER this OR the first-available code above)
    //String portName = "COM4";
    
    // open the serial port
    port = new Serial(this, portName, 115200);
    
    // send single character to trigger DMP init/start
    // (expected by MPU6050_DMP6 example Arduino sketch)
    port.write('r');
 }

 void draw() {
    if (millis() - interval > 1000) {
        // resend single character to trigger DMP init/start
        // in case the MPU is halted/reset while applet is running
        port.write('r');
        interval = millis();
    }
    
    // black background
    background(0);
    
    // translate everything to the middle of the viewport
    pushMatrix();
    translate(width / 2, height / 2);

    // 3-step rotation from yaw/pitch/roll angles (gimbal lock!)
    // ...and other weirdness I haven't figured out yet
    //rotateY(-ypr[0]);
    //rotateZ(-ypr[1]);
    //rotateX(-ypr[2]);

    // toxiclibs direct angle/axis rotation from quaternion (NO gimbal lock!)
    // (axis order [1, 3, 2] and inversion [-1, +1, +1] is a consequence of
    // different coordinate system orientation assumptions between Processing
    // and InvenSense DMP)
    float[] axis = quat.toAxisAngle();
    rotate(axis[0], -axis[1], axis[3], axis[2]);

    // draw main body in red
    fill(255, 0, 0, 200);
    box(10, 10, 200);
    
    // draw front-facing tip in blue
    fill(0, 0, 255, 200);
    pushMatrix();
    translate(0, 0, -120);
    rotateX(PI/2);
    drawCylinder(0, 20, 20, 8);
    popMatrix();
    
    // draw wings and tail fin in green
    fill(0, 255, 0, 200);
    beginShape(TRIANGLES);
    vertex(-100,  2, 30); vertex(0,  2, -80); vertex(100,  2, 30);  // wing top layer
    vertex(-100, -2, 30); vertex(0, -2, -80); vertex(100, -2, 30);  // wing bottom layer
    vertex(-2, 0, 98); vertex(-2, -30, 98); vertex(-2, 0, 70);  // tail left layer
    vertex( 2, 0, 98); vertex( 2, -30, 98); vertex( 2, 0, 70);  // tail right layer
    endShape();
    beginShape(QUADS);
    vertex(-100, 2, 30); vertex(-100, -2, 30); vertex(  0, -2, -80); vertex(  0, 2, -80);
    vertex( 100, 2, 30); vertex( 100, -2, 30); vertex(  0, -2, -80); vertex(  0, 2, -80);
    vertex(-100, 2, 30); vertex(-100, -2, 30); vertex(100, -2,  30); vertex(100, 2,  30);
    vertex(-2,   0, 98); vertex(2,   0, 98); vertex(2, -30, 98); vertex(-2, -30, 98);
    vertex(-2,   0, 98); vertex(2,   0, 98); vertex(2,   0, 70); vertex(-2,   0, 70);
    vertex(-2, -30, 98); vertex(2, -30, 98); vertex(2,   0, 70); vertex(-2,   0, 70);
    endShape();
    
    popMatrix();
 }

 void serialEvent(Serial port) {
    interval = millis();
    while (port.available() > 0) {
        int ch = port.read();
        print((char)ch);
        if (ch == '$') {serialCount = 0;} // this will help with alignment
        if (aligned < 4) {
            // make sure we are properly aligned on a 14-byte packet
            if (serialCount == 0) {
                if (ch == '$') aligned++; else aligned = 0;
            } else if (serialCount == 1) {
                if (ch == 2) aligned++; else aligned = 0;
            } else if (serialCount == 12) {
                if (ch == '\r') aligned++; else aligned = 0;
            } else if (serialCount == 13) {
                if (ch == '\n') aligned++; else aligned = 0;
            }
            //println(ch + " " + aligned + " " + serialCount);
            serialCount++;
            if (serialCount == 14) serialCount = 0;
        } else {
            if (serialCount > 0 || ch == '$') {
                teapotPacket[serialCount++] = (char)ch;
                if (serialCount == 14) {
                    serialCount = 0; // restart packet byte position
                    
                    // get quaternion from data packet
                    q[0] = ((teapotPacket[2] << 8) | teapotPacket[3]) / 16384.0f;
                    q[1] = ((teapotPacket[4] << 8) | teapotPacket[5]) / 16384.0f;
                    q[2] = ((teapotPacket[6] << 8) | teapotPacket[7]) / 16384.0f;
                    q[3] = ((teapotPacket[8] << 8) | teapotPacket[9]) / 16384.0f;
                    for (int i = 0; i < 4; i++) if (q[i] >= 2) q[i] = -4 + q[i];
                    
                    // set our toxilibs quaternion to new data
                    quat.set(q[0], q[1], q[2], q[3]);

                    /*
                    // below calculations unnecessary for orientation only using toxilibs
                    
                    // calculate gravity vector
                    gravity[0] = 2 * (q[1]*q[3] - q[0]*q[2]);
                    gravity[1] = 2 * (q[0]*q[1] + q[2]*q[3]);
                    gravity[2] = q[0]*q[0] - q[1]*q[1] - q[2]*q[2] + q[3]*q[3];
        
                    // calculate Euler angles
                    euler[0] = atan2(2*q[1]*q[2] - 2*q[0]*q[3], 2*q[0]*q[0] + 2*q[1]*q[1] - 1);
                    euler[1] = -asin(2*q[1]*q[3] + 2*q[0]*q[2]);
                    euler[2] = atan2(2*q[2]*q[3] - 2*q[0]*q[1], 2*q[0]*q[0] + 2*q[3]*q[3] - 1);
        
                    // calculate yaw/pitch/roll angles
                    ypr[0] = atan2(2*q[1]*q[2] - 2*q[0]*q[3], 2*q[0]*q[0] + 2*q[1]*q[1] - 1);
                    ypr[1] = atan(gravity[0] / sqrt(gravity[1]*gravity[1] + gravity[2]*gravity[2]));
                    ypr[2] = atan(gravity[1] / sqrt(gravity[0]*gravity[0] + gravity[2]*gravity[2]));
        
                    // output various components for debugging
                    //println("q:\t" + round(q[0]*100.0f)/100.0f + "\t" + round(q[1]*100.0f)/100.0f + "\t" + round(q[2]*100.0f)/100.0f + "\t" + round(q[3]*100.0f)/100.0f);
                    //println("euler:\t" + euler[0]*180.0f/PI + "\t" + euler[1]*180.0f/PI + "\t" + euler[2]*180.0f/PI);
                    //println("ypr:\t" + ypr[0]*180.0f/PI + "\t" + ypr[1]*180.0f/PI + "\t" + ypr[2]*180.0f/PI);
                    */
                }
            }
        }
    }
 }

 void drawCylinder(float topRadius, float bottomRadius, float tall, int sides) {
    float angle = 0;
    float angleIncrement = TWO_PI / sides;
    beginShape(QUAD_STRIP);
    for (int i = 0; i < sides + 1; ++i) {
        vertex(topRadius*cos(angle), 0, topRadius*sin(angle));
        vertex(bottomRadius*cos(angle), tall, bottomRadius*sin(angle));
        angle += angleIncrement;
    }
    endShape();
    
    // If it is not a cone, draw the circular top cap
    if (topRadius != 0) {
        angle = 0;
        beginShape(TRIANGLE_FAN);
        
        // Center point
        vertex(0, 0, 0);
        for (int i = 0; i < sides + 1; i++) {
            vertex(topRadius * cos(angle), 0, topRadius * sin(angle));
            angle += angleIncrement;
        }
        endShape();
    }
  
    // If it is not a cone, draw the circular bottom cap
    if (bottomRadius != 0) {
        angle = 0;
        beginShape(TRIANGLE_FAN);
    
        // Center point
        vertex(0, tall, 0);
        for (int i = 0; i < sides + 1; i++) {
            vertex(bottomRadius * cos(angle), tall, bottomRadius * sin(angle));
            angle += angleIncrement;
        }
        endShape();
    }
 }
	// I2C device class (I2Cdev) demonstration Processing sketch for MPU6050 DMP output
	// 6/20/2012 by Jeff Rowberg <[email protected]>
	// Updates should (hopefully) always be available at https://github.com/jrowberg/i2cdevlib
	//
	// Changelog:
	// 2012-06-20 - initial release

	/* ============================================
	I2Cdev device library code is placed under the MIT license
	Copyright (c) 2012 Jeff Rowberg

	Permission is hereby granted, free of charge, to any person obtaining a copy
	of this software and associated documentation files (the "Software"), to deal
	in the Software without restriction, including without limitation the rights
	to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
	copies of the Software, and to permit persons to whom the Software is
	furnished to do so, subject to the following conditions:

	The above copyright notice and this permission notice shall be included in
	all copies or substantial portions of the Software.

	THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
	AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
	OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
	THE SOFTWARE.
	===============================================
	*/

	import processing.serial.*;
	import processing.opengl.*;
	import toxi.geom.*;
	import toxi.processing.*;

	// NOTE: requires ToxicLibs to be installed in order to run properly.
	// 1. Download from http://toxiclibs.org/downloads
	// 2. Extract into [userdir]/Processing/libraries
	// (location may be different on Mac/Linux)
	// 3. Run and bask in awesomeness

	ToxiclibsSupport gfx;

	Serial port; // The serial port
	char[] teapotPacket = new char[14]; // InvenSense Teapot packet
	int serialCount = 0; // current packet byte position
	int aligned = 0;
	int interval = 0;

	float[] q = new float[4];
	Quaternion quat = new Quaternion(1, 0, 0, 0);

	float[] gravity = new float[3];
	float[] euler = new float[3];
	float[] ypr = new float[3];

	void setup() {
	// 300px square viewport using OpenGL rendering
	size(640, 480, OPENGL);
	gfx = new ToxiclibsSupport(this);

	// setup lights and antialiasing
	lights();
	smooth();

	// display serial port list for debugging/clarity
	println(Serial.list());

	// get the first available port (use EITHER this OR the specific port code below)
	String portName = Serial.list()[5];

	// get a specific serial port (use EITHER this OR the first-available code above)
	//String portName = "COM4";

	// open the serial port
	port = new Serial(this, portName, 115200);

	// send single character to trigger DMP init/start
	// (expected by MPU6050_DMP6 example Arduino sketch)
	port.write('r');
	}

	void draw() {
	if (millis() - interval > 1000) {
	// resend single character to trigger DMP init/start
	// in case the MPU is halted/reset while applet is running
	port.write('r');
	interval = millis();
	}

	// black background
	background(0);

	// translate everything to the middle of the viewport
	pushMatrix();
	translate(width / 2, height / 2);

	// 3-step rotation from yaw/pitch/roll angles (gimbal lock!)
	// ...and other weirdness I haven't figured out yet
	//rotateY(-ypr[0]);
	//rotateZ(-ypr[1]);
	//rotateX(-ypr[2]);

	// toxiclibs direct angle/axis rotation from quaternion (NO gimbal lock!)
	// (axis order [1, 3, 2] and inversion [-1, +1, +1] is a consequence of
	// different coordinate system orientation assumptions between Processing
	// and InvenSense DMP)
	float[] axis = quat.toAxisAngle();
	rotate(axis[0], -axis[1], axis[3], axis[2]);

	// draw main body in red
	fill(255, 0, 0, 200);
	box(10, 10, 200);

	// draw front-facing tip in blue
	fill(0, 0, 255, 200);
	pushMatrix();
	translate(0, 0, -120);
	rotateX(PI/2);
	drawCylinder(0, 20, 20, 8);
	popMatrix();

	// draw wings and tail fin in green
	fill(0, 255, 0, 200);
	beginShape(TRIANGLES);
	vertex(-100, 2, 30); vertex(0, 2, -80); vertex(100, 2, 30); // wing top layer
	vertex(-100, -2, 30); vertex(0, -2, -80); vertex(100, -2, 30); // wing bottom layer
	vertex(-2, 0, 98); vertex(-2, -30, 98); vertex(-2, 0, 70); // tail left layer
	vertex( 2, 0, 98); vertex( 2, -30, 98); vertex( 2, 0, 70); // tail right layer
	endShape();
	beginShape(QUADS);
	vertex(-100, 2, 30); vertex(-100, -2, 30); vertex( 0, -2, -80); vertex( 0, 2, -80);
	vertex( 100, 2, 30); vertex( 100, -2, 30); vertex( 0, -2, -80); vertex( 0, 2, -80);
	vertex(-100, 2, 30); vertex(-100, -2, 30); vertex(100, -2, 30); vertex(100, 2, 30);
	vertex(-2, 0, 98); vertex(2, 0, 98); vertex(2, -30, 98); vertex(-2, -30, 98);
	vertex(-2, 0, 98); vertex(2, 0, 98); vertex(2, 0, 70); vertex(-2, 0, 70);
	vertex(-2, -30, 98); vertex(2, -30, 98); vertex(2, 0, 70); vertex(-2, 0, 70);
	endShape();

	popMatrix();
	}

	void serialEvent(Serial port) {
	interval = millis();
	while (port.available() > 0) {
	int ch = port.read();
	print((char)ch);
	if (ch == '$') {serialCount = 0;} // this will help with alignment
	if (aligned < 4) {
	// make sure we are properly aligned on a 14-byte packet
	if (serialCount == 0) {
	if (ch == '$') aligned++; else aligned = 0;
	} else if (serialCount == 1) {
	if (ch == 2) aligned++; else aligned = 0;
	} else if (serialCount == 12) {
	if (ch == '\r') aligned++; else aligned = 0;
	} else if (serialCount == 13) {
	if (ch == '\n') aligned++; else aligned = 0;
	}
	//println(ch + " " + aligned + " " + serialCount);
	serialCount++;
	if (serialCount == 14) serialCount = 0;
	} else {
	if (serialCount > 0 \|\| ch == '$') {
	teapotPacket[serialCount++] = (char)ch;
	if (serialCount == 14) {
	serialCount = 0; // restart packet byte position

	// get quaternion from data packet
	q[0] = ((teapotPacket[2] << 8) \| teapotPacket[3]) / 16384.0f;
	q[1] = ((teapotPacket[4] << 8) \| teapotPacket[5]) / 16384.0f;
	q[2] = ((teapotPacket[6] << 8) \| teapotPacket[7]) / 16384.0f;
	q[3] = ((teapotPacket[8] << 8) \| teapotPacket[9]) / 16384.0f;
	for (int i = 0; i < 4; i++) if (q[i] >= 2) q[i] = -4 + q[i];

	// set our toxilibs quaternion to new data
	quat.set(q[0], q[1], q[2], q[3]);

	/*
	// below calculations unnecessary for orientation only using toxilibs

	// calculate gravity vector
	gravity[0] = 2 * (q[1]q[3] - q[0]q[2]);
	gravity[1] = 2 * (q[0]q[1] + q[2]q[3]);
	gravity[2] = q[0]q[0] - q[1]q[1] - q[2]q[2] + q[3]q[3];

	// calculate Euler angles
	euler[0] = atan2(2q[1]q[2] - 2q[0]q[3], 2q[0]q[0] + 2q[1]q[1] - 1);
	euler[1] = -asin(2q[1]q[3] + 2q[0]q[2]);
	euler[2] = atan2(2q[2]q[3] - 2q[0]q[1], 2q[0]q[0] + 2q[3]q[3] - 1);

	// calculate yaw/pitch/roll angles
	ypr[0] = atan2(2q[1]q[2] - 2q[0]q[3], 2q[0]q[0] + 2q[1]q[1] - 1);
	ypr[1] = atan(gravity[0] / sqrt(gravity[1]gravity[1] + gravity[2]gravity[2]));
	ypr[2] = atan(gravity[1] / sqrt(gravity[0]gravity[0] + gravity[2]gravity[2]));

	// output various components for debugging
	//println("q:\t" + round(q[0]100.0f)/100.0f + "\t" + round(q[1]100.0f)/100.0f + "\t" + round(q[2]100.0f)/100.0f + "\t" + round(q[3]100.0f)/100.0f);
	//println("euler:\t" + euler[0]180.0f/PI + "\t" + euler[1]180.0f/PI + "\t" + euler[2]*180.0f/PI);
	//println("ypr:\t" + ypr[0]180.0f/PI + "\t" + ypr[1]180.0f/PI + "\t" + ypr[2]*180.0f/PI);
	*/
	}
	}
	}
	}
	}

	void drawCylinder(float topRadius, float bottomRadius, float tall, int sides) {
	float angle = 0;
	float angleIncrement = TWO_PI / sides;
	beginShape(QUAD_STRIP);
	for (int i = 0; i < sides + 1; ++i) {
	vertex(topRadiuscos(angle), 0, topRadiussin(angle));
	vertex(bottomRadiuscos(angle), tall, bottomRadiussin(angle));
	angle += angleIncrement;
	}
	endShape();

	// If it is not a cone, draw the circular top cap
	if (topRadius != 0) {
	angle = 0;
	beginShape(TRIANGLE_FAN);

	// Center point
	vertex(0, 0, 0);
	for (int i = 0; i < sides + 1; i++) {
	vertex(topRadius * cos(angle), 0, topRadius * sin(angle));
	angle += angleIncrement;
	}
	endShape();
	}

	// If it is not a cone, draw the circular bottom cap
	if (bottomRadius != 0) {
	angle = 0;
	beginShape(TRIANGLE_FAN);

	// Center point
	vertex(0, tall, 0);
	for (int i = 0; i < sides + 1; i++) {
	vertex(bottomRadius * cos(angle), tall, bottomRadius * sin(angle));
	angle += angleIncrement;
	}
	endShape();
	}
	}