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SCDS:master SCDS:branch-carlos SCDS:Branch-Yixuan SCDS:Branch-Asher SCDS:20240215-115542-release-candidate SCDS:20230929-083754-release-candidate SCDS:20230830-154348-release-candidate SCDS:20230707-131020-release-candidate
SCDS:v9.1 SCDS:v9.0.1 SCDS:v9.0 SCDS:v8.2 SCDS:v8.1.1 SCDS:v8.1 SCDS:v8.0 SCDS:v7.2 SCDS:v7.1 SCDS:v7.0 SCDS:v6.2 SCDS:v6.1 SCDS:v6.0
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compare: SCDS:b779a61a7cb0a2d46fa63ce2acb1346541a88224
Branches Tags
SCDS:branch-carlos SCDS:Branch-Yixuan SCDS:Branch-Asher SCDS:master SCDS:20240215-115542-release-candidate SCDS:20230929-083754-release-candidate SCDS:20230830-154348-release-candidate SCDS:20230707-131020-release-candidate
SCDS:v9.1 SCDS:v9.0.1 SCDS:v9.0 SCDS:v8.2 SCDS:v8.1.1 SCDS:v8.1 SCDS:v8.0 SCDS:v7.2 SCDS:v7.1 SCDS:v7.0 SCDS:v6.2 SCDS:v6.1 SCDS:v6.0

3 Commits
9e8609e68d ... b779a61a7c

Author SHA1 Message Date
Carlos
b779a61a7c Updating to use Roadrunner 2024-06-30 09:57:10 -07:00
Carlos
1a1ef3b2dc Add first pass of Roadrunner class files 2024-06-22 11:10:36 -07:00
Carlos
4ecd419511 Updated movement library to the updated orientation of the motors, added speed control via bumpers 2024-06-22 11:02:18 -07:00
11 changed files with 811 additions and 29 deletions
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73
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/CometBotsLinearOpMode.java
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@ -29,10 +29,13 @@
package org.firstinspires.ftc.teamcode;
import static org.firstinspires.ftc.teamcode.cometbots.Constants.*;
import com.qualcomm.robotcore.eventloop.opmode.Disabled;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import com.qualcomm.robotcore.eventloop.opmode.TeleOp;
import com.qualcomm.robotcore.hardware.DcMotor;
import com.qualcomm.robotcore.hardware.DcMotorSimple;
import com.qualcomm.robotcore.hardware.Gamepad;
import com.qualcomm.robotcore.util.ElapsedTime;
@ -79,12 +82,15 @@ public class CometBotsLinearOpMode extends LinearOpMode {
@Override
public void runOpMode() {
// Button A counter to cycle speeds
int cntBtnA = 1;
// Initialize the hardware variables. Note that the strings used here must correspond
// to the names assigned during the robot configuration step on the DS or RC devices.
rhw = hardwareMap.get(DcMotor.class, "right hand wheel");
rlw = hardwareMap.get(DcMotor.class, "right leg wheel");
lhw = hardwareMap.get(DcMotor.class, "left hand wheel");
llw = hardwareMap.get(DcMotor.class, "left leg wheel");
rhw = hardwareMap.get(DcMotor.class, RT_FRONT);
rlw = hardwareMap.get(DcMotor.class, RT_BACK);
lhw = hardwareMap.get(DcMotor.class, LT_FRONT);
llw = hardwareMap.get(DcMotor.class, LT_BACK);
/*
Put all motors in an array for easier handling
@ -116,22 +122,22 @@ public class CometBotsLinearOpMode extends LinearOpMode {
// Combine the joystick requests for each axis-motion to determine each wheel's power.
// Set up a variable for each drive wheel to save the power level for telemetry.
double leftFrontPower = axial + lateral + yaw;
double rightFrontPower = axial - lateral - yaw;
double leftBackPower = axial - lateral + yaw;
double rightBackPower = axial + lateral - yaw;
double lftFrntPwr = axial + lateral + yaw;
double rtFrntPwr = axial - lateral - yaw;
double ltBckPwr = axial - lateral + yaw;
double rtBckPwr = axial + lateral - yaw;
// Normalize the values so no wheel power exceeds 100%
// This ensures that the robot maintains the desired motion.
max = Math.max(Math.abs(leftFrontPower), Math.abs(rightFrontPower));
max = Math.max(max, Math.abs(leftBackPower));
max = Math.max(max, Math.abs(rightBackPower));
max = Math.max(Math.abs(lftFrntPwr), Math.abs(rtFrntPwr));
max = Math.max(max, Math.abs(ltBckPwr));
max = Math.max(max, Math.abs(rtBckPwr));
if (max > 1.0) {
leftFrontPower /= max;
rightFrontPower /= max;
leftBackPower /= max;
rightBackPower /= max;
lftFrntPwr /= max;
rtFrntPwr /= max;
ltBckPwr /= max;
rtBckPwr /= max;
}
// This is test code:
@ -145,22 +151,39 @@ public class CometBotsLinearOpMode extends LinearOpMode {
// Once the correct motors move in the correct direction re-comment this code.
/*
leftFrontPower = gamepad1.x ? 1.0 : 0.0; // X gamepad
leftBackPower = gamepad1.a ? 1.0 : 0.0; // A gamepad
rightFrontPower = gamepad1.y ? 1.0 : 0.0; // Y gamepad
rightBackPower = gamepad1.b ? 1.0 : 0.0; // B gamepad
lftFrntPwr = gamepad1.x ? 1.0 : 0.0; // X gamepad
ltBckPwr = gamepad1.a ? 1.0 : 0.0; // A gamepad
rtFrntPwr = gamepad1.y ? 1.0 : 0.0; // Y gamepad
rtBckPwr = gamepad1.b ? 1.0 : 0.0; // B gamepad
*/
lhw.setPower(lftFrntPwr/cntBtnA);
rhw.setPower(rtFrntPwr/cntBtnA);
llw.setPower(ltBckPwr/cntBtnA);
rlw.setPower(rtBckPwr/cntBtnA);
// Send calculated power to wheels
lhw.setPower(leftFrontPower);
rhw.setPower(rightFrontPower);
llw.setPower(leftBackPower);
rlw.setPower(rightBackPower);
if(gamepad1.left_bumper) {
sleep(175);
cntBtnA--;
if(cntBtnA < 0) {
cntBtnA = 0;
}
}
if(gamepad1.right_bumper) {
sleep(175);
cntBtnA++;
if(cntBtnA > 4) {
cntBtnA = 4;
}
}
// Show the elapsed game time and wheel power.
telemetry.addData("Status", "Run Time: " + runtime.toString());
telemetry.addData("Front left/Right", "%4.2f, %4.2f", leftFrontPower, rightFrontPower);
telemetry.addData("Back left/Right", "%4.2f, %4.2f", leftBackPower, rightBackPower);
telemetry.addData("Front left/Right", "%4.2f, %4.2f", lftFrntPwr, rtFrntPwr);
telemetry.addData("Back left/Right", "%4.2f, %4.2f", ltBckPwr, rtBckPwr);
telemetry.addData("Power Mode", cntBtnA);
telemetry.update();
}
}}

132
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/CometBotsMecanumDriveMode.java Normal file
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@ -0,0 +1,132 @@
/* Copyright (c) 2021 FIRST. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without modification,
* are permitted (subject to the limitations in the disclaimer below) provided that
* the following conditions are met:
*
* Redistributions of source code must retain the above copyright notice, this list
* of conditions and the following disclaimer.
*
* Redistributions in binary form must reproduce the above copyright notice, this
* list of conditions and the following disclaimer in the documentation and/or
* other materials provided with the distribution.
*
* Neither the name of FIRST nor the names of its contributors may be used to endorse or
* promote products derived from this software without specific prior written permission.
*
* NO EXPRESS OR IMPLIED LICENSES TO ANY PARTY'S PATENT RIGHTS ARE GRANTED BY THIS
* LICENSE. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
* THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
package org.firstinspires.ftc.teamcode;
import static org.firstinspires.ftc.teamcode.cometbots.Constants.LT_BACK;
import static org.firstinspires.ftc.teamcode.cometbots.Constants.LT_FRONT;
import static org.firstinspires.ftc.teamcode.cometbots.Constants.RT_BACK;
import static org.firstinspires.ftc.teamcode.cometbots.Constants.RT_FRONT;
import com.acmerobotics.roadrunner.Pose2d;
import com.acmerobotics.roadrunner.PoseVelocity2d;
import com.acmerobotics.roadrunner.Vector2d;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import com.qualcomm.robotcore.eventloop.opmode.TeleOp;
import com.qualcomm.robotcore.hardware.DcMotor;
import com.qualcomm.robotcore.util.ElapsedTime;
import org.firstinspires.ftc.teamcode.cometbots.MovementLibrary;
/*
* This file contains an example of a Linear "OpMode".
* An OpMode is a 'program' that runs in either the autonomous or the teleop period of an FTC match.
* The names of OpModes appear on the menu of the FTC Driver Station.
* When a selection is made from the menu, the corresponding OpMode is executed.
*
* This particular OpMode illustrates driving a 4-motor Omni-Directional (or Holonomic) robot.
* This code will work with either a Mecanum-Drive or an X-Drive train.
* Both of these drives are illustrated at https://gm0.org/en/latest/docs/robot-design/drivetrains/holonomic.html
* Note that a Mecanum drive must display an X roller-pattern when viewed from above.
*
* Also note that it is critical to set the correct rotation direction for each motor. See details below.
*
* Holonomic drives provide the ability for the robot to move in three axes (directions) simultaneously.
* Each motion axis is controlled by one Joystick axis.
*
* 1) Axial: Driving forward and backward Left-joystick Forward/Backward
* 2) Lateral: Strafing right and left Left-joystick Right and Left
* 3) Yaw: Rotating Clockwise and counter clockwise Right-joystick Right and Left
*
* This code is written assuming that the right-side motors need to be reversed for the robot to drive forward.
* When you first test your robot, if it moves backward when you push the left stick forward, then you must flip
* the direction of all 4 motors (see code below).
*
* Use Android Studio to Copy this Class, and Paste it into your team's code folder with a new name.
* Remove or comment out the @Disabled line to add this OpMode to the Driver Station OpMode list
*/
@TeleOp(name="CometBots Mecanum Drive Demo", group = "[14493] CometBots")
public class CometBotsMecanumDriveMode extends LinearOpMode {
// Declare OpMode members for each of the 4 motors.
private ElapsedTime runtime = new ElapsedTime();
private DcMotor rhw = null;
private DcMotor rlw = null;
private DcMotor lhw = null;
private DcMotor llw = null;
@Override
public void runOpMode() {
MecanumDrive drive = new MecanumDrive(hardwareMap, new Pose2d(0,0,Math.toRadians(90)));
// Button A counter to cycle speeds
int cntBtnA = 1;
// Initialize the hardware variables. Note that the strings used here must correspond
// to the names assigned during the robot configuration step on the DS or RC devices.
rhw = hardwareMap.get(DcMotor.class, RT_FRONT);
rlw = hardwareMap.get(DcMotor.class, RT_BACK);
lhw = hardwareMap.get(DcMotor.class, LT_FRONT);
llw = hardwareMap.get(DcMotor.class, LT_BACK);
/*
Put all motors in an array for easier handling
NOTE: Placement of motor in array is important especially when dealing with functions
that set direction
*/
DcMotor[] motors = {rhw, rlw, lhw, llw};
/*
Initialize all wheels forward using motors a
*/
MovementLibrary.setDirectionForward(motors);
telemetry.addData("Status", "Initialized");
telemetry.update();
waitForStart();
runtime.reset();
// run until the end of the match (driver presses STOP)
while (opModeIsActive()) {
drive.setDrivePowers(
new PoseVelocity2d(
new Vector2d(
gamepad1.right_stick_x,
gamepad1.right_stick_y
),
-gamepad1.right_stick_x
)
);
drive.updatePoseEstimate();
}
}}

22
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/Drawing.java Normal file
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@ -0,0 +1,22 @@
package org.firstinspires.ftc.teamcode;
import com.acmerobotics.dashboard.canvas.Canvas;
import com.acmerobotics.roadrunner.Pose2d;
import com.acmerobotics.roadrunner.Vector2d;
public final class Drawing {
private Drawing() {}
public static void drawRobot(Canvas c, Pose2d t) {
final double ROBOT_RADIUS = 9;
c.setStrokeWidth(1);
c.strokeCircle(t.position.x, t.position.y, ROBOT_RADIUS);
Vector2d halfv = t.heading.vec().times(0.5 * ROBOT_RADIUS);
Vector2d p1 = t.position.plus(halfv);
Vector2d p2 = p1.plus(halfv);
c.strokeLine(p1.x, p1.y, p2.x, p2.y);
}
}

8
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/Localizer.java Normal file
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@ -0,0 +1,8 @@
package org.firstinspires.ftc.teamcode;
import com.acmerobotics.roadrunner.Time;
import com.acmerobotics.roadrunner.Twist2dDual;
public interface Localizer {
Twist2dDual<Time> update();
}

502
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/MecanumDrive.java Normal file
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@ -0,0 +1,502 @@
package org.firstinspires.ftc.teamcode;
import static org.firstinspires.ftc.teamcode.cometbots.Constants.*;
import androidx.annotation.NonNull;
import com.acmerobotics.dashboard.canvas.Canvas;
import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.TelemetryPacket;
import com.acmerobotics.roadrunner.*;
import com.acmerobotics.roadrunner.AngularVelConstraint;
import com.acmerobotics.roadrunner.DualNum;
import com.acmerobotics.roadrunner.HolonomicController;
import com.acmerobotics.roadrunner.MecanumKinematics;
import com.acmerobotics.roadrunner.MinVelConstraint;
import com.acmerobotics.roadrunner.MotorFeedforward;
import com.acmerobotics.roadrunner.Pose2d;
import com.acmerobotics.roadrunner.Pose2dDual;
import com.acmerobotics.roadrunner.ProfileAccelConstraint;
import com.acmerobotics.roadrunner.Time;
import com.acmerobotics.roadrunner.TimeTrajectory;
import com.acmerobotics.roadrunner.TimeTurn;
import com.acmerobotics.roadrunner.TrajectoryActionBuilder;
import com.acmerobotics.roadrunner.TurnConstraints;
import com.acmerobotics.roadrunner.Twist2dDual;
import com.acmerobotics.roadrunner.VelConstraint;
import com.acmerobotics.roadrunner.ftc.DownsampledWriter;
import com.acmerobotics.roadrunner.ftc.Encoder;
import com.acmerobotics.roadrunner.ftc.FlightRecorder;
import com.acmerobotics.roadrunner.ftc.LazyImu;
import com.acmerobotics.roadrunner.ftc.LynxFirmware;
import com.acmerobotics.roadrunner.ftc.OverflowEncoder;
import com.acmerobotics.roadrunner.ftc.PositionVelocityPair;
import com.acmerobotics.roadrunner.ftc.RawEncoder;
import com.qualcomm.hardware.lynx.LynxModule;
import com.qualcomm.hardware.rev.RevHubOrientationOnRobot;
import com.qualcomm.robotcore.hardware.DcMotor;
import com.qualcomm.robotcore.hardware.DcMotorEx;
import com.qualcomm.robotcore.hardware.DcMotorSimple;
import com.qualcomm.robotcore.hardware.HardwareMap;
import com.qualcomm.robotcore.hardware.IMU;
import com.qualcomm.robotcore.hardware.VoltageSensor;
import org.firstinspires.ftc.robotcore.external.navigation.AngleUnit;
import org.firstinspires.ftc.robotcore.external.navigation.YawPitchRollAngles;
import org.firstinspires.ftc.teamcode.cometbots.MovementLibrary;
import org.firstinspires.ftc.teamcode.messages.DriveCommandMessage;
import org.firstinspires.ftc.teamcode.messages.MecanumCommandMessage;
import org.firstinspires.ftc.teamcode.messages.MecanumLocalizerInputsMessage;
import org.firstinspires.ftc.teamcode.messages.PoseMessage;
import java.lang.Math;
import java.util.Arrays;
import java.util.LinkedList;
import java.util.List;
@Config
public final class MecanumDrive {
public static class Params {
// IMU orientation
// TODO: fill in these values based on
// see https://ftc-docs.firstinspires.org/en/latest/programming_resources/imu/imu.html?highlight=imu#physical-hub-mounting
public RevHubOrientationOnRobot.LogoFacingDirection logoFacingDirection =
RevHubOrientationOnRobot.LogoFacingDirection.FORWARD;
public RevHubOrientationOnRobot.UsbFacingDirection usbFacingDirection =
RevHubOrientationOnRobot.UsbFacingDirection.UP;
// drive model parameters
public double inPerTick = 119/5924.5;
public double lateralInPerTick = 124/6930.5;
public double trackWidthTicks = 1131;
// feedforward parameters (in tick units)
public double kS = 0.7476;
public double kV = 0.0043736;
public double kA = 00055;
// path profile parameters (in inches)
public double maxWheelVel = 50;
public double minProfileAccel = -30;
public double maxProfileAccel = 50;
// turn profile parameters (in radians)
public double maxAngVel = Math.PI; // shared with path
public double maxAngAccel = Math.PI;
// path controller gains
public double axialGain = 4.125;
public double lateralGain = 4.125;
public double headingGain = 4.25; // shared with turn
public double axialVelGain = 0.0;
public double lateralVelGain = 0.0;
public double headingVelGain = 0.0; // shared with turn
}
public static Params PARAMS = new Params();
public final MecanumKinematics kinematics = new MecanumKinematics(
PARAMS.inPerTick * PARAMS.trackWidthTicks, PARAMS.inPerTick / PARAMS.lateralInPerTick);
public final TurnConstraints defaultTurnConstraints = new TurnConstraints(
PARAMS.maxAngVel, -PARAMS.maxAngAccel, PARAMS.maxAngAccel);
public final VelConstraint defaultVelConstraint =
new MinVelConstraint(Arrays.asList(
kinematics.new WheelVelConstraint(PARAMS.maxWheelVel),
new AngularVelConstraint(PARAMS.maxAngVel)
));
public final AccelConstraint defaultAccelConstraint =
new ProfileAccelConstraint(PARAMS.minProfileAccel, PARAMS.maxProfileAccel);
public final DcMotorEx leftFront, leftBack, rightBack, rightFront;
public final VoltageSensor voltageSensor;
public final LazyImu lazyImu;
public final Localizer localizer;
public Pose2d pose;
private final LinkedList<Pose2d> poseHistory = new LinkedList<>();
private final DownsampledWriter estimatedPoseWriter = new DownsampledWriter("ESTIMATED_POSE", 50_000_000);
private final DownsampledWriter targetPoseWriter = new DownsampledWriter("TARGET_POSE", 50_000_000);
private final DownsampledWriter driveCommandWriter = new DownsampledWriter("DRIVE_COMMAND", 50_000_000);
private final DownsampledWriter mecanumCommandWriter = new DownsampledWriter("MECANUM_COMMAND", 50_000_000);
public class DriveLocalizer implements Localizer {
public final Encoder leftFront, leftBack, rightBack, rightFront;
public final IMU imu;
private int lastLeftFrontPos, lastLeftBackPos, lastRightBackPos, lastRightFrontPos;
private Rotation2d lastHeading;
private boolean initialized;
public DriveLocalizer() {
leftFront = new OverflowEncoder(new RawEncoder(MecanumDrive.this.leftFront));
leftBack = new OverflowEncoder(new RawEncoder(MecanumDrive.this.leftBack));
rightBack = new OverflowEncoder(new RawEncoder(MecanumDrive.this.rightBack));
rightFront = new OverflowEncoder(new RawEncoder(MecanumDrive.this.rightFront));
imu = lazyImu.get();
// TODO: reverse encoders if needed
// leftFront.setDirection(DcMotorSimple.Direction.REVERSE);
}
@Override
public Twist2dDual<Time> update() {
PositionVelocityPair leftFrontPosVel = leftFront.getPositionAndVelocity();
PositionVelocityPair leftBackPosVel = leftBack.getPositionAndVelocity();
PositionVelocityPair rightBackPosVel = rightBack.getPositionAndVelocity();
PositionVelocityPair rightFrontPosVel = rightFront.getPositionAndVelocity();
YawPitchRollAngles angles = imu.getRobotYawPitchRollAngles();
FlightRecorder.write("MECANUM_LOCALIZER_INPUTS", new MecanumLocalizerInputsMessage(
leftFrontPosVel, leftBackPosVel, rightBackPosVel, rightFrontPosVel, angles));
Rotation2d heading = Rotation2d.exp(angles.getYaw(AngleUnit.RADIANS));
if (!initialized) {
initialized = true;
lastLeftFrontPos = leftFrontPosVel.position;
lastLeftBackPos = leftBackPosVel.position;
lastRightBackPos = rightBackPosVel.position;
lastRightFrontPos = rightFrontPosVel.position;
lastHeading = heading;
return new Twist2dDual<>(
Vector2dDual.constant(new Vector2d(0.0, 0.0), 2),
DualNum.constant(0.0, 2)
);
}
double headingDelta = heading.minus(lastHeading);
Twist2dDual<Time> twist = kinematics.forward(new MecanumKinematics.WheelIncrements<>(
new DualNum<Time>(new double[]{
(leftFrontPosVel.position - lastLeftFrontPos),
leftFrontPosVel.velocity,
}).times(PARAMS.inPerTick),
new DualNum<Time>(new double[]{
(leftBackPosVel.position - lastLeftBackPos),
leftBackPosVel.velocity,
}).times(PARAMS.inPerTick),
new DualNum<Time>(new double[]{
(rightBackPosVel.position - lastRightBackPos),
rightBackPosVel.velocity,
}).times(PARAMS.inPerTick),
new DualNum<Time>(new double[]{
(rightFrontPosVel.position - lastRightFrontPos),
rightFrontPosVel.velocity,
}).times(PARAMS.inPerTick)
));
lastLeftFrontPos = leftFrontPosVel.position;
lastLeftBackPos = leftBackPosVel.position;
lastRightBackPos = rightBackPosVel.position;
lastRightFrontPos = rightFrontPosVel.position;
lastHeading = heading;
return new Twist2dDual<>(
twist.line,
DualNum.cons(headingDelta, twist.angle.drop(1))
);
}
}
public MecanumDrive(HardwareMap hardwareMap, Pose2d pose) {
this.pose = pose;
LynxFirmware.throwIfModulesAreOutdated(hardwareMap);
for (LynxModule module : hardwareMap.getAll(LynxModule.class)) {
module.setBulkCachingMode(LynxModule.BulkCachingMode.AUTO);
}
// TODO: make sure your config has motors with these names (or change them)
// see https://ftc-docs.firstinspires.org/en/latest/hardware_and_software_configuration/configuring/index.html
leftFront = hardwareMap.get(DcMotorEx.class, LT_FRONT);
leftBack = hardwareMap.get(DcMotorEx.class, LT_BACK);
rightBack = hardwareMap.get(DcMotorEx.class, RT_BACK);
rightFront = hardwareMap.get(DcMotorEx.class, RT_FRONT);
leftFront.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.BRAKE);
leftBack.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.BRAKE);
rightBack.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.BRAKE);
rightFront.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.BRAKE);
/*
Put all motors in an array for easier handling
NOTE: Placement of motor in array is important especially when dealing with functions
that set direction
*/
DcMotor[] motors = {rightFront, rightBack, leftFront, leftBack};
/*
Initialize all wheels forward using motors a
*/
MovementLibrary.setDirectionForward(motors);
// TODO: make sure your config has an IMU with this name (can be BNO or BHI)
// see https://ftc-docs.firstinspires.org/en/latest/hardware_and_software_configuration/configuring/index.html
lazyImu = new LazyImu(hardwareMap, "imu", new RevHubOrientationOnRobot(
PARAMS.logoFacingDirection, PARAMS.usbFacingDirection));
voltageSensor = hardwareMap.voltageSensor.iterator().next();
localizer = new DriveLocalizer();
FlightRecorder.write("MECANUM_PARAMS", PARAMS);
}
public void setDrivePowers(PoseVelocity2d powers) {
MecanumKinematics.WheelVelocities<Time> wheelVels = new MecanumKinematics(1).inverse(
PoseVelocity2dDual.constant(powers, 1));
double maxPowerMag = 1;
for (DualNum<Time> power : wheelVels.all()) {
maxPowerMag = Math.max(maxPowerMag, power.value());
}
leftFront.setPower(wheelVels.leftFront.get(0) / maxPowerMag);
leftBack.setPower(wheelVels.leftBack.get(0) / maxPowerMag);
rightBack.setPower(wheelVels.rightBack.get(0) / maxPowerMag);
rightFront.setPower(wheelVels.rightFront.get(0) / maxPowerMag);
}
public final class FollowTrajectoryAction implements Action {
public final TimeTrajectory timeTrajectory;
private double beginTs = -1;
private final double[] xPoints, yPoints;
public FollowTrajectoryAction(TimeTrajectory t) {
timeTrajectory = t;
List<Double> disps = com.acmerobotics.roadrunner.Math.range(
0, t.path.length(),
Math.max(2, (int) Math.ceil(t.path.length() / 2)));
xPoints = new double[disps.size()];
yPoints = new double[disps.size()];
for (int i = 0; i < disps.size(); i++) {
Pose2d p = t.path.get(disps.get(i), 1).value();
xPoints[i] = p.position.x;
yPoints[i] = p.position.y;
}
}
@Override
public boolean run(@NonNull TelemetryPacket p) {
double t;
if (beginTs < 0) {
beginTs = Actions.now();
t = 0;
} else {
t = Actions.now() - beginTs;
}
if (t >= timeTrajectory.duration) {
leftFront.setPower(0);
leftBack.setPower(0);
rightBack.setPower(0);
rightFront.setPower(0);
return false;
}
Pose2dDual<Time> txWorldTarget = timeTrajectory.get(t);
targetPoseWriter.write(new PoseMessage(txWorldTarget.value()));
PoseVelocity2d robotVelRobot = updatePoseEstimate();
PoseVelocity2dDual<Time> command = new HolonomicController(
PARAMS.axialGain, PARAMS.lateralGain, PARAMS.headingGain,
PARAMS.axialVelGain, PARAMS.lateralVelGain, PARAMS.headingVelGain
)
.compute(txWorldTarget, pose, robotVelRobot);
driveCommandWriter.write(new DriveCommandMessage(command));
MecanumKinematics.WheelVelocities<Time> wheelVels = kinematics.inverse(command);
double voltage = voltageSensor.getVoltage();
final MotorFeedforward feedforward = new MotorFeedforward(PARAMS.kS,
PARAMS.kV / PARAMS.inPerTick, PARAMS.kA / PARAMS.inPerTick);
double leftFrontPower = feedforward.compute(wheelVels.leftFront) / voltage;
double leftBackPower = feedforward.compute(wheelVels.leftBack) / voltage;
double rightBackPower = feedforward.compute(wheelVels.rightBack) / voltage;
double rightFrontPower = feedforward.compute(wheelVels.rightFront) / voltage;
mecanumCommandWriter.write(new MecanumCommandMessage(
voltage, leftFrontPower, leftBackPower, rightBackPower, rightFrontPower
));
leftFront.setPower(leftFrontPower);
leftBack.setPower(leftBackPower);
rightBack.setPower(rightBackPower);
rightFront.setPower(rightFrontPower);
p.put("x", pose.position.x);
p.put("y", pose.position.y);
p.put("heading (deg)", Math.toDegrees(pose.heading.toDouble()));
Pose2d error = txWorldTarget.value().minusExp(pose);
p.put("xError", error.position.x);
p.put("yError", error.position.y);
p.put("headingError (deg)", Math.toDegrees(error.heading.toDouble()));
// only draw when active; only one drive action should be active at a time
Canvas c = p.fieldOverlay();
drawPoseHistory(c);
c.setStroke("#4CAF50");
Drawing.drawRobot(c, txWorldTarget.value());
c.setStroke("#3F51B5");
Drawing.drawRobot(c, pose);
c.setStroke("#4CAF50FF");
c.setStrokeWidth(1);
c.strokePolyline(xPoints, yPoints);
return true;
}
@Override
public void preview(Canvas c) {
c.setStroke("#4CAF507A");
c.setStrokeWidth(1);
c.strokePolyline(xPoints, yPoints);
}
}
public final class TurnAction implements Action {
private final TimeTurn turn;
private double beginTs = -1;
public TurnAction(TimeTurn turn) {
this.turn = turn;
}
@Override
public boolean run(@NonNull TelemetryPacket p) {
double t;
if (beginTs < 0) {
beginTs = Actions.now();
t = 0;
} else {
t = Actions.now() - beginTs;
}
if (t >= turn.duration) {
leftFront.setPower(0);
leftBack.setPower(0);
rightBack.setPower(0);
rightFront.setPower(0);
return false;
}
Pose2dDual<Time> txWorldTarget = turn.get(t);
targetPoseWriter.write(new PoseMessage(txWorldTarget.value()));
PoseVelocity2d robotVelRobot = updatePoseEstimate();
PoseVelocity2dDual<Time> command = new HolonomicController(
PARAMS.axialGain, PARAMS.lateralGain, PARAMS.headingGain,
PARAMS.axialVelGain, PARAMS.lateralVelGain, PARAMS.headingVelGain
)
.compute(txWorldTarget, pose, robotVelRobot);
driveCommandWriter.write(new DriveCommandMessage(command));
MecanumKinematics.WheelVelocities<Time> wheelVels = kinematics.inverse(command);
double voltage = voltageSensor.getVoltage();
final MotorFeedforward feedforward = new MotorFeedforward(PARAMS.kS,
PARAMS.kV / PARAMS.inPerTick, PARAMS.kA / PARAMS.inPerTick);
double leftFrontPower = feedforward.compute(wheelVels.leftFront) / voltage;
double leftBackPower = feedforward.compute(wheelVels.leftBack) / voltage;
double rightBackPower = feedforward.compute(wheelVels.rightBack) / voltage;
double rightFrontPower = feedforward.compute(wheelVels.rightFront) / voltage;
mecanumCommandWriter.write(new MecanumCommandMessage(
voltage, leftFrontPower, leftBackPower, rightBackPower, rightFrontPower
));
leftFront.setPower(feedforward.compute(wheelVels.leftFront) / voltage);
leftBack.setPower(feedforward.compute(wheelVels.leftBack) / voltage);
rightBack.setPower(feedforward.compute(wheelVels.rightBack) / voltage);
rightFront.setPower(feedforward.compute(wheelVels.rightFront) / voltage);
Canvas c = p.fieldOverlay();
drawPoseHistory(c);
c.setStroke("#4CAF50");
Drawing.drawRobot(c, txWorldTarget.value());
c.setStroke("#3F51B5");
Drawing.drawRobot(c, pose);
c.setStroke("#7C4DFFFF");
c.fillCircle(turn.beginPose.position.x, turn.beginPose.position.y, 2);
return true;
}
@Override
public void preview(Canvas c) {
c.setStroke("#7C4DFF7A");
c.fillCircle(turn.beginPose.position.x, turn.beginPose.position.y, 2);
}
}
public PoseVelocity2d updatePoseEstimate() {
Twist2dDual<Time> twist = localizer.update();
pose = pose.plus(twist.value());
poseHistory.add(pose);
while (poseHistory.size() > 100) {
poseHistory.removeFirst();
}
estimatedPoseWriter.write(new PoseMessage(pose));
return twist.velocity().value();
}
private void drawPoseHistory(Canvas c) {
double[] xPoints = new double[poseHistory.size()];
double[] yPoints = new double[poseHistory.size()];
int i = 0;
for (Pose2d t : poseHistory) {
xPoints[i] = t.position.x;
yPoints[i] = t.position.y;
i++;
}
c.setStrokeWidth(1);
c.setStroke("#3F51B5");
c.strokePolyline(xPoints, yPoints);
}
public TrajectoryActionBuilder actionBuilder(Pose2d beginPose) {
return new TrajectoryActionBuilder(
TurnAction::new,
FollowTrajectoryAction::new,
new TrajectoryBuilderParams(
1e-6,
new ProfileParams(
0.25, 0.1, 1e-2
)
),
beginPose, 0.0,
defaultTurnConstraints,
defaultVelConstraint, defaultAccelConstraint
);
}
}

5
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/cometbots/Constants.java
View File

@ -4,4 +4,9 @@ public class Constants {
public static double CB_BASE_SPEED = 0.2;
public static String RT_FRONT = "right hand wheel";
public static String LT_FRONT = "left hand wheel";
public static String RT_BACK = "right leg wheel";
public static String LT_BACK = "left leg wheel";
}

8
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/cometbots/MovementLibrary.java
View File

@ -12,21 +12,21 @@ public class MovementLibrary {
public static void setLeftSideForward(DcMotor[] motors) {
motors[2].setDirection(DcMotor.Direction.FORWARD);
motors[3].setDirection(DcMotor.Direction.REVERSE);
motors[3].setDirection(DcMotor.Direction.FORWARD);
}
public static void setRightSideForward(DcMotor[] motors) {
motors[0].setDirection(DcMotor.Direction.REVERSE);
motors[0].setDirection(DcMotor.Direction.FORWARD);
motors[1].setDirection(DcMotor.Direction.FORWARD);
}
public static void setLeftSideBackward(DcMotor[] motors) {
motors[2].setDirection(DcMotor.Direction.REVERSE);
motors[3].setDirection(DcMotor.Direction.FORWARD);
motors[3].setDirection(DcMotor.Direction.REVERSE);
}
public static void setRightSideBackward(DcMotor[] motors) {
motors[0].setDirection(DcMotor.Direction.FORWARD);
motors[0].setDirection(DcMotor.Direction.REVERSE);
motors[1].setDirection(DcMotor.Direction.REVERSE);
}

24
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/messages/DriveCommandMessage.java Normal file
View File

@ -0,0 +1,24 @@
package org.firstinspires.ftc.teamcode.messages;
import com.acmerobotics.roadrunner.PoseVelocity2dDual;
import com.acmerobotics.roadrunner.Time;
public final class DriveCommandMessage {
public long timestamp;
public double forwardVelocity;
public double forwardAcceleration;
public double lateralVelocity;
public double lateralAcceleration;
public double angularVelocity;
public double angularAcceleration;
public DriveCommandMessage(PoseVelocity2dDual<Time> poseVelocity) {
this.timestamp = System.nanoTime();
this.forwardVelocity = poseVelocity.linearVel.x.get(0);
this.forwardAcceleration = poseVelocity.linearVel.x.get(1);
this.lateralVelocity = poseVelocity.linearVel.y.get(0);
this.lateralAcceleration = poseVelocity.linearVel.y.get(1);
this.angularVelocity = poseVelocity.angVel.get(0);
this.angularAcceleration = poseVelocity.angVel.get(1);
}
}

19
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/messages/MecanumCommandMessage.java Normal file
View File

@ -0,0 +1,19 @@
package org.firstinspires.ftc.teamcode.messages;
public final class MecanumCommandMessage {
public long timestamp;
public double voltage;
public double leftFrontPower;
public double leftBackPower;
public double rightBackPower;
public double rightFrontPower;
public MecanumCommandMessage(double voltage, double leftFrontPower, double leftBackPower, double rightBackPower, double rightFrontPower) {
this.timestamp = System.nanoTime();
this.voltage = voltage;
this.leftFrontPower = leftFrontPower;
this.leftBackPower = leftBackPower;
this.rightBackPower = rightBackPower;
this.rightFrontPower = rightFrontPower;
}
}

30
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/messages/MecanumLocalizerInputsMessage.java Normal file
View File

@ -0,0 +1,30 @@
package org.firstinspires.ftc.teamcode.messages;
import com.acmerobotics.roadrunner.ftc.PositionVelocityPair;
import org.firstinspires.ftc.robotcore.external.navigation.AngleUnit;
import org.firstinspires.ftc.robotcore.external.navigation.YawPitchRollAngles;
public final class MecanumLocalizerInputsMessage {
public long timestamp;
public PositionVelocityPair leftFront;
public PositionVelocityPair leftBack;
public PositionVelocityPair rightBack;
public PositionVelocityPair rightFront;
public double yaw;
public double pitch;
public double roll;
public MecanumLocalizerInputsMessage(PositionVelocityPair leftFront, PositionVelocityPair leftBack, PositionVelocityPair rightBack, PositionVelocityPair rightFront, YawPitchRollAngles angles) {
this.timestamp = System.nanoTime();
this.leftFront = leftFront;
this.leftBack = leftBack;
this.rightBack = rightBack;
this.rightFront = rightFront;
{
this.yaw = angles.getYaw(AngleUnit.RADIANS);
this.pitch = angles.getPitch(AngleUnit.RADIANS);
this.roll = angles.getRoll(AngleUnit.RADIANS);
}
}
}

17
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/messages/PoseMessage.java Normal file
View File

@ -0,0 +1,17 @@
package org.firstinspires.ftc.teamcode.messages;
import com.acmerobotics.roadrunner.Pose2d;
public final class PoseMessage {
public long timestamp;
public double x;
public double y;
public double heading;
public PoseMessage(Pose2d pose) {
this.timestamp = System.nanoTime();
this.x = pose.position.x;
this.y = pose.position.y;
this.heading = pose.heading.toDouble();
}
}