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base: KeshavAnandCode:d5a3457be251fdeae571cc84af708b05a8dc3dd9
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KeshavAnandCode:master KeshavAnandCode:LimelightPID KeshavAnandCode:SpindexerUpgrades KeshavAnandCode:Targeting KeshavAnandCode:SpindexerPosUpdate KeshavAnandCode:SpindexerRefactor KeshavAnandCode:danielv2 KeshavAnandCode:organize/expand KeshavAnandCode:extracontrolhub KeshavAnandCode:daniel
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compare: KeshavAnandCode:SpindexerUpgrades
Branches Tags
KeshavAnandCode:master KeshavAnandCode:LimelightPID KeshavAnandCode:SpindexerUpgrades KeshavAnandCode:Targeting KeshavAnandCode:SpindexerPosUpdate KeshavAnandCode:SpindexerRefactor KeshavAnandCode:danielv2 KeshavAnandCode:organize/expand KeshavAnandCode:extracontrolhub KeshavAnandCode:daniel

90 Commits
d5a3457be2 ... SpindexerU

Author SHA1 Message Date
Matt9150
d1434fbaa8 Add Targeting values from shootertesting. Tune flywheel with shootertest. Add additional telemetry. 2026-01-26 01:00:03 -06:00
Matt9150
d216ce78fc Improve Spindexer shaking. Upgrade shooterTest to control the spindexer and fix flywheel real time pidf coef updates.. 2026-01-25 16:48:27 -06:00
Matt9150
8dc03adfd3 Merge with LimelightTesting. 2026-01-25 11:39:26 -06:00
Matt9150
7ffc51f60a Add shoot all ball order 2026-01-25 11:33:56 -06:00
KeshavAnandCode
7625f9a640 stash 2026-01-24 17:53:02 -06:00
DanTheMan-byte
fefeeb1f2e i need you @KeshavAnandCode 2026-01-24 17:18:57 -06:00
DanTheMan-byte
b5a31afe52 i need you @KeshavAnandCode 2026-01-24 15:42:32 -06:00
DanTheMan-byte
8d29a80696 need to add zero code to properly test 2026-01-24 14:45:35 -06:00
DanTheMan-byte
5922f4e935 need to add zero code to properly test 2026-01-23 22:50:33 -06:00
DanTheMan-byte
78d38481a7 stash 2026-01-23 21:44:29 -06:00
KeshavAnandCode
8a4bfecbf8 turret 2026-01-23 21:24:38 -06:00
KeshavAnandCode
3591e20001 Merge branch 'Targeting' 2026-01-23 20:24:16 -06:00
Matt9150
4050a354f7 Update TelopV3 and Targeting for merge conflicts. 2026-01-23 20:19:21 -06:00
KeshavAnandCode
16ffdd003f stash 2026-01-23 19:38:47 -06:00
Matt9150
f20e640c62 Merge remote-tracking branch 'origin/master' into Targeting 
# Conflicts:
#	TeamCode/src/main/java/org/firstinspires/ftc/teamcode/teleop/TeleopV3.java
#	TeamCode/src/main/java/org/firstinspires/ftc/teamcode/tests/TurretTest.java
#	TeamCode/src/main/java/org/firstinspires/ftc/teamcode/utils/Turret.java
 2026-01-22 22:13:07 -06:00
Matt9150
c2e9d8fa87 Merge remote-tracking branch 'origin/Targeting' into Targeting 2026-01-22 22:00:41 -06:00
Matt9150
46a5366a4a Add Auto ball detect on startup to spindexer to detect how many balls are already in spindexer on power on. 2026-01-22 21:59:58 -06:00
KeshavAnandCode
fbdeb6e291 Turret works y8ippee horray hurrah ig 2026-01-22 21:04:25 -06:00
abhiram vishnubhotla
298b7bca8c Merge pull request #13 from Technical-Turbulence-FTC/feature/interpolation 
Feature/interpolation
 2026-01-22 20:21:05 -06:00
abhiramtx
2f0fcad128 updated interpolation in teleop 2026-01-22 20:06:08 -06:00
abhiramtx
45199b952b added interpolation 2026-01-22 20:03:00 -06:00
abhiramtx
76ceb91fb7 Merge branch 'Targeting' of https://github.com/Technical-Turbulence-FTC/DecodeFTCMain into turret-refactor-updates 2026-01-22 19:28:42 -06:00
Matt9150
daccec4fdd Add Targeting Class with initial values that still need tuning. Connect Targeting Class to TeleOpV3. Clean up unused code in Flywheel class. 2026-01-22 00:00:17 -06:00
abhiramtx
b55d44ae97 Merge branch 'Targeting' of https://github.com/Technical-Turbulence-FTC/DecodeFTCMain into turret-refactor-updates 2026-01-21 20:01:22 -06:00
abhiramtx
50212015e3 trackGoal expected robot centric view, but was fed a field centric view. simple trig to use a deltaPos instead of just pos 2026-01-21 19:04:30 -06:00
abhiramtx
c271c88e45 Merge branch 'master' of https://github.com/Technical-Turbulence-FTC/DecodeFTCMain into test/continuous_ll_track 2026-01-21 18:36:06 -06:00
Matt9150
33300876ef Merge remote-tracking branch 'origin/master' into Targeting 2026-01-21 09:28:59 -06:00
Matt9150
e1745500cc Create new targeting class. Fix Flywheel Error with motor2 velocity and include spindexer pos updates. 2026-01-21 09:28:21 -06:00
KeshavAnandCode
0dbf155608 stash 2026-01-20 21:18:42 -06:00
KeshavAnandCode
313eeeaa95 Merge remote-tracking branch 'origin/SpindexerPosUpdate' 2026-01-20 20:59:56 -06:00
KeshavAnandCode
b28647373a no errors 2026-01-20 20:57:14 -06:00
KeshavAnandCode
7e7254aaea turret refaftoring 2026-01-20 20:52:23 -06:00
Matt9150
e7dfa11196 New Spindexer Positions after repair. 2026-01-20 20:38:40 -06:00
abhiramtx
a3068cea2e Merge branch 'SpindexerRefactor' of https://github.com/Technical-Turbulence-FTC/DecodeFTCMain into test/continuous_ll_track 2026-01-20 19:17:16 -06:00
Matt9150
51bf55cc49 Merge remote-tracking branch 'origin/SpindexerRefactor' into SpindexerRefactor 2026-01-19 23:40:52 -06:00
Matt9150
6f3a178a08 Comment out color sensor reads for now to speed up loop times. 2026-01-19 23:40:17 -06:00
DanTheMan-byte
ccb52f625d error check 2026-01-19 20:42:22 -06:00
DanTheMan-byte
8f92dc8f31 test 2026-01-19 20:28:13 -06:00
Matt9150
40d51ce757 Working Spindexer prototype with original shoot all functionality. 2026-01-19 19:39:01 -06:00
Matt9150
cfd09df8a0 Working Spindexer prototype with original shoot all functionality. 2026-01-19 11:11:22 -06:00
abhiramtx
f1d4bb9d24 continous ll tracking, TEST 2026-01-19 10:38:34 -06:00
Matt9150
59796154bd Switched to built in FTC PIDF Controls. 2026-01-18 11:19:54 -06:00
KeshavAnandCode
d42af20447 woag 2026-01-17 14:26:15 -06:00
KeshavAnandCode
1c292e77c7 Working red auto apparently...blue is theoretial atp 2026-01-17 13:50:58 -06:00
KeshavAnandCode
fde0880225 Working red auto apparently...blue is theoretial atp 2026-01-17 09:44:06 -06:00
KeshavAnandCode
e8bf2033ad yayyy 2026-01-17 00:53:05 -06:00
KeshavAnandCode
de6e7f2910 stadg 2026-01-16 23:06:05 -06:00
KeshavAnandCode
ef5d615f91 yoooo 2026-01-16 20:29:32 -06:00
KeshavAnandCode
4aca64f61c Merge remote-tracking branch 'origin/master' 2026-01-15 21:05:18 -06:00
KeshavAnandCode
bfcecd42d3 @Abhiram pls fix this 2026-01-15 21:04:56 -06:00
KeshavAnandCode
66e76285b2 update 2026-01-14 22:57:32 -06:00
KeshavAnandCode
7b923f31ca Merge branch 'danielv2' 2026-01-14 19:25:45 -06:00
KeshavAnandCode
d3bbbb7f2b Merge branch 'danielv2' 
# Conflicts:
#	TeamCode/src/main/java/org/firstinspires/ftc/teamcode/autonomous/Blue_V2.java
#	TeamCode/src/main/java/org/firstinspires/ftc/teamcode/autonomous/Red_V2.java
#	TeamCode/src/main/java/org/firstinspires/ftc/teamcode/teleop/TeleopV2.java
#	TeamCode/src/main/java/org/firstinspires/ftc/teamcode/utils/PositionalServoProgrammer.java
 2026-01-14 19:25:20 -06:00
DanTheMan-byte
c160b3fa6b configuration preparation 2026-01-13 22:10:16 -06:00
DanTheMan-byte
de52f86280 fixed some flywheel stuff 2026-01-13 19:50:24 -06:00
DanTheMan-byte
58e7289c7b new auton that is very simple 2026-01-12 20:55:09 -06:00
DanTheMan-byte
46ed4f544f auton is updated - to be tested 2026-01-12 20:17:44 -06:00
DanTheMan-byte
e39fa396cb started updating the auto 2026-01-11 18:21:03 -06:00
DanTheMan-byte
5e8727ebaa stash 2026-01-11 17:46:08 -06:00
DanTheMan-byte
c460a4fb7a stash 2026-01-11 17:24:23 -06:00
DanTheMan-byte
301b5ec765 stash 2026-01-11 17:20:50 -06:00
DanTheMan-byte
70ad084ab1 new teleop draft 2026-01-11 17:19:54 -06:00
KeshavAnandCode
70ca5b814a daniel 2026-01-11 15:54:22 -06:00
DanTheMan-byte
d81a189ef9 intake test was tested with good results in both modes 2026-01-10 21:06:57 -06:00
DanTheMan-byte
82c3c83262 stash 2026-01-09 22:21:03 -06:00
DanTheMan-byte
b9e6dff3f8 intake test to be further tested into crowded balls 2026-01-09 22:18:25 -06:00
DanTheMan-byte
8e8629f624 spindex pid tuned 2026-01-08 20:44:18 -06:00
DanTheMan-byte
d967e0489d stash 2026-01-08 20:17:13 -06:00
DanTheMan-byte
16d9a13376 spindex is built, needs improvement 2026-01-06 22:50:37 -06:00
DanTheMan-byte
7f3ca719fa todo 2026-01-05 16:13:19 -06:00
DanTheMan-byte
475fc4fe1c stash 2026-01-05 14:57:42 -06:00
DanTheMan-byte
9c2a86c3e6 limelight added to code 2026-01-04 17:48:49 -06:00
DanTheMan-byte
d37bc733cf stash 2026-01-04 16:07:45 -06:00
DanTheMan-byte
4588321b44 added webcam to Red_V2.java and changed localization in TeleopV2.java 2026-01-03 18:15:12 -06:00
DanTheMan-byte
4b998766a1 stash 2026-01-03 15:55:35 -06:00
DanTheMan-byte
07297c60f1 stash 2026-01-02 13:31:00 -06:00
DanTheMan-byte
0bf392f81f added continous servos and smoother velocity PID 2026-01-02 00:17:28 -06:00
DanTheMan-byte
05412940e8 edited Flywheel.java 2026-01-01 22:39:02 -06:00
DanTheMan-byte
054b6de169 stash 2025-12-31 16:54:38 -06:00
DanTheMan-byte
75b3dc7fd4 stash 2025-12-31 16:53:59 -06:00
DanTheMan-byte
e3c259587e stash 2025-12-31 16:52:20 -06:00
DanTheMan-byte
b10a723f37 stash 2025-12-31 16:51:27 -06:00
DanTheMan-byte
ca37fa078c stash 2025-12-31 16:41:40 -06:00
DanTheMan-byte
ddc159ba3c stash 2025-12-31 16:40:55 -06:00
DanTheMan-byte
713bafd9b4 stash 2025-12-31 16:39:43 -06:00
DanTheMan-byte
61f314d71d stash 2025-12-31 16:36:06 -06:00
Keshav Anand
1e87410d7b Merge pull request #5 from Technical-Turbulence-FTC/copilot/modularize-teleop-subsystems 
[WIP] Modularize teleop code into subsystems
 2025-12-14 15:50:03 -06:00
copilot-swe-agent[bot]
a7d1c18c56 Initial plan 2025-12-14 21:47:27 +00:00
DanTheMan-byte
a58371d3d7 stash 2025-12-05 20:42:03 -06:00
DanTheMan-byte
f48788cfd0 stash 2025-12-05 19:27:30 -06:00
29 changed files with 4649 additions and 1619 deletions
Expand all files Collapse all files

479
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/autonomous/Blue_V2.java → TeamCode/src/main/java/org/firstinspires/ftc/teamcode/autonomous/AutoClose_V3.java
View File

@@ -1,10 +1,9 @@
package org.firstinspires.ftc.teamcode.autonomous; package org.firstinspires.ftc.teamcode.autonomous;
import static org.firstinspires.ftc.teamcode.constants.Color.*;
import static org.firstinspires.ftc.teamcode.constants.Poses.*; import static org.firstinspires.ftc.teamcode.constants.Poses.*;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.*; import static org.firstinspires.ftc.teamcode.constants.ServoPositions.*;
import static org.firstinspires.ftc.teamcode.constants.ShooterVars.*; import static org.firstinspires.ftc.teamcode.constants.ShooterVars.*;
import static org.firstinspires.ftc.teamcode.utils.PositionalServoProgrammer.*;
import androidx.annotation.NonNull; import androidx.annotation.NonNull;
@@ -19,156 +18,81 @@ import com.acmerobotics.roadrunner.SequentialAction;
import com.acmerobotics.roadrunner.TrajectoryActionBuilder; import com.acmerobotics.roadrunner.TrajectoryActionBuilder;
import com.acmerobotics.roadrunner.Vector2d; import com.acmerobotics.roadrunner.Vector2d;
import com.acmerobotics.roadrunner.ftc.Actions; import com.acmerobotics.roadrunner.ftc.Actions;
import com.qualcomm.hardware.limelightvision.LLResult;
import com.qualcomm.hardware.limelightvision.LLResultTypes;
import com.qualcomm.robotcore.eventloop.opmode.Autonomous; import com.qualcomm.robotcore.eventloop.opmode.Autonomous;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode; import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import org.firstinspires.ftc.robotcore.external.navigation.DistanceUnit; import org.firstinspires.ftc.robotcore.external.navigation.DistanceUnit;
import org.firstinspires.ftc.teamcode.libs.RR.MecanumDrive; import org.firstinspires.ftc.teamcode.libs.RR.MecanumDrive;
import org.firstinspires.ftc.teamcode.utils.AprilTagWebcam; import org.firstinspires.ftc.teamcode.utils.FlywheelV2;
import org.firstinspires.ftc.teamcode.utils.Flywheel;
import org.firstinspires.ftc.teamcode.utils.Robot; import org.firstinspires.ftc.teamcode.utils.Robot;
import org.firstinspires.ftc.teamcode.utils.Servos;
import java.util.List;
@Config @Config
@Autonomous(preselectTeleOp = "TeleopV2") @Autonomous(preselectTeleOp = "TeleopV3")
public class Blue_V2 extends LinearOpMode { public class AutoClose_V3 extends LinearOpMode {
Robot robot; Robot robot;
MultipleTelemetry TELE; MultipleTelemetry TELE;
MecanumDrive drive; MecanumDrive drive;
FlywheelV2 flywheel;
AprilTagWebcam aprilTag; Servos servo;
Flywheel flywheel;
double velo = 0.0; double velo = 0.0;
double targetVelocity = 0.0; public static double intake1Time = 2.7;
public static double intake1Time = 2.9; public static double intake2Time = 3.0;
public static double intake2Time = 2.9;
public static double colorDetect = 3.0; public static double colorDetect = 3.0;
boolean gpp = false; boolean gpp = false;
boolean pgp = false; boolean pgp = false;
boolean ppg = false; boolean ppg = false;
double powPID = 0.0; double powPID = 0.0;
double bearing = 0.0;
int b1 = 0; // 0 = no ball, 1 = green, 2 = purple int b1 = 0; // 0 = no ball, 1 = green, 2 = purple
int b2 = 0;// 0 = no ball, 1 = green, 2 = purple int b2 = 0;// 0 = no ball, 1 = green, 2 = purple
int b3 = 0;// 0 = no ball, 1 = green, 2 = purple int b3 = 0;// 0 = no ball, 1 = green, 2 = purple
public static double holdTurrPow = 0.1; // power to hold turret in place
boolean spindexPosEqual(double spindexer) {
TELE.addData("Velocity", velo);
TELE.addLine("spindex equal");
TELE.update();
return (scalar * ((robot.spin1Pos.getVoltage() - restPos) / 3.3) > spindexer - 0.01 &&
scalar * ((robot.spin1Pos.getVoltage() - restPos) / 3.3) < spindexer + 0.01);
}
public Action initShooter(int vel) { public Action initShooter(int vel) {
return new Action() { return new Action() {
double initPos = 0.0;
double stamp = 0.0;
double stamp1 = 0.0;
double ticker = 0.0;
double stamp2 = 0.0;
double currentPos = 0.0;
boolean steady = false;
public boolean run(@NonNull TelemetryPacket telemetryPacket) { public boolean run(@NonNull TelemetryPacket telemetryPacket) {
if (ticker == 0) { powPID = flywheel.manageFlywheel(vel, robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
stamp2 = getRuntime(); velo = flywheel.getVelo(robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
}
targetVelocity = (double) vel;
ticker++;
if (ticker % 16 == 0) {
stamp = getRuntime();
stamp1 = stamp;
}
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition());
velo = flywheel.getVelo();
robot.shooter1.setPower(powPID); robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID); robot.shooter2.setPower(powPID);
robot.transfer.setPower(1);
TELE.addData("Velocity", velo);
TELE.update();
if (vel < velo && getRuntime() - stamp2 > 3.0 && !steady){
steady = true;
stamp2 = getRuntime();
return true;
} else if (steady && getRuntime() - stamp2 > 1.5){
TELE.addData("Velocity", velo);
TELE.addLine("finished init");
TELE.update();
return false;
} else {
return true;
}
}
};
}
public Action steadyShooter(int vel, boolean last) {
return new Action() {
double stamp = 0.0;
boolean steady = false;
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition());
velo = flywheel.getVelo();
steady = flywheel.getSteady();
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
robot.transfer.setPower(1);
TELE.addData("Velocity", velo); TELE.addData("Velocity", velo);
TELE.update(); TELE.update();
return !flywheel.getSteady();
if (last && !steady){
stamp = getRuntime();
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
return false;
} else if (steady) {
stamp = getRuntime();
return true;
} else {
return true;
}
} }
}; };
} }
public Action Obelisk() { public Action Obelisk() {
return new Action() { return new Action() {
double stamp = getRuntime(); int id = 0;
int ticker = 0;
@Override @Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) { public boolean run(@NonNull TelemetryPacket telemetryPacket) {
if (ticker == 0) { LLResult result = robot.limelight.getLatestResult();
stamp = getRuntime(); if (result != null && result.isValid()) {
} List<LLResultTypes.FiducialResult> fiducials = result.getFiducialResults();
ticker++; for (LLResultTypes.FiducialResult fiducial : fiducials) {
id = fiducial.getFiducialId();
TELE.addData("ID", id);
TELE.update();
}
if (aprilTag.getTagById(21) != null) { }
if (id == 21){
gpp = true; gpp = true;
} else if (aprilTag.getTagById(22) != null) { } else if (id == 22){
pgp = true; pgp = true;
} else if (aprilTag.getTagById(23) != null) { } else if (id == 23){
ppg = true; ppg = true;
} }
aprilTag.update();
TELE.addData("Velocity", velo); TELE.addData("Velocity", velo);
TELE.addData("21", gpp); TELE.addData("21", gpp);
@@ -176,10 +100,21 @@ public class Blue_V2 extends LinearOpMode {
TELE.addData("23", ppg); TELE.addData("23", ppg);
TELE.update(); TELE.update();
if (gpp || pgp || ppg){ if (gpp || pgp || ppg) {
robot.turr1.setPosition(turret_blue); if (redAlliance){
robot.turr2.setPosition(1 - turret_blue); robot.limelight.pipelineSwitch(3);
return false; double turretPID = turret_redClose;
robot.turr1.setPosition(turretPID);
robot.turr2.setPosition(-turretPID);
return false;
} else {
robot.limelight.pipelineSwitch(2);
double turretPID = turret_blueClose;
robot.turr1.setPosition(turretPID);
robot.turr2.setPosition(-turretPID);
return false;
}
} else { } else {
return true; return true;
} }
@@ -187,151 +122,59 @@ public class Blue_V2 extends LinearOpMode {
}; };
} }
public Action intakeReject() { public Action spindex(double spindexer, int vel) {
return new Action() { return new Action() {
double stamp = 0.0; double spinPID = 0.0;
int ticker = 0;
@Override @Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) { public boolean run(@NonNull TelemetryPacket telemetryPacket) {
powPID = flywheel.manageFlywheel(vel, robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
double position = 0.0; velo = flywheel.getVelo(robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
if ((getRuntime() % 0.3) > 0.15) {
position = spindexer_intakePos1 + 0.02;
} else {
position = spindexer_intakePos1 - 0.02;
}
robot.spin1.setPosition(position);
robot.spin2.setPosition(1 - position);
if (ticker == 0) {
stamp = getRuntime();
}
ticker++;
if (getRuntime() - stamp < 0.3){
return true;
}else {
robot.intake.setPower(0);
return false;
}
}
};
}
public Action spindex (double spindexer, double vel){
return new Action() {
double currentPos = 0.0;
double stamp = 0.0;
double initPos = 0.0;
double stamp1 = 0.0;
int ticker = 0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
ticker++;
if (ticker % 8 == 0) {
currentPos = (double) robot.shooter1.getCurrentPosition() / 2048;
stamp = getRuntime();
velo = -60 * ((currentPos - initPos) / (stamp - stamp1));
initPos = currentPos;
stamp1 = stamp;
}
if (vel - velo > 500 && ticker > 16) {
powPID = 1.0;
} else if (velo - vel > 500 && ticker > 16){
powPID = 0.0;
} else if (Math.abs(vel - velo) < 100 && ticker > 16){
double feed = Math.log((668.39 / (vel + 591.96)) - 0.116) / -4.18;
// --- PROPORTIONAL CORRECTION ---
double error = vel - velo;
double correction = kP * error;
// limit how fast power changes (prevents oscillation)
correction = Math.max(-maxStep, Math.min(maxStep, correction));
// --- FINAL MOTOR POWER ---
powPID = feed + correction;
// clamp to allowed range
powPID = Math.max(0, Math.min(1, powPID));
}
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition());
velo = flywheel.getVelo();
robot.shooter1.setPower(powPID); robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID); robot.shooter2.setPower(powPID);
robot.spin1.setPosition(spindexer);
robot.spin2.setPosition(1-spindexer); spinPID = servo.setSpinPos(spindexer);
robot.spin1.setPower(spinPID);
robot.spin2.setPower(-spinPID);
TELE.addData("Velocity", velo); TELE.addData("Velocity", velo);
TELE.addLine("spindex"); TELE.addLine("spindex");
TELE.update(); TELE.update();
drive.updatePoseEstimate(); drive.updatePoseEstimate();
teleStart = drive.localizer.getPose(); teleStart = drive.localizer.getPose();
return !spindexPosEqual(spindexer); if (servo.spinEqual(spindexer)){
robot.spin1.setPower(0);
robot.spin2.setPower(0);
return false;
} else {
return true;
}
} }
}; };
} }
public Action Shoot(double vel) { public Action Shoot(int vel) {
return new Action() { return new Action() {
double transferStamp = 0.0; double transferStamp = 0.0;
int ticker = 1; int ticker = 1;
boolean transferIn = false; boolean transferIn = false;
double currentPos = 0.0;
double stamp = 0.0;
double initPos = 0.0;
double stamp1 = 0.0;
@Override @Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) { public boolean run(@NonNull TelemetryPacket telemetryPacket) {
TELE.addData("Velocity", velo); TELE.addData("Velocity", velo);
TELE.addLine("shooting"); TELE.addLine("shooting");
TELE.update(); TELE.update();
if (ticker % 8 == 0) { powPID = flywheel.manageFlywheel(vel, robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
currentPos = (double) robot.shooter1.getCurrentPosition() / 2048; velo = flywheel.getVelo(robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
stamp = getRuntime();
velo = -60 * ((currentPos - initPos) / (stamp - stamp1));
initPos = currentPos;
stamp1 = stamp;
}
if (vel - velo > 500 && ticker > 16) {
powPID = 1.0;
} else if (velo - vel > 500 && ticker > 16){
powPID = 0.0;
} else if (Math.abs(vel - velo) < 100 && ticker > 16){
double feed = Math.log((668.39 / (vel + 591.96)) - 0.116) / -4.18;
// --- PROPORTIONAL CORRECTION ---
double error = vel - velo;
double correction = kP * error;
// limit how fast power changes (prevents oscillation)
correction = Math.max(-maxStep, Math.min(maxStep, correction));
// --- FINAL MOTOR POWER ---
powPID = feed + correction;
// clamp to allowed range
powPID = Math.max(0, Math.min(1, powPID));
}
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition());
velo = flywheel.getVelo();
robot.shooter1.setPower(powPID); robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID); robot.shooter2.setPower(powPID);
drive.updatePoseEstimate(); drive.updatePoseEstimate();
detectTag();
teleStart = drive.localizer.getPose(); teleStart = drive.localizer.getPose();
if (ticker == 1) { if (ticker == 1) {
transferStamp = getRuntime(); transferStamp = getRuntime();
ticker++; ticker++;
@@ -343,8 +186,10 @@ public class Blue_V2 extends LinearOpMode {
TELE.update(); TELE.update();
transferIn = true; transferIn = true;
return true; return true;
} else if (getRuntime() - transferStamp > waitTransfer+waitTransferOut && transferIn){ } else if (getRuntime() - transferStamp > waitTransfer + waitTransferOut && transferIn) {
robot.transferServo.setPosition(transferServo_out); robot.transferServo.setPosition(transferServo_out);
robot.turr1.setPosition(holdTurrPow);
robot.turr2.setPosition(holdTurrPow);
TELE.addData("Velocity", velo); TELE.addData("Velocity", velo);
TELE.addLine("shot once"); TELE.addLine("shot once");
TELE.update(); TELE.update();
@@ -359,9 +204,10 @@ public class Blue_V2 extends LinearOpMode {
public Action intake(double intakeTime) { public Action intake(double intakeTime) {
return new Action() { return new Action() {
double position = 0.0; double position = spindexer_intakePos1;
double stamp = 0.0; double stamp = 0.0;
int ticker = 0; int ticker = 0;
double pow = 1.0;
@Override @Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) { public boolean run(@NonNull TelemetryPacket telemetryPacket) {
@@ -370,17 +216,38 @@ public class Blue_V2 extends LinearOpMode {
} }
ticker++; ticker++;
robot.intake.setPower(pow);
double s1D = robot.color1.getDistance(DistanceUnit.MM); double s1D = robot.color1.getDistance(DistanceUnit.MM);
double s2D = robot.color2.getDistance(DistanceUnit.MM); double s2D = robot.color2.getDistance(DistanceUnit.MM);
double s3D = robot.color3.getDistance(DistanceUnit.MM); double s3D = robot.color3.getDistance(DistanceUnit.MM);
if ((getRuntime() % 0.3) > 0.15) { if (!servo.spinEqual(position)){
position = spindexer_intakePos1 + 0.02; double spinPID = servo.setSpinPos(position);
} else { robot.spin1.setPower(spinPID);
position = spindexer_intakePos1 - 0.02; robot.spin2.setPower(-spinPID);
}
if (s1D < 43 && servo.spinEqual(position) && getRuntime() - stamp > 0.5){
if (s2D > 60){
if (servo.spinEqual(spindexer_intakePos1)){
position = spindexer_intakePos2;
} else if (servo.spinEqual(spindexer_intakePos2)){
position = spindexer_intakePos3;
} else if (servo.spinEqual(spindexer_intakePos3)){
position = spindexer_intakePos1;
}
} else if (s3D > 33){
if (servo.spinEqual(spindexer_intakePos1)){
position = spindexer_intakePos3;
} else if (servo.spinEqual(spindexer_intakePos2)){
position = spindexer_intakePos1;
} else if (servo.spinEqual(spindexer_intakePos3)){
position = spindexer_intakePos2;
}
}
stamp = getRuntime();
} }
robot.spin1.setPosition(position);
robot.spin2.setPosition(1 - position);
TELE.addData("Velocity", velo); TELE.addData("Velocity", velo);
TELE.addLine("Intaking"); TELE.addLine("Intaking");
@@ -391,8 +258,16 @@ public class Blue_V2 extends LinearOpMode {
teleStart = drive.localizer.getPose(); teleStart = drive.localizer.getPose();
robot.intake.setPower(1); robot.intake.setPower(1);
if ((s1D < 40.0 && s2D < 40.0 && s3D < 40.0) || getRuntime() - stamp > intakeTime) { if ((s1D < 43.0 && s2D < 60.0 && s3D < 33.0) || getRuntime() - stamp > intakeTime) {
return false; robot.spin1.setPower(0);
robot.spin2.setPower(0);
if (getRuntime() - stamp - intakeTime < 1){
pow = -2*(getRuntime() - stamp - intakeTime);
return true;
} else {
robot.intake.setPower(0);
return false;
}
} else { } else {
return true; return true;
} }
@@ -400,11 +275,10 @@ public class Blue_V2 extends LinearOpMode {
}; };
} }
public Action ColorDetect() { public Action ColorDetect(int vel) {
return new Action() { return new Action() {
double stamp = 0.0; double stamp = 0.0;
int ticker = 0; int ticker = 0;
double position = 0.0;
@Override @Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) { public boolean run(@NonNull TelemetryPacket telemetryPacket) {
if (ticker == 0) { if (ticker == 0) {
@@ -412,13 +286,10 @@ public class Blue_V2 extends LinearOpMode {
} }
ticker++; ticker++;
if ((getRuntime() % 0.3) > 0.15) { powPID = flywheel.manageFlywheel(vel, robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
position = spindexer_intakePos1 + 0.02; velo = flywheel.getVelo(robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
} else { robot.shooter1.setPower(powPID);
position = spindexer_intakePos1 - 0.02; robot.shooter2.setPower(powPID);
}
robot.spin1.setPosition(position);
robot.spin2.setPosition(1 - position);
double s1D = robot.color1.getDistance(DistanceUnit.MM); double s1D = robot.color1.getDistance(DistanceUnit.MM);
double s2D = robot.color2.getDistance(DistanceUnit.MM); double s2D = robot.color2.getDistance(DistanceUnit.MM);
@@ -428,7 +299,7 @@ public class Blue_V2 extends LinearOpMode {
teleStart = drive.localizer.getPose(); teleStart = drive.localizer.getPose();
if (s1D < 40) { if (s1D < 43) {
double green = robot.color1.getNormalizedColors().green; double green = robot.color1.getNormalizedColors().green;
double red = robot.color1.getNormalizedColors().red; double red = robot.color1.getNormalizedColors().red;
@@ -436,8 +307,6 @@ public class Blue_V2 extends LinearOpMode {
double gP = green / (green + red + blue); double gP = green / (green + red + blue);
if (gP >= 0.4) { if (gP >= 0.4) {
b1 = 2; b1 = 2;
} else { } else {
@@ -445,7 +314,7 @@ public class Blue_V2 extends LinearOpMode {
} }
} }
if (s2D < 40) { if (s2D < 60) {
double green = robot.color2.getNormalizedColors().green; double green = robot.color2.getNormalizedColors().green;
double red = robot.color2.getNormalizedColors().red; double red = robot.color2.getNormalizedColors().red;
@@ -460,7 +329,7 @@ public class Blue_V2 extends LinearOpMode {
} }
} }
if (s3D < 30) { if (s3D < 33) {
double green = robot.color3.getNormalizedColors().green; double green = robot.color3.getNormalizedColors().green;
double red = robot.color3.getNormalizedColors().red; double red = robot.color3.getNormalizedColors().red;
@@ -495,7 +364,7 @@ public class Blue_V2 extends LinearOpMode {
robot = new Robot(hardwareMap); robot = new Robot(hardwareMap);
flywheel = new Flywheel(); flywheel = new FlywheelV2();
TELE = new MultipleTelemetry( TELE = new MultipleTelemetry(
telemetry, FtcDashboard.getInstance().getTelemetry() telemetry, FtcDashboard.getInstance().getTelemetry()
@@ -505,7 +374,8 @@ public class Blue_V2 extends LinearOpMode {
0, 0, 0 0, 0, 0
)); ));
aprilTag = new AprilTagWebcam(); robot.limelight.pipelineSwitch(1);
robot.limelight.start();
TrajectoryActionBuilder shoot0 = drive.actionBuilder(new Pose2d(0, 0, 0)) TrajectoryActionBuilder shoot0 = drive.actionBuilder(new Pose2d(0, 0, 0))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1); .strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
@@ -518,38 +388,78 @@ public class Blue_V2 extends LinearOpMode {
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1); .strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
TrajectoryActionBuilder pickup2 = drive.actionBuilder(new Pose2d(bx1, by1, bh1)) TrajectoryActionBuilder pickup2 = drive.actionBuilder(new Pose2d(bx1, by1, bh1))
.strafeToLinearHeading(new Vector2d(bx3a, by3a), bh3a) .strafeToLinearHeading(new Vector2d(bx3a, by3a), bh3a)
.strafeToLinearHeading(new Vector2d(bx3b, by3b), bh3b); .strafeToLinearHeading(new Vector2d(bx3b, by3b), bh3b);
TrajectoryActionBuilder shoot2 = drive.actionBuilder(new Pose2d(bx3b, by3b, bh3b)) TrajectoryActionBuilder shoot2 = drive.actionBuilder(new Pose2d(bx3b, by3b, bh3b))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1); .strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
aprilTag.init(robot, TELE);
while (opModeInInit()) { while (opModeInInit()) {
if (gamepad2.dpadUpWasPressed()) { if (gamepad2.dpadUpWasPressed()) {
hoodAuto-= 0.01; hoodAuto -= 0.01;
} }
if (gamepad2.dpadDownWasPressed()) { if (gamepad2.dpadDownWasPressed()) {
hoodAuto += 0.01; hoodAuto += 0.01;
} }
robot.hood.setPosition(hoodAuto); if (gamepad2.crossWasPressed()){
redAlliance = !redAlliance;
}
robot.turr1.setPosition(turret_detectBlue); double turrPID;
robot.turr2.setPosition(1 - turret_detectBlue);
if (redAlliance){
turrPID = turret_detectRedClose;
shoot0 = drive.actionBuilder(new Pose2d(0, 0, 0))
.strafeToLinearHeading(new Vector2d(rx1, ry1), rh1);
pickup1 = drive.actionBuilder(new Pose2d(rx1, ry1, rh1))
.strafeToLinearHeading(new Vector2d(rx2a, ry2a), rh2a)
.strafeToLinearHeading(new Vector2d(rx2b, ry2b), rh2b);
shoot1 = drive.actionBuilder(new Pose2d(rx2b, ry2b, rh2b))
.strafeToLinearHeading(new Vector2d(rx1, ry1), rh1);
pickup2 = drive.actionBuilder(new Pose2d(rx1, ry1, rh1))
.strafeToLinearHeading(new Vector2d(rx3a, ry3a), rh3a)
.strafeToLinearHeading(new Vector2d(rx3b, ry3b), rh3b);
shoot2 = drive.actionBuilder(new Pose2d(rx3b, ry3b, rh3b))
.strafeToLinearHeading(new Vector2d(rx1, ry1), rh1);
} else {
turrPID = turret_detectBlueClose;
shoot0 = drive.actionBuilder(new Pose2d(0, 0, 0))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
pickup1 = drive.actionBuilder(new Pose2d(bx1, by1, bh1))
.strafeToLinearHeading(new Vector2d(bx2a, by2a), bh2a)
.strafeToLinearHeading(new Vector2d(bx2b, by2b), bh2b);
shoot1 = drive.actionBuilder(new Pose2d(bx2b, by2b, bh2b))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
pickup2 = drive.actionBuilder(new Pose2d(bx1, by1, bh1))
.strafeToLinearHeading(new Vector2d(bx3a, by3a), bh3a)
.strafeToLinearHeading(new Vector2d(bx3b, by3b), bh3b);
shoot2 = drive.actionBuilder(new Pose2d(bx3b, by3b, bh3b))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
}
robot.turr1.setPosition(turrPID);
robot.turr2.setPosition(-turrPID);
robot.hood.setPosition(hoodAuto);
robot.transferServo.setPosition(transferServo_out); robot.transferServo.setPosition(transferServo_out);
robot.spin1.setPosition(spindexer_intakePos1);
robot.spin2.setPosition(1 - spindexer_intakePos1);
aprilTag.update();
TELE.addData("Velocity", velo); TELE.addData("Velocity", velo);
TELE.addData("Turret Pos", servo.getTurrPos());
TELE.addData("Spin Pos", servo.getSpinPos());
TELE.update(); TELE.update();
} }
@@ -559,8 +469,6 @@ public class Blue_V2 extends LinearOpMode {
if (opModeIsActive()) { if (opModeIsActive()) {
robot.hood.setPosition(hoodAuto);
Actions.runBlocking( Actions.runBlocking(
new ParallelAction( new ParallelAction(
shoot0.build(), shoot0.build(),
@@ -572,14 +480,11 @@ public class Blue_V2 extends LinearOpMode {
teleStart = drive.localizer.getPose(); teleStart = drive.localizer.getPose();
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition()); robot.transfer.setPower(1);
velo = flywheel.getVelo();
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
shootingSequence(); shootingSequence();
robot.hood.setPosition(hoodAuto); robot.transfer.setPower(0);
drive.updatePoseEstimate(); drive.updatePoseEstimate();
@@ -598,9 +503,7 @@ public class Blue_V2 extends LinearOpMode {
Actions.runBlocking( Actions.runBlocking(
new ParallelAction( new ParallelAction(
shoot1.build(), shoot1.build(),
ColorDetect(), ColorDetect(AUTO_CLOSE_VEL)
steadyShooter(AUTO_CLOSE_VEL, true),
intakeReject()
) )
); );
@@ -608,12 +511,12 @@ public class Blue_V2 extends LinearOpMode {
teleStart = drive.localizer.getPose(); teleStart = drive.localizer.getPose();
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition()); robot.transfer.setPower(1);
velo = flywheel.getVelo();
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
shootingSequence(); shootingSequence();
robot.transfer.setPower(0);
drive.updatePoseEstimate(); drive.updatePoseEstimate();
teleStart = drive.localizer.getPose(); teleStart = drive.localizer.getPose();
@@ -631,19 +534,16 @@ public class Blue_V2 extends LinearOpMode {
Actions.runBlocking( Actions.runBlocking(
new ParallelAction( new ParallelAction(
shoot2.build(), shoot2.build(),
ColorDetect(), ColorDetect(AUTO_CLOSE_VEL)
steadyShooter(AUTO_CLOSE_VEL, true),
intakeReject()
) )
); );
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition()); robot.transfer.setPower(1);
velo = flywheel.getVelo();
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
shootingSequence(); shootingSequence();
robot.transfer.setPower(0);
drive.updatePoseEstimate(); drive.updatePoseEstimate();
teleStart = drive.localizer.getPose(); teleStart = drive.localizer.getPose();
@@ -657,6 +557,19 @@ public class Blue_V2 extends LinearOpMode {
} }
} }
//TODO: adjust this according to Teleop numbers
public void detectTag() {
LLResult result = robot.limelight.getLatestResult();
if (result != null) {
if (result.isValid()) {
bearing = result.getTx();
}
}
double turretPos = servo.getTurrPos() - (bearing / 1300);
double turretPID = turretPos;
robot.turr1.setPosition(turretPID);
robot.turr2.setPosition(-turretPID);
}
public void shootingSequence() { public void shootingSequence() {
TELE.addData("Velocity", velo); TELE.addData("Velocity", velo);

651
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/autonomous/AutoFar_V1.java Normal file
View File

@@ -0,0 +1,651 @@
package org.firstinspires.ftc.teamcode.autonomous;
import static org.firstinspires.ftc.teamcode.constants.Color.*;
import static org.firstinspires.ftc.teamcode.constants.Poses.*;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.*;
import static org.firstinspires.ftc.teamcode.constants.ShooterVars.*;
import androidx.annotation.NonNull;
import com.acmerobotics.dashboard.FtcDashboard;
import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
import com.acmerobotics.dashboard.telemetry.TelemetryPacket;
import com.acmerobotics.roadrunner.Action;
import com.acmerobotics.roadrunner.ParallelAction;
import com.acmerobotics.roadrunner.Pose2d;
import com.acmerobotics.roadrunner.SequentialAction;
import com.acmerobotics.roadrunner.TrajectoryActionBuilder;
import com.acmerobotics.roadrunner.Vector2d;
import com.acmerobotics.roadrunner.ftc.Actions;
import com.qualcomm.hardware.limelightvision.LLResult;
import com.qualcomm.hardware.limelightvision.LLResultTypes;
import com.qualcomm.robotcore.eventloop.opmode.Autonomous;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import org.firstinspires.ftc.robotcore.external.navigation.DistanceUnit;
import org.firstinspires.ftc.teamcode.libs.RR.MecanumDrive;
import org.firstinspires.ftc.teamcode.utils.FlywheelV2;
import org.firstinspires.ftc.teamcode.utils.Robot;
import org.firstinspires.ftc.teamcode.utils.Servos;
import java.util.List;
@Config
@Autonomous(preselectTeleOp = "TeleopV3")
public class AutoFar_V1 extends LinearOpMode {
Robot robot;
MultipleTelemetry TELE;
MecanumDrive drive;
FlywheelV2 flywheel;
Servos servo;
double velo = 0.0;
public static double intake1Time = 2.7;
public static double intake2Time = 3.0;
public static double colorDetect = 3.0;
boolean gpp = false;
boolean pgp = false;
boolean ppg = false;
double powPID = 0.0;
double bearing = 0.0;
int b1 = 0; // 0 = no ball, 1 = green, 2 = purple
int b2 = 0;// 0 = no ball, 1 = green, 2 = purple
int b3 = 0;// 0 = no ball, 1 = green, 2 = purple
public static double holdTurrPow = 0.1; // power to hold turret in place
public Action initShooter(int vel) {
return new Action() {
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
powPID = flywheel.manageFlywheel(vel, robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
velo = flywheel.getVelo(robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
TELE.addData("Velocity", velo);
TELE.update();
return !flywheel.getSteady();
}
};
}
public Action Obelisk() {
return new Action() {
int id = 0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
LLResult result = robot.limelight.getLatestResult();
if (result != null && result.isValid()) {
List<LLResultTypes.FiducialResult> fiducials = result.getFiducialResults();
for (LLResultTypes.FiducialResult fiducial : fiducials) {
id = fiducial.getFiducialId();
TELE.addData("ID", id);
TELE.update();
}
}
if (id == 21){
gpp = true;
} else if (id == 22){
pgp = true;
} else if (id == 23){
ppg = true;
}
TELE.addData("Velocity", velo);
TELE.addData("21", gpp);
TELE.addData("22", pgp);
TELE.addData("23", ppg);
TELE.update();
if (gpp || pgp || ppg) {
if (redAlliance){
robot.limelight.pipelineSwitch(3);
robot.turr1.setPosition(turret_redFar);
robot.turr2.setPosition(-turret_redFar);
} else {
robot.limelight.pipelineSwitch(2);
robot.turr1.setPosition(turret_blueFar);
robot.turr2.setPosition(-turret_blueFar);
}
return false;
} else {
return true;
}
}
};
}
public Action spindex(double spindexer, int vel) {
return new Action() {
double spinPID = 0.0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
powPID = flywheel.manageFlywheel(vel, robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
velo = flywheel.getVelo(robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
spinPID = servo.setSpinPos(spindexer);
robot.spin1.setPower(spinPID);
robot.spin2.setPower(-spinPID);
TELE.addData("Velocity", velo);
TELE.addLine("spindex");
TELE.update();
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
if (servo.spinEqual(spindexer)){
robot.spin1.setPower(0);
robot.spin2.setPower(0);
return false;
} else {
return true;
}
}
};
}
public Action Shoot(int vel) {
return new Action() {
double transferStamp = 0.0;
int ticker = 1;
boolean transferIn = false;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
TELE.addData("Velocity", velo);
TELE.addLine("shooting");
TELE.update();
powPID = flywheel.manageFlywheel(vel, robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
velo = flywheel.getVelo(robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
drive.updatePoseEstimate();
detectTag();
teleStart = drive.localizer.getPose();
if (ticker == 1) {
transferStamp = getRuntime();
ticker++;
}
if (getRuntime() - transferStamp > waitTransfer && !transferIn) {
robot.transferServo.setPosition(transferServo_in);
TELE.addData("Velocity", velo);
TELE.addData("ticker", ticker);
TELE.update();
transferIn = true;
return true;
} else if (getRuntime() - transferStamp > waitTransfer + waitTransferOut && transferIn) {
robot.transferServo.setPosition(transferServo_out);
robot.turr1.setPosition(holdTurrPow);
robot.turr2.setPosition(holdTurrPow);
TELE.addData("Velocity", velo);
TELE.addLine("shot once");
TELE.update();
return false;
} else {
return true;
}
}
};
}
public Action intake(double intakeTime) {
return new Action() {
double position = spindexer_intakePos1;
double stamp = 0.0;
int ticker = 0;
double pow = 1.0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
if (ticker == 0) {
stamp = getRuntime();
}
ticker++;
robot.intake.setPower(pow);
double s1D = robot.color1.getDistance(DistanceUnit.MM);
double s2D = robot.color2.getDistance(DistanceUnit.MM);
double s3D = robot.color3.getDistance(DistanceUnit.MM);
if (!servo.spinEqual(position)){
double spinPID = servo.setSpinPos(position);
robot.spin1.setPower(spinPID);
robot.spin2.setPower(-spinPID);
}
if (s1D < 43 && servo.spinEqual(position) && getRuntime() - stamp > 0.5){
if (s2D > 60){
if (servo.spinEqual(spindexer_intakePos1)){
position = spindexer_intakePos2;
} else if (servo.spinEqual(spindexer_intakePos2)){
position = spindexer_intakePos3;
} else if (servo.spinEqual(spindexer_intakePos3)){
position = spindexer_intakePos1;
}
} else if (s3D > 33){
if (servo.spinEqual(spindexer_intakePos1)){
position = spindexer_intakePos3;
} else if (servo.spinEqual(spindexer_intakePos2)){
position = spindexer_intakePos1;
} else if (servo.spinEqual(spindexer_intakePos3)){
position = spindexer_intakePos2;
}
}
stamp = getRuntime();
}
TELE.addData("Velocity", velo);
TELE.addLine("Intaking");
TELE.update();
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
robot.intake.setPower(1);
if ((s1D < 43.0 && s2D < 60.0 && s3D < 33.0) || getRuntime() - stamp > intakeTime) {
robot.spin1.setPower(0);
robot.spin2.setPower(0);
if (getRuntime() - stamp - intakeTime < 1){
pow = -2*(getRuntime() - stamp - intakeTime);
return true;
} else {
robot.intake.setPower(0);
return false;
}
} else {
return true;
}
}
};
}
public Action ColorDetect(int vel) {
return new Action() {
double stamp = 0.0;
int ticker = 0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
if (ticker == 0) {
stamp = getRuntime();
}
ticker++;
powPID = flywheel.manageFlywheel(vel, robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
velo = flywheel.getVelo(robot.shooter1.getCurrentPosition(), robot.shooter2.getCurrentPosition());
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
double s1D = robot.color1.getDistance(DistanceUnit.MM);
double s2D = robot.color2.getDistance(DistanceUnit.MM);
double s3D = robot.color3.getDistance(DistanceUnit.MM);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
if (s1D < 43) {
double green = robot.color1.getNormalizedColors().green;
double red = robot.color1.getNormalizedColors().red;
double blue = robot.color1.getNormalizedColors().blue;
double gP = green / (green + red + blue);
if (gP >= 0.4) {
b1 = 2;
} else {
b1 = 1;
}
}
if (s2D < 60) {
double green = robot.color2.getNormalizedColors().green;
double red = robot.color2.getNormalizedColors().red;
double blue = robot.color2.getNormalizedColors().blue;
double gP = green / (green + red + blue);
if (gP >= 0.4) {
b2 = 2;
} else {
b2 = 1;
}
}
if (s3D < 33) {
double green = robot.color3.getNormalizedColors().green;
double red = robot.color3.getNormalizedColors().red;
double blue = robot.color3.getNormalizedColors().blue;
double gP = green / (green + red + blue);
if (gP >= 0.4) {
b3 = 2;
} else {
b3 = 1;
}
}
TELE.addData("Velocity", velo);
TELE.addLine("Detecting");
TELE.addData("Distance 1", s1D);
TELE.addData("Distance 2", s2D);
TELE.addData("Distance 3", s3D);
TELE.addData("B1", b1);
TELE.addData("B2", b2);
TELE.addData("B3", b3);
TELE.update();
return (b1 + b2 + b3 < 4) && !(getRuntime() - stamp > colorDetect);
}
};
}
@Override
public void runOpMode() throws InterruptedException {
robot = new Robot(hardwareMap);
flywheel = new FlywheelV2();
TELE = new MultipleTelemetry(
telemetry, FtcDashboard.getInstance().getTelemetry()
);
drive = new MecanumDrive(hardwareMap, new Pose2d(
0, 0, 0
));
robot.limelight.pipelineSwitch(1);
robot.limelight.start();
//TODO: add positions to develop auto
TrajectoryActionBuilder park = drive.actionBuilder(new Pose2d(0,0,0))
.strafeToLinearHeading(new Vector2d(rfx1, rfy1), rfh1);
while (opModeInInit()) {
if (gamepad2.dpadUpWasPressed()) {
hoodAuto -= 0.01;
}
if (gamepad2.dpadDownWasPressed()) {
hoodAuto += 0.01;
}
if (gamepad2.crossWasPressed()){
redAlliance = !redAlliance;
}
double turrPID;
if (redAlliance){
turrPID = turret_detectRedClose;
} else {
turrPID = turret_detectBlueClose;
}
robot.turr1.setPosition(turrPID);
robot.turr2.setPosition(-turrPID);
robot.hood.setPosition(hoodAutoFar);
robot.transferServo.setPosition(transferServo_out);
TELE.addData("Velocity", velo);
TELE.addData("Turret Pos", servo.getTurrPos());
TELE.addData("Spin Pos", servo.getSpinPos());
TELE.update();
}
waitForStart();
if (isStopRequested()) return;
if (opModeIsActive()) {
Actions.runBlocking(
new ParallelAction(
initShooter(AUTO_FAR_VEL),
Obelisk()
)
);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
robot.transfer.setPower(1);
shootingSequence();
robot.transfer.setPower(0);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
Actions.runBlocking(park.build());
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
TELE.addData("Velocity", velo);
TELE.addLine("finished");
TELE.update();
sleep(2000);
}
}
//TODO: adjust this according to Teleop numbers
public void detectTag() {
LLResult result = robot.limelight.getLatestResult();
if (result != null) {
if (result.isValid()) {
bearing = result.getTx();
}
}
double turretPos = servo.getTurrPos() - (bearing / 1300);
double turretPID = turretPos;
robot.turr1.setPosition(turretPID);
robot.turr2.setPosition(-turretPID);
}
public void shootingSequence() {
TELE.addData("Velocity", velo);
if (gpp) {
if (b1 + b2 + b3 == 4) {
if (b1 == 2 && b2 - b3 == 0) {
sequence1();
TELE.addLine("sequence1");
} else if (b2 == 2 && b1 - b3 == 0) {
sequence3();
TELE.addLine("sequence3");
} else if (b3 == 2 && b1 - b2 == 0) {
sequence6();
TELE.addLine("sequence6");
} else {
sequence1();
TELE.addLine("sequence1");
}
} else if (b1 + b2 + b3 >= 5) {
if (b1 == 2) {
sequence1();
TELE.addLine("sequence1");
} else if (b2 == 2) {
sequence3();
TELE.addLine("sequence3");
} else if (b3 == 2) {
sequence6();
TELE.addLine("sequence6");
}
} else {
sequence1();
TELE.addLine("sequence1");
}
} else if (pgp) {
if (b1 + b2 + b3 == 4) {
if (b1 == 2 && b2 - b3 == 0) {
sequence3();
TELE.addLine("sequence3");
} else if (b2 == 2 && b1 - b3 == 0) {
sequence1();
TELE.addLine("sequence1");
} else if (b3 == 2 && b1 - b2 == 0) {
sequence4();
TELE.addLine("sequence4");
} else {
sequence1();
TELE.addLine("sequence1");
}
} else if (b1 + b2 + b3 >= 5) {
if (b1 == 2) {
sequence3();
TELE.addLine("sequence3");
} else if (b2 == 2) {
sequence1();
TELE.addLine("sequence1");
} else if (b3 == 2) {
sequence4();
TELE.addLine("sequence4");
}
} else {
sequence3();
TELE.addLine("sequence3");
}
} else if (ppg) {
if (b1 + b2 + b3 == 4) {
if (b1 == 2 && b2 - b3 == 0) {
sequence6();
TELE.addLine("sequence6");
} else if (b2 == 2 && b1 - b3 == 0) {
sequence5();
TELE.addLine("sequence5");
} else if (b3 == 2 && b1 - b2 == 0) {
sequence1();
TELE.addLine("sequence1");
} else {
sequence1();
TELE.addLine("sequence1");
}
} else if (b1 + b2 + b3 >= 5) {
if (b1 == 2) {
sequence6();
TELE.addLine("sequence6");
} else if (b2 == 2) {
sequence5();
TELE.addLine("sequence5");
} else if (b3 == 2) {
sequence1();
TELE.addLine("sequence1");
}
} else {
sequence6();
TELE.addLine("sequence6");
}
} else {
sequence1();
TELE.addLine("sequence1");
}
TELE.update();
}
public void sequence1() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall1, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL),
spindex(spindexer_outtakeBall2, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL),
spindex(spindexer_outtakeBall3, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL)
)
);
}
public void sequence2() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall1, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL),
spindex(spindexer_outtakeBall3, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL),
spindex(spindexer_outtakeBall2, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL)
)
);
}
public void sequence3() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall2, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL),
spindex(spindexer_outtakeBall1, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL),
spindex(spindexer_outtakeBall3, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL)
)
);
}
public void sequence4() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall2, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL),
spindex(spindexer_outtakeBall3, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL),
spindex(spindexer_outtakeBall1, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL)
)
);
}
public void sequence5() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall3, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL),
spindex(spindexer_outtakeBall1, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL),
spindex(spindexer_outtakeBall2, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL)
)
);
}
public void sequence6() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall3, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL),
spindex(spindexer_outtakeBall2, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL),
spindex(spindexer_outtakeBall1, AUTO_FAR_VEL),
Shoot(AUTO_FAR_VEL)
)
);
}
}

802
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/autonomous/ProtoAutoClose_V3.java Normal file
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@@ -0,0 +1,802 @@
package org.firstinspires.ftc.teamcode.autonomous;
import static org.firstinspires.ftc.teamcode.constants.Color.redAlliance;
import static org.firstinspires.ftc.teamcode.constants.Poses.bh1;
import static org.firstinspires.ftc.teamcode.constants.Poses.bh2a;
import static org.firstinspires.ftc.teamcode.constants.Poses.bh2b;
import static org.firstinspires.ftc.teamcode.constants.Poses.bh3a;
import static org.firstinspires.ftc.teamcode.constants.Poses.bh3b;
import static org.firstinspires.ftc.teamcode.constants.Poses.bh4a;
import static org.firstinspires.ftc.teamcode.constants.Poses.bh4b;
import static org.firstinspires.ftc.teamcode.constants.Poses.bx1;
import static org.firstinspires.ftc.teamcode.constants.Poses.bx2a;
import static org.firstinspires.ftc.teamcode.constants.Poses.bx2b;
import static org.firstinspires.ftc.teamcode.constants.Poses.bx3a;
import static org.firstinspires.ftc.teamcode.constants.Poses.bx3b;
import static org.firstinspires.ftc.teamcode.constants.Poses.bx4a;
import static org.firstinspires.ftc.teamcode.constants.Poses.bx4b;
import static org.firstinspires.ftc.teamcode.constants.Poses.by1;
import static org.firstinspires.ftc.teamcode.constants.Poses.by2a;
import static org.firstinspires.ftc.teamcode.constants.Poses.by2b;
import static org.firstinspires.ftc.teamcode.constants.Poses.by3a;
import static org.firstinspires.ftc.teamcode.constants.Poses.by3b;
import static org.firstinspires.ftc.teamcode.constants.Poses.by4a;
import static org.firstinspires.ftc.teamcode.constants.Poses.by4b;
import static org.firstinspires.ftc.teamcode.constants.Poses.rh1;
import static org.firstinspires.ftc.teamcode.constants.Poses.rh2a;
import static org.firstinspires.ftc.teamcode.constants.Poses.rh2b;
import static org.firstinspires.ftc.teamcode.constants.Poses.rh3a;
import static org.firstinspires.ftc.teamcode.constants.Poses.rh3b;
import static org.firstinspires.ftc.teamcode.constants.Poses.rh4a;
import static org.firstinspires.ftc.teamcode.constants.Poses.rh4b;
import static org.firstinspires.ftc.teamcode.constants.Poses.rx1;
import static org.firstinspires.ftc.teamcode.constants.Poses.rx2a;
import static org.firstinspires.ftc.teamcode.constants.Poses.rx2b;
import static org.firstinspires.ftc.teamcode.constants.Poses.rx3a;
import static org.firstinspires.ftc.teamcode.constants.Poses.rx3b;
import static org.firstinspires.ftc.teamcode.constants.Poses.rx4a;
import static org.firstinspires.ftc.teamcode.constants.Poses.rx4b;
import static org.firstinspires.ftc.teamcode.constants.Poses.ry1;
import static org.firstinspires.ftc.teamcode.constants.Poses.ry2a;
import static org.firstinspires.ftc.teamcode.constants.Poses.ry2b;
import static org.firstinspires.ftc.teamcode.constants.Poses.ry3a;
import static org.firstinspires.ftc.teamcode.constants.Poses.ry3b;
import static org.firstinspires.ftc.teamcode.constants.Poses.ry4a;
import static org.firstinspires.ftc.teamcode.constants.Poses.ry4b;
import static org.firstinspires.ftc.teamcode.constants.Poses.teleStart;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.hoodAuto;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_outtakeBall1;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_outtakeBall2;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_outtakeBall3;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.transferServo_in;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.transferServo_out;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.turret_blueClose;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.turret_redClose;
import static org.firstinspires.ftc.teamcode.constants.ShooterVars.AUTO_CLOSE_VEL;
import static org.firstinspires.ftc.teamcode.teleop.TeleopV3.spinPow;
import androidx.annotation.NonNull;
import com.acmerobotics.dashboard.FtcDashboard;
import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
import com.acmerobotics.dashboard.telemetry.TelemetryPacket;
import com.acmerobotics.roadrunner.Action;
import com.acmerobotics.roadrunner.ParallelAction;
import com.acmerobotics.roadrunner.Pose2d;
import com.acmerobotics.roadrunner.SequentialAction;
import com.acmerobotics.roadrunner.TrajectoryActionBuilder;
import com.acmerobotics.roadrunner.TranslationalVelConstraint;
import com.acmerobotics.roadrunner.Vector2d;
import com.acmerobotics.roadrunner.ftc.Actions;
import com.qualcomm.hardware.limelightvision.LLResult;
import com.qualcomm.hardware.limelightvision.LLResultTypes;
import com.qualcomm.robotcore.eventloop.opmode.Autonomous;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import org.firstinspires.ftc.robotcore.external.navigation.DistanceUnit;
import org.firstinspires.ftc.teamcode.libs.RR.MecanumDrive;
import org.firstinspires.ftc.teamcode.utils.Flywheel;
import org.firstinspires.ftc.teamcode.utils.Robot;
import org.firstinspires.ftc.teamcode.utils.Servos;
import java.util.List;
@Config
@Autonomous(preselectTeleOp = "TeleopV3")
public class ProtoAutoClose_V3 extends LinearOpMode {
public static double intake1Time = 2.7;
public static double intake2Time = 3.0;
public static double colorDetect = 3.0;
public static double holdTurrPow = 0.01; // power to hold turret in place
public static double slowSpeed = 30.0;
Robot robot;
MultipleTelemetry TELE;
MecanumDrive drive;
Flywheel flywheel;
Servos servo;
double velo = 0.0;
boolean gpp = false;
boolean pgp = false;
boolean ppg = false;
public static double spinUnjamTime = 0.6;
double powPID = 0.0;
double bearing = 0.0;
int b1 = 0; // 0 = no ball, 1 = green, 2 = purple
int b2 = 0;// 0 = no ball, 1 = green, 2 = purple
int b3 = 0;// 0 = no ball, 1 = green, 2 = purple
public Action initShooter(int vel) {
return new Action() {
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
flywheel.manageFlywheel(vel);
velo = flywheel.getVelo();
TELE.addData("Velocity", velo);
TELE.update();
return !flywheel.getSteady();
}
};
}
public Action Obelisk() {
return new Action() {
int id = 0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
LLResult result = robot.limelight.getLatestResult();
if (result != null && result.isValid()) {
List<LLResultTypes.FiducialResult> fiducials = result.getFiducialResults();
for (LLResultTypes.FiducialResult fiducial : fiducials) {
id = fiducial.getFiducialId();
TELE.addData("ID", id);
TELE.update();
}
}
if (id == 21) {
gpp = true;
} else if (id == 22) {
pgp = true;
} else if (id == 23) {
ppg = true;
}
TELE.addData("Velocity", velo);
TELE.addData("21", gpp);
TELE.addData("22", pgp);
TELE.addData("23", ppg);
TELE.update();
if (gpp || pgp || ppg) {
if (redAlliance) {
robot.limelight.pipelineSwitch(3);
robot.turr1.setPosition(turret_redClose);
robot.turr2.setPosition(1 - turret_redClose);
return false;
} else {
robot.limelight.pipelineSwitch(2);
double turretPID = turret_blueClose;
robot.turr1.setPosition(turretPID);
robot.turr2.setPosition(1 - turretPID);
return false;
}
} else {
return true;
}
}
};
}
public Action spindex(double spindexer, int vel) {
return new Action() {
double spinPID = 0.0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
flywheel.manageFlywheel(vel);
velo = flywheel.getVelo();
spinPID = servo.setSpinPos(spindexer);
robot.spin1.setPower(spinPID);
robot.spin2.setPower(-spinPID);
TELE.addData("Velocity", velo);
TELE.addLine("spindex");
TELE.update();
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
if (servo.spinEqual(spindexer)) {
robot.spin1.setPower(0);
robot.spin2.setPower(0);
return false;
} else {
return true;
}
}
};
}
public Action Shoot(int vel) {
return new Action() {
int ticker = 1;
double initPos = 0.0;
double finalPos = 0.0;
boolean zeroNeeded = false;
boolean zeroPassed = false;
double currentPos = 0.0;
double prevPos = 0.0;
double stamp = 0.0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
TELE.addData("Velocity", velo);
TELE.addLine("shooting");
TELE.update();
flywheel.manageFlywheel(vel);
velo = flywheel.getVelo();
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
robot.intake.setPower(-0.3);
if (ticker == 1) {
stamp = getRuntime();
}
ticker++;
robot.intake.setPower(0);
if (getRuntime() - stamp < 2.7) {
robot.transferServo.setPosition(transferServo_in);
robot.spin1.setPower(-spinPow);
robot.spin2.setPower(spinPow);
return true;
} else {
robot.transferServo.setPosition(transferServo_out);
return false;
}
}
};
}
public Action spindexUnjam(double jamTime) {
return new Action() {
double stamp = 0.0;
int ticker = 0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
ticker++;
if (ticker == 1) {
stamp = getRuntime();
}
if (ticker % 12 < 6) {
robot.spin1.setPower(-1);
robot.spin2.setPower(1);
} else {
robot.spin1.setPower(1);
robot.spin2.setPower(-1);
}
if (getRuntime() - stamp > jamTime+0.4) {
robot.intake.setPower(0.5);
return false;
}
else if (getRuntime() - stamp > jamTime) {
robot.intake.setPower(-(getRuntime()-stamp-jamTime)*2.5);
return true;
}
else {
robot.intake.setPower(1);
return true;
}
}
};
}
public Action intake(double intakeTime) {
return new Action() {
double stamp = 0.0;
int ticker = 0;
double spinCurrentPos = 0.0;
double spinInitPos = 0.0;
boolean reverse = false;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
if (ticker == 0) {
stamp = getRuntime();
}
ticker++;
if (ticker % 60 < 12) {
robot.spin1.setPower(-1);
robot.spin2.setPower(1);
} else if (ticker % 60 < 30) {
robot.spin1.setPower(-0.5);
robot.spin2.setPower(0.5);
}
else if (ticker % 60 < 42) {
robot.spin1.setPower(1);
robot.spin2.setPower(-1);
}
else {
robot.spin1.setPower(0.5);
robot.spin2.setPower(-0.5);
}
robot.intake.setPower(1);
TELE.addData("Reverse?", reverse);
TELE.update();
if (getRuntime() - stamp > intakeTime) {
if (reverse) {
robot.spin1.setPower(-1);
robot.spin2.setPower(1);
} else {
robot.spin1.setPower(1);
robot.spin2.setPower(-1);
}
return false;
} else {
if (ticker % 4 == 0) {
spinCurrentPos = servo.getSpinPos();
reverse = Math.abs(spinCurrentPos - spinInitPos) < 0.03;
spinInitPos = spinCurrentPos;
}
return true;
}
}
};
}
public Action ColorDetect(int vel) {
return new Action() {
double stamp = 0.0;
int ticker = 0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
if (ticker == 0) {
stamp = getRuntime();
}
ticker++;
flywheel.manageFlywheel(vel);
velo = flywheel.getVelo();
double s1D = robot.color1.getDistance(DistanceUnit.MM);
double s2D = robot.color2.getDistance(DistanceUnit.MM);
double s3D = robot.color3.getDistance(DistanceUnit.MM);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
if (s1D < 43) {
double green = robot.color1.getNormalizedColors().green;
double red = robot.color1.getNormalizedColors().red;
double blue = robot.color1.getNormalizedColors().blue;
double gP = green / (green + red + blue);
if (gP >= 0.4) {
b1 = 2;
} else {
b1 = 1;
}
}
if (s2D < 60) {
double green = robot.color2.getNormalizedColors().green;
double red = robot.color2.getNormalizedColors().red;
double blue = robot.color2.getNormalizedColors().blue;
double gP = green / (green + red + blue);
if (gP >= 0.4) {
b2 = 2;
} else {
b2 = 1;
}
}
if (s3D < 33) {
double green = robot.color3.getNormalizedColors().green;
double red = robot.color3.getNormalizedColors().red;
double blue = robot.color3.getNormalizedColors().blue;
double gP = green / (green + red + blue);
if (gP >= 0.4) {
b3 = 2;
} else {
b3 = 1;
}
}
TELE.addData("Velocity", velo);
TELE.addLine("Detecting");
TELE.addData("Distance 1", s1D);
TELE.addData("Distance 2", s2D);
TELE.addData("Distance 3", s3D);
TELE.addData("B1", b1);
TELE.addData("B2", b2);
TELE.addData("B3", b3);
TELE.update();
return (b1 + b2 + b3 < 4) && !(getRuntime() - stamp > colorDetect);
}
};
}
@Override
public void runOpMode() throws InterruptedException {
robot = new Robot(hardwareMap);
flywheel = new Flywheel(hardwareMap);
TELE = new MultipleTelemetry(
telemetry, FtcDashboard.getInstance().getTelemetry()
);
drive = new MecanumDrive(hardwareMap, new Pose2d(
0, 0, 0
));
servo = new Servos(hardwareMap);
robot.limelight.pipelineSwitch(1);
robot.limelight.start();
TrajectoryActionBuilder shoot0 = drive.actionBuilder(new Pose2d(0, 0, 0))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
TrajectoryActionBuilder pickup1 = drive.actionBuilder(new Pose2d(bx1, by1, bh1))
.strafeToLinearHeading(new Vector2d(bx2a, by2a), bh2a)
.strafeToLinearHeading(new Vector2d(bx2b, by2b), bh2b,
new TranslationalVelConstraint(slowSpeed));
//
// TrajectoryActionBuilder lever = drive.actionBuilder(new Pose2d(bx2b, by2b, bh2b))
// .strafeToLinearHeading(new Vector2d(bx2c, by2c), bh2c);
TrajectoryActionBuilder shoot1 = drive.actionBuilder(new Pose2d(bx2b, by2b, bh2b))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
TrajectoryActionBuilder pickup2 = drive.actionBuilder(new Pose2d(bx1, by1, bh1))
.strafeToLinearHeading(new Vector2d(bx3a, by3a), bh3a)
.strafeToLinearHeading(new Vector2d(bx3b, by3b), bh3b,
new TranslationalVelConstraint(slowSpeed));
TrajectoryActionBuilder shoot2 = drive.actionBuilder(new Pose2d(bx3b, by3b, bh3b))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
TrajectoryActionBuilder pickup3 = drive.actionBuilder(new Pose2d(bx1, by1, bh1))
.strafeToLinearHeading(new Vector2d(bx4a, by4a), bh4a)
.strafeToLinearHeading(new Vector2d(bx4b, by4b), bh4b,
new TranslationalVelConstraint(slowSpeed));
TrajectoryActionBuilder shoot3 = drive.actionBuilder(new Pose2d(bx4b, by4b, bh4b))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
while (opModeInInit()) {
if (gamepad2.dpadUpWasPressed()) {
hoodAuto -= 0.01;
}
if (gamepad2.dpadDownWasPressed()) {
hoodAuto += 0.01;
}
if (gamepad2.crossWasPressed()) {
redAlliance = !redAlliance;
}
double turretPID;
if (redAlliance) {
turretPID = turret_redClose;
shoot0 = drive.actionBuilder(new Pose2d(0, 0, 0))
.strafeToLinearHeading(new Vector2d(rx1, ry1), rh1);
pickup1 = drive.actionBuilder(new Pose2d(rx1, ry1, rh1))
.strafeToLinearHeading(new Vector2d(rx2a, ry2a), rh2a)
.strafeToLinearHeading(new Vector2d(rx2b, ry2b), rh2b,
new TranslationalVelConstraint(slowSpeed));
// lever = drive.actionBuilder(new Pose2d(rx2b, ry2b, rh2b))
// .strafeToLinearHeading(new Vector2d(rx2c, ry2c), rh2c);
shoot1 = drive.actionBuilder(new Pose2d(rx2b, ry2b, rh2b))
.strafeToLinearHeading(new Vector2d(rx1, ry1), rh1);
pickup2 = drive.actionBuilder(new Pose2d(rx1, ry1, rh1))
.strafeToLinearHeading(new Vector2d(rx3a, ry3a), rh3a)
.strafeToLinearHeading(new Vector2d(rx3b, ry3b), rh3b,
new TranslationalVelConstraint(slowSpeed));
shoot2 = drive.actionBuilder(new Pose2d(rx3b, ry3b, rh3b))
.strafeToLinearHeading(new Vector2d(rx1, ry1), rh1);
pickup3 = drive.actionBuilder(new Pose2d(rx1, ry1, rh1))
.strafeToLinearHeading(new Vector2d(rx4a, ry4a), rh4a)
.strafeToLinearHeading(new Vector2d(rx4b, ry4b), rh4b,
new TranslationalVelConstraint(slowSpeed));
shoot3 = drive.actionBuilder(new Pose2d(rx4b, ry4b, rh4b))
.strafeToLinearHeading(new Vector2d(rx1, ry1), rh1);
} else {
turretPID = turret_blueClose;
shoot0 = drive.actionBuilder(new Pose2d(0, 0, 0))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
pickup1 = drive.actionBuilder(new Pose2d(bx1, by1, bh1))
.strafeToLinearHeading(new Vector2d(bx2a, by2a), bh2a)
.strafeToLinearHeading(new Vector2d(bx2b, by2b), bh2b,
new TranslationalVelConstraint(slowSpeed));
shoot1 = drive.actionBuilder(new Pose2d(bx2b, by2b, bh2b))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
pickup2 = drive.actionBuilder(new Pose2d(bx1, by1, bh1))
.strafeToLinearHeading(new Vector2d(bx3a, by3a), bh3a)
.strafeToLinearHeading(new Vector2d(bx3b, by3b), bh3b,
new TranslationalVelConstraint(slowSpeed));
shoot2 = drive.actionBuilder(new Pose2d(bx3b, by3b, bh3b))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
pickup3 = drive.actionBuilder(new Pose2d(bx1, by1, bh1))
.strafeToLinearHeading(new Vector2d(bx4a, by4a), bh4a)
.strafeToLinearHeading(new Vector2d(bx4b, by4b), bh4b,
new TranslationalVelConstraint(slowSpeed));
shoot3 = drive.actionBuilder(new Pose2d(bx4b, by4b, bh4b))
.strafeToLinearHeading(new Vector2d(bx1, by1), bh1);
}
robot.turr1.setPosition(turretPID);
robot.turr2.setPosition(1 - turretPID);
robot.hood.setPosition(hoodAuto);
robot.transferServo.setPosition(transferServo_out);
TELE.addData("Red?", redAlliance);
TELE.update();
}
waitForStart();
if (isStopRequested()) return;
if (opModeIsActive()) {
Actions.runBlocking(
new ParallelAction(
shoot0.build(),
initShooter(AUTO_CLOSE_VEL)
)
);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
robot.transfer.setPower(1);
shootingSequence();
robot.transfer.setPower(0);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
Actions.runBlocking(
new ParallelAction(
pickup1.build(),
intake(intake1Time)
)
);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
Actions.runBlocking(
new SequentialAction(
shoot1.build(),
spindexUnjam(spinUnjamTime)
)
);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
robot.transfer.setPower(1);
shootingSequence();
robot.transfer.setPower(0);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
Actions.runBlocking(
new ParallelAction(
pickup2.build(),
intake(intake2Time)
)
);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
Actions.runBlocking(
new ParallelAction(
shoot2.build(),
spindexUnjam(spinUnjamTime)
)
);
robot.transfer.setPower(1);
shootingSequence();
robot.transfer.setPower(0);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
Actions.runBlocking(
new ParallelAction(
pickup3.build(),
intake(intake2Time)
)
);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
Actions.runBlocking(
new ParallelAction(
shoot3.build(),
spindexUnjam(spinUnjamTime)
)
);
robot.transfer.setPower(1);
shootingSequence();
robot.transfer.setPower(0);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
TELE.addData("Velocity", velo);
TELE.addLine("finished");
TELE.update();
sleep(2000);
}
}
//TODO: adjust this according to Teleop numbers
public void detectTag() {
LLResult result = robot.limelight.getLatestResult();
if (result != null) {
if (result.isValid()) {
bearing = result.getTx();
}
}
double turretPos = (bearing / 1300);
robot.turr1.setPosition(turretPos);
robot.turr2.setPosition(1 - turretPos);
}
public void shootingSequence() {
TELE.addLine("Shooting");
TELE.update();
Actions.runBlocking(Shoot(AUTO_CLOSE_VEL));
}
public void sequence1() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall1, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall2, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall3, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL)
)
);
}
public void sequence2() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall1, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall3, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall2, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL)
)
);
}
public void sequence3() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall2, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall1, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall3, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL)
)
);
}
public void sequence4() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall2, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall3, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall1, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL)
)
);
}
public void sequence5() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall3, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall1, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall2, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL)
)
);
}
public void sequence6() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall3, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall2, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall1, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL)
)
);
}
}

827
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/autonomous/Red_V2.java
View File

@@ -1,827 +0,0 @@
package org.firstinspires.ftc.teamcode.autonomous;
import static org.firstinspires.ftc.teamcode.constants.Poses.*;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.*;
import static org.firstinspires.ftc.teamcode.constants.ShooterVars.*;
import static org.firstinspires.ftc.teamcode.utils.PositionalServoProgrammer.*;
import androidx.annotation.NonNull;
import com.acmerobotics.dashboard.FtcDashboard;
import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
import com.acmerobotics.dashboard.telemetry.TelemetryPacket;
import com.acmerobotics.roadrunner.ParallelAction;
import com.acmerobotics.roadrunner.Pose2d;
import com.acmerobotics.roadrunner.SequentialAction;
import com.acmerobotics.roadrunner.TrajectoryActionBuilder;
import com.acmerobotics.roadrunner.Vector2d;
import com.qualcomm.robotcore.eventloop.opmode.Autonomous;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import com.acmerobotics.roadrunner.Action;
import com.acmerobotics.roadrunner.ftc.Actions;
import org.firstinspires.ftc.robotcore.external.navigation.DistanceUnit;
import org.firstinspires.ftc.teamcode.libs.RR.MecanumDrive;
import org.firstinspires.ftc.teamcode.utils.Flywheel;
import org.firstinspires.ftc.teamcode.utils.AprilTagWebcam;
import org.firstinspires.ftc.teamcode.utils.Robot;
@Config
@Autonomous(preselectTeleOp = "TeleopV2")
public class Red_V2 extends LinearOpMode {
Robot robot;
MultipleTelemetry TELE;
MecanumDrive drive;
AprilTagWebcam aprilTag;
Flywheel flywheel;
double velo = 0.0;
double targetVelocity = 0.0;
public static double intake1Time = 2.9;
public static double intake2Time = 2.9;
public static double colorDetect = 3.0;
boolean gpp = false;
boolean pgp = false;
boolean ppg = false;
double powPID = 0.0;
int b1 = 0; // 0 = no ball, 1 = green, 2 = purple
int b2 = 0;// 0 = no ball, 1 = green, 2 = purple
int b3 = 0;// 0 = no ball, 1 = green, 2 = purple
boolean spindexPosEqual(double spindexer) {
TELE.addData("Velocity", velo);
TELE.addLine("spindex equal");
TELE.update();
return (scalar * ((robot.spin1Pos.getVoltage() - restPos) / 3.3) > spindexer - 0.01 &&
scalar * ((robot.spin1Pos.getVoltage() - restPos) / 3.3) < spindexer + 0.01);
}
public Action initShooter(int vel) {
return new Action() {
double initPos = 0.0;
double stamp = 0.0;
double stamp1 = 0.0;
double ticker = 0.0;
double stamp2 = 0.0;
double currentPos = 0.0;
boolean steady = false;
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
if (ticker == 0) {
stamp2 = getRuntime();
}
targetVelocity = (double) vel;
ticker++;
if (ticker % 16 == 0) {
stamp = getRuntime();
stamp1 = stamp;
}
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition());
velo = flywheel.getVelo();
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
robot.transfer.setPower(1);
TELE.addData("Velocity", velo);
TELE.update();
if (vel < velo && getRuntime() - stamp2 > 3.0 && !steady){
steady = true;
stamp2 = getRuntime();
return true;
} else if (steady && getRuntime() - stamp2 > 1.5){
TELE.addData("Velocity", velo);
TELE.addLine("finished init");
TELE.update();
return false;
} else {
return true;
}
}
};
}
public Action steadyShooter(int vel, boolean last) {
return new Action() {
double stamp = 0.0;
boolean steady = false;
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition());
velo = flywheel.getVelo();
steady = flywheel.getSteady();
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
robot.transfer.setPower(1);
TELE.addData("Velocity", velo);
TELE.update();
if (last && !steady){
stamp = getRuntime();
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
return false;
} else if (steady) {
stamp = getRuntime();
return true;
} else {
return true;
}
}
};
}
public Action Obelisk() {
return new Action() {
double stamp = getRuntime();
int ticker = 0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
if (ticker == 0) {
stamp = getRuntime();
}
ticker++;
if (aprilTag.getTagById(21) != null) {
gpp = true;
} else if (aprilTag.getTagById(22) != null) {
pgp = true;
} else if (aprilTag.getTagById(23) != null) {
ppg = true;
}
aprilTag.update();
TELE.addData("Velocity", velo);
TELE.addData("21", gpp);
TELE.addData("22", pgp);
TELE.addData("23", ppg);
TELE.update();
if (gpp || pgp || ppg){
robot.turr1.setPosition(turret_red);
robot.turr2.setPosition(1 - turret_red);
return false;
} else {
return true;
}
}
};
}
public Action spindex (double spindexer, double vel){
return new Action() {
double currentPos = 0.0;
double stamp = 0.0;
double initPos = 0.0;
double stamp1 = 0.0;
int ticker = 0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
ticker++;
if (ticker % 8 == 0) {
currentPos = (double) robot.shooter1.getCurrentPosition() / 2048;
stamp = getRuntime();
velo = -60 * ((currentPos - initPos) / (stamp - stamp1));
initPos = currentPos;
stamp1 = stamp;
}
if (vel - velo > 500 && ticker > 16) {
powPID = 1.0;
} else if (velo - vel > 500 && ticker > 16){
powPID = 0.0;
} else if (Math.abs(vel - velo) < 100 && ticker > 16){
double feed = Math.log((668.39 / (vel + 591.96)) - 0.116) / -4.18;
// --- PROPORTIONAL CORRECTION ---
double error = vel - velo;
double correction = kP * error;
// limit how fast power changes (prevents oscillation)
correction = Math.max(-maxStep, Math.min(maxStep, correction));
// --- FINAL MOTOR POWER ---
powPID = feed + correction;
// clamp to allowed range
powPID = Math.max(0, Math.min(1, powPID));
}
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition());
velo = flywheel.getVelo();
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
robot.spin1.setPosition(spindexer);
robot.spin2.setPosition(1-spindexer);
TELE.addData("Velocity", velo);
TELE.addLine("spindex");
TELE.update();
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
return !spindexPosEqual(spindexer);
}
};
}
public Action Shoot(double vel) {
return new Action() {
double transferStamp = 0.0;
int ticker = 1;
boolean transferIn = false;
double currentPos = 0.0;
double stamp = 0.0;
double initPos = 0.0;
double stamp1 = 0.0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
TELE.addData("Velocity", velo);
TELE.addLine("shooting");
TELE.update();
if (ticker % 8 == 0) {
currentPos = (double) robot.shooter1.getCurrentPosition() / 2048;
stamp = getRuntime();
velo = -60 * ((currentPos - initPos) / (stamp - stamp1));
initPos = currentPos;
stamp1 = stamp;
}
if (vel - velo > 500 && ticker > 16) {
powPID = 1.0;
} else if (velo - vel > 500 && ticker > 16){
powPID = 0.0;
} else if (Math.abs(vel - velo) < 100 && ticker > 16){
double feed = Math.log((668.39 / (vel + 591.96)) - 0.116) / -4.18;
// --- PROPORTIONAL CORRECTION ---
double error = vel - velo;
double correction = kP * error;
// limit how fast power changes (prevents oscillation)
correction = Math.max(-maxStep, Math.min(maxStep, correction));
// --- FINAL MOTOR POWER ---
powPID = feed + correction;
// clamp to allowed range
powPID = Math.max(0, Math.min(1, powPID));
}
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition());
velo = flywheel.getVelo();
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
if (ticker == 1) {
transferStamp = getRuntime();
ticker++;
}
if (getRuntime() - transferStamp > waitTransfer && !transferIn) {
robot.transferServo.setPosition(transferServo_in);
TELE.addData("Velocity", velo);
TELE.addData("ticker", ticker);
TELE.update();
transferIn = true;
return true;
} else if (getRuntime() - transferStamp > waitTransfer+waitTransferOut && transferIn){
robot.transferServo.setPosition(transferServo_out);
TELE.addData("Velocity", velo);
TELE.addLine("shot once");
TELE.update();
return false;
} else {
return true;
}
}
};
}
public Action intake(double intakeTime) {
return new Action() {
double position = 0.0;
double stamp = 0.0;
int ticker = 0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
if (ticker == 0) {
stamp = getRuntime();
}
ticker++;
double s1D = robot.color1.getDistance(DistanceUnit.MM);
double s2D = robot.color2.getDistance(DistanceUnit.MM);
double s3D = robot.color3.getDistance(DistanceUnit.MM);
if ((getRuntime() % 0.3) > 0.15) {
position = spindexer_intakePos1 + 0.02;
} else {
position = spindexer_intakePos1 - 0.02;
}
robot.spin1.setPosition(position);
robot.spin2.setPosition(1 - position);
TELE.addData("Velocity", velo);
TELE.addLine("Intaking");
TELE.update();
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
robot.intake.setPower(1);
if ((s1D < 40.0 && s2D < 40.0 && s3D < 40.0) || getRuntime() - stamp > intakeTime) {
return false;
} else {
return true;
}
}
};
}
public Action intakeReject() {
return new Action() {
double stamp = 0.0;
int ticker = 0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
if (ticker == 0) {
stamp = getRuntime();
}
ticker++;
if (getRuntime() - stamp < 0.3){
return true;
}else {
robot.intake.setPower(0);
return false;
}
}
};
}
public Action ColorDetect() {
return new Action() {
double stamp = 0.0;
int ticker = 0;
double position = 0.0;
@Override
public boolean run(@NonNull TelemetryPacket telemetryPacket) {
if (ticker == 0) {
stamp = getRuntime();
}
ticker++;
if ((getRuntime() % 0.3) > 0.15) {
position = spindexer_intakePos1 + 0.02;
} else {
position = spindexer_intakePos1 - 0.02;
}
robot.spin1.setPosition(position);
robot.spin2.setPosition(1 - position);
double s1D = robot.color1.getDistance(DistanceUnit.MM);
double s2D = robot.color2.getDistance(DistanceUnit.MM);
double s3D = robot.color3.getDistance(DistanceUnit.MM);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
if (s1D < 40) {
double green = robot.color1.getNormalizedColors().green;
double red = robot.color1.getNormalizedColors().red;
double blue = robot.color1.getNormalizedColors().blue;
double gP = green / (green + red + blue);
if (gP >= 0.4) {
b1 = 2;
} else {
b1 = 1;
}
}
if (s2D < 40) {
double green = robot.color2.getNormalizedColors().green;
double red = robot.color2.getNormalizedColors().red;
double blue = robot.color2.getNormalizedColors().blue;
double gP = green / (green + red + blue);
if (gP >= 0.4) {
b2 = 2;
} else {
b2 = 1;
}
}
if (s3D < 30) {
double green = robot.color3.getNormalizedColors().green;
double red = robot.color3.getNormalizedColors().red;
double blue = robot.color3.getNormalizedColors().blue;
double gP = green / (green + red + blue);
if (gP >= 0.4) {
b3 = 2;
} else {
b3 = 1;
}
}
TELE.addData("Velocity", velo);
TELE.addLine("Detecting");
TELE.addData("Distance 1", s1D);
TELE.addData("Distance 2", s2D);
TELE.addData("Distance 3", s3D);
TELE.addData("B1", b1);
TELE.addData("B2", b2);
TELE.addData("B3", b3);
TELE.update();
return (b1 + b2 + b3 < 4) && !(getRuntime() - stamp > colorDetect);
}
};
}
@Override
public void runOpMode() throws InterruptedException {
robot = new Robot(hardwareMap);
flywheel = new Flywheel();
TELE = new MultipleTelemetry(
telemetry, FtcDashboard.getInstance().getTelemetry()
);
drive = new MecanumDrive(hardwareMap, new Pose2d(
0, 0, 0
));
aprilTag = new AprilTagWebcam();
TrajectoryActionBuilder shoot0 = drive.actionBuilder(new Pose2d(0, 0, 0))
.strafeToLinearHeading(new Vector2d(rx1, ry1), rh1);
TrajectoryActionBuilder pickup1 = drive.actionBuilder(new Pose2d(rx1, ry1, rh1))
.strafeToLinearHeading(new Vector2d(rx2a, ry2a), rh2a)
.strafeToLinearHeading(new Vector2d(rx2b, ry2b), rh2b);
TrajectoryActionBuilder shoot1 = drive.actionBuilder(new Pose2d(rx2b, ry2b, rh2b))
.strafeToLinearHeading(new Vector2d(rx1, ry1), rh1);
TrajectoryActionBuilder pickup2 = drive.actionBuilder(new Pose2d(rx1, ry1, rh1))
.strafeToLinearHeading(new Vector2d(rx3a, ry3a), rh3a)
.strafeToLinearHeading(new Vector2d(rx3b, ry3b), rh3b);
TrajectoryActionBuilder shoot2 = drive.actionBuilder(new Pose2d(rx3b, ry3b, rh3b))
.strafeToLinearHeading(new Vector2d(rx1, ry1), rh1);
aprilTag.init(robot, TELE);
while (opModeInInit()) {
if (gamepad2.dpadUpWasPressed()) {
hoodAuto-= 0.01;
}
if (gamepad2.dpadDownWasPressed()) {
hoodAuto += 0.01;
}
robot.hood.setPosition(hoodAuto);
robot.turr1.setPosition(turret_detectRed);
robot.turr2.setPosition(1 - turret_detectRed);
robot.transferServo.setPosition(transferServo_out);
robot.spin1.setPosition(spindexer_intakePos1);
robot.spin2.setPosition(1 - spindexer_intakePos1);
aprilTag.update();
TELE.addData("Velocity", velo);
TELE.update();
}
waitForStart();
if (isStopRequested()) return;
if (opModeIsActive()) {
robot.hood.setPosition(hoodAuto);
Actions.runBlocking(
new ParallelAction(
shoot0.build(),
initShooter(AUTO_CLOSE_VEL),
Obelisk()
)
);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition());
velo = flywheel.getVelo();
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
shootingSequence();
robot.hood.setPosition(hoodAuto);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
Actions.runBlocking(
new ParallelAction(
pickup1.build(),
intake(intake1Time)
)
);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
Actions.runBlocking(
new ParallelAction(
shoot1.build(),
ColorDetect(),
steadyShooter(AUTO_CLOSE_VEL, true),
intakeReject()
)
);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition());
velo = flywheel.getVelo();
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
shootingSequence();
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
Actions.runBlocking(
new ParallelAction(
pickup2.build(),
intake(intake2Time)
)
);
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
Actions.runBlocking(
new ParallelAction(
shoot2.build(),
ColorDetect(),
steadyShooter(AUTO_CLOSE_VEL, true),
intakeReject()
)
);
powPID = flywheel.manageFlywheel(AUTO_CLOSE_VEL, (double) robot.shooter1.getCurrentPosition());
velo = flywheel.getVelo();
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
shootingSequence();
drive.updatePoseEstimate();
teleStart = drive.localizer.getPose();
TELE.addData("Velocity", velo);
TELE.addLine("finished");
TELE.update();
sleep(2000);
}
}
public void shootingSequence() {
TELE.addData("Velocity", velo);
if (gpp) {
if (b1 + b2 + b3 == 4) {
if (b1 == 2 && b2 - b3 == 0) {
sequence1();
TELE.addLine("sequence1");
} else if (b2 == 2 && b1 - b3 == 0) {
sequence3();
TELE.addLine("sequence3");
} else if (b3 == 2 && b1 - b2 == 0) {
sequence6();
TELE.addLine("sequence6");
} else {
sequence1();
TELE.addLine("sequence1");
}
} else if (b1 + b2 + b3 >= 5) {
if (b1 == 2) {
sequence1();
TELE.addLine("sequence1");
} else if (b2 == 2) {
sequence3();
TELE.addLine("sequence3");
} else if (b3 == 2) {
sequence6();
TELE.addLine("sequence6");
}
} else {
sequence1();
TELE.addLine("sequence1");
}
} else if (pgp) {
if (b1 + b2 + b3 == 4) {
if (b1 == 2 && b2 - b3 == 0) {
sequence3();
TELE.addLine("sequence3");
} else if (b2 == 2 && b1 - b3 == 0) {
sequence1();
TELE.addLine("sequence1");
} else if (b3 == 2 && b1 - b2 == 0) {
sequence4();
TELE.addLine("sequence4");
} else {
sequence1();
TELE.addLine("sequence1");
}
} else if (b1 + b2 + b3 >= 5) {
if (b1 == 2) {
sequence3();
TELE.addLine("sequence3");
} else if (b2 == 2) {
sequence1();
TELE.addLine("sequence1");
} else if (b3 == 2) {
sequence4();
TELE.addLine("sequence4");
}
} else {
sequence3();
TELE.addLine("sequence3");
}
} else if (ppg) {
if (b1 + b2 + b3 == 4) {
if (b1 == 2 && b2 - b3 == 0) {
sequence6();
TELE.addLine("sequence6");
} else if (b2 == 2 && b1 - b3 == 0) {
sequence5();
TELE.addLine("sequence5");
} else if (b3 == 2 && b1 - b2 == 0) {
sequence1();
TELE.addLine("sequence1");
} else {
sequence1();
TELE.addLine("sequence1");
}
} else if (b1 + b2 + b3 >= 5) {
if (b1 == 2) {
sequence6();
TELE.addLine("sequence6");
} else if (b2 == 2) {
sequence5();
TELE.addLine("sequence5");
} else if (b3 == 2) {
sequence1();
TELE.addLine("sequence1");
}
} else {
sequence6();
TELE.addLine("sequence6");
}
} else {
sequence1();
TELE.addLine("sequence1");
}
TELE.update();
}
public void sequence1() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall1, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall2, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall3, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL)
)
);
}
public void sequence2() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall1, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall3, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall2, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL)
)
);
}
public void sequence3() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall2, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall1, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall3, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL)
)
);
}
public void sequence4() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall2, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall3, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall1, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL)
)
);
}
public void sequence5() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall3, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall1, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall2, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL)
)
);
}
public void sequence6() {
Actions.runBlocking(
new SequentialAction(
spindex(spindexer_outtakeBall3, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall2, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL),
spindex(spindexer_outtakeBall1, AUTO_CLOSE_VEL),
Shoot(AUTO_CLOSE_VEL)
)
);
}
}

4
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/autonomous/blank.java
View File

@@ -1,4 +0,0 @@
package org.firstinspires.ftc.teamcode.autonomous;
public class blank {
}

1
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/constants/Color.java
View File

@@ -1,4 +1,5 @@
package org.firstinspires.ftc.teamcode.constants; package org.firstinspires.ftc.teamcode.constants;
public class Color { public class Color {
public static boolean redAlliance = true;
} }

46
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/constants/Poses.java
View File

@@ -12,40 +12,32 @@ public class Poses {
public static double relativeGoalHeight = goalHeight - turretHeight; public static double relativeGoalHeight = goalHeight - turretHeight;
public static double x1 = 50, y1 = 0, h1 = 0; public static Pose2d goalPose = new Pose2d(-10, 0, 0);
public static double x2 = 31, y2 = 32, h2 = Math.toRadians(140); public static double rx1 = 40, ry1 = -7, rh1 = 0;
public static double rx2a = 41, ry2a = 18, rh2a = Math.toRadians(140);
public static double rx2b = 23, ry2b = 36, rh2b = Math.toRadians(140);
public static double x2_b = 58, y2_b = 42, h2_b = Math.toRadians(140); public static double rx2c = 34, ry2c = 50, rh2c = Math.toRadians(140);
public static double x3 = 34, y3 = 58, h3 = Math.toRadians(140); public static double rx3a = 55, ry3a = 39, rh3a = Math.toRadians(140);
public static double rx3b = 33, ry3b = 61, rh3b = Math.toRadians(140);
public static double tx = 0, ty = 0, th = 0; public static double rx4a = 72, ry4a = 55, rh4a = Math.toRadians(140);
public static double rx4b = 48, ry4b = 79, rh4b = Math.toRadians(140);
public static Pose2d goalPose = new Pose2d(-15, 0, 0); public static double bx1 = 40, by1 = 7, bh1 = 0;
public static double bx2a = 45, by2a = -18, bh2a = Math.toRadians(-140);
public static double bx2b = 25, by2b = -38, bh2b = Math.toRadians(-140);
public static double bx2c = 34, by2c = -50, bh2c = Math.toRadians(-140);
public static double bx3a = 55, by3a = -43, bh3a = Math.toRadians(-140);
public static double bx3b = 37, by3b = -61, bh3b = Math.toRadians(-140);
public static double bx4a = 72, by4a = -55, bh4a = Math.toRadians(-140);
public static double bx4b = 48, by4b = -79, bh4b = Math.toRadians(-140);
public static double rfx1 = 10, rfy1 = 0, rfh1 = 0; //TODO: test this
public static double rx1 = 45, ry1 = -7, rh1 = 0; public static Pose2d teleStart = new Pose2d(0, 0, 0);
public static double rx2a = 45, ry2a = 5, rh2a = Math.toRadians(140);
public static double rx2b = 31, ry2b = 32, rh2b = Math.toRadians(140);
public static double rx3a = 58, ry3a = 42, rh3a = Math.toRadians(140);
public static double rx3b = 34, ry3b = 58, rh3b = Math.toRadians(140);
public static double bx1 = 45, by1 = 6, bh1 = 0;
public static double bx2a = 53, by2a = -7, bh2a = Math.toRadians(-140);
public static double bx2b = 23, by2b = -39, bh2b = Math.toRadians(-140);
public static double bx3a = 56, by3a = -34, bh3a = Math.toRadians(-140);
public static double bx3b = 34, by3b = -58, bh3b = Math.toRadians(-140);
public static Pose2d teleStart = new Pose2d(rx1, ry1, rh1);
} }

36
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/constants/ServoPositions.java
View File

@@ -5,16 +5,16 @@ import com.acmerobotics.dashboard.config.Config;
@Config @Config
public class ServoPositions { public class ServoPositions {
public static double spindexer_intakePos1 = 0.665; public static double spindexer_intakePos1 = 0.18;
public static double spindexer_intakePos3 = 0.29; public static double spindexer_intakePos2 = 0.36;//0.5;
public static double spindexer_intakePos2 = 0.99; public static double spindexer_intakePos3 = 0.54;//0.66;
public static double spindexer_outtakeBall3 = 0.845; public static double spindexer_outtakeBall3 = 0.47;
public static double spindexer_outtakeBall2 = 0.48; public static double spindexer_outtakeBall2 = 0.31;
public static double spindexer_outtakeBall1 = 0.1; public static double spindexer_outtakeBall1 = 0.15;
public static double transferServo_out = 0.15; public static double transferServo_out = 0.15;
@@ -24,18 +24,26 @@ public class ServoPositions {
public static double hoodDefault = 0.6; public static double hoodDefault = 0.6;
public static double hoodAuto = 0.55; public static double hoodAuto = 0.27;
public static double hoodHigh = 0.21; public static double hoodAutoFar = 0.5; //TODO: change this;
public static double hoodLow = 1.0; public static double hoodHigh = 0.21; //TODO: change this;
public static double turret_red = 0.42; public static double hoodLow = 1.0; //TODO: change this;
public static double turret_blue = 0.38;
public static double turret_detectRed = 0.2; public static double turret_redClose = 0.42;
public static double turret_blueClose = 0.38;
public static double turret_redFar = 0.5; //TODO: change this
public static double turret_blueFar = 0.5; // TODO: change this
public static double turret_detectRedClose = 0.2;
public static double turret_detectBlueClose = 0.6;
public static double turrDefault = 0.4;
public static double turrMin = 0.2;
public static double turrMax = 0.8;
public static double turret_detectBlue = 0.6;
public static double turrDefault = 0.40;
} }

5
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/constants/ShooterVars.java
View File

@@ -19,5 +19,8 @@ public class ShooterVars {
public static double maxStep = 0.06; // prevents sudden jumps public static double maxStep = 0.06; // prevents sudden jumps
// VELOCITY CONSTANTS // VELOCITY CONSTANTS
public static int AUTO_CLOSE_VEL = 3025; //3300; public static int AUTO_CLOSE_VEL = 3175; //3300;
public static int AUTO_FAR_VEL = 4000; //TODO: test this
public static Types.Motif currentMotif = Types.Motif.NONE;
} }

10
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/constants/Types.java Normal file
View File

@@ -0,0 +1,10 @@
package org.firstinspires.ftc.teamcode.constants;
public class Types {
public enum Motif {
NONE,
GPP, // Green, Purple, Purple
PGP, // Purple, Green, Purple
PPG // Purple, Purple, Green
}
}

4
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/constants/blank.java
View File

@@ -1,4 +0,0 @@
package org.firstinspires.ftc.teamcode.constants;
public class blank {
}

275
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/libs/RR/MecanumDrive.java
View File

@@ -5,7 +5,9 @@ import androidx.annotation.NonNull;
import com.acmerobotics.dashboard.canvas.Canvas; import com.acmerobotics.dashboard.canvas.Canvas;
import com.acmerobotics.dashboard.config.Config; import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.TelemetryPacket; import com.acmerobotics.dashboard.telemetry.TelemetryPacket;
import com.acmerobotics.roadrunner.*; import com.acmerobotics.roadrunner.AccelConstraint;
import com.acmerobotics.roadrunner.Action;
import com.acmerobotics.roadrunner.Actions;
import com.acmerobotics.roadrunner.AngularVelConstraint; import com.acmerobotics.roadrunner.AngularVelConstraint;
import com.acmerobotics.roadrunner.DualNum; import com.acmerobotics.roadrunner.DualNum;
import com.acmerobotics.roadrunner.HolonomicController; import com.acmerobotics.roadrunner.HolonomicController;
@@ -14,12 +16,20 @@ import com.acmerobotics.roadrunner.MinVelConstraint;
import com.acmerobotics.roadrunner.MotorFeedforward; import com.acmerobotics.roadrunner.MotorFeedforward;
import com.acmerobotics.roadrunner.Pose2d; import com.acmerobotics.roadrunner.Pose2d;
import com.acmerobotics.roadrunner.Pose2dDual; import com.acmerobotics.roadrunner.Pose2dDual;
import com.acmerobotics.roadrunner.PoseVelocity2d;
import com.acmerobotics.roadrunner.PoseVelocity2dDual;
import com.acmerobotics.roadrunner.ProfileAccelConstraint; import com.acmerobotics.roadrunner.ProfileAccelConstraint;
import com.acmerobotics.roadrunner.ProfileParams;
import com.acmerobotics.roadrunner.Rotation2d;
import com.acmerobotics.roadrunner.Time; import com.acmerobotics.roadrunner.Time;
import com.acmerobotics.roadrunner.TimeTrajectory; import com.acmerobotics.roadrunner.TimeTrajectory;
import com.acmerobotics.roadrunner.TimeTurn; import com.acmerobotics.roadrunner.TimeTurn;
import com.acmerobotics.roadrunner.TrajectoryActionBuilder; import com.acmerobotics.roadrunner.TrajectoryActionBuilder;
import com.acmerobotics.roadrunner.TrajectoryBuilderParams;
import com.acmerobotics.roadrunner.TurnConstraints; import com.acmerobotics.roadrunner.TurnConstraints;
import com.acmerobotics.roadrunner.Twist2d;
import com.acmerobotics.roadrunner.Twist2dDual;
import com.acmerobotics.roadrunner.Vector2d;
import com.acmerobotics.roadrunner.VelConstraint; import com.acmerobotics.roadrunner.VelConstraint;
import com.acmerobotics.roadrunner.ftc.DownsampledWriter; import com.acmerobotics.roadrunner.ftc.DownsampledWriter;
import com.acmerobotics.roadrunner.ftc.Encoder; import com.acmerobotics.roadrunner.ftc.Encoder;
@@ -46,13 +56,131 @@ import org.firstinspires.ftc.teamcode.libs.RR.messages.MecanumCommandMessage;
import org.firstinspires.ftc.teamcode.libs.RR.messages.MecanumLocalizerInputsMessage; import org.firstinspires.ftc.teamcode.libs.RR.messages.MecanumLocalizerInputsMessage;
import org.firstinspires.ftc.teamcode.libs.RR.messages.PoseMessage; import org.firstinspires.ftc.teamcode.libs.RR.messages.PoseMessage;
import java.lang.Math;
import java.util.Arrays; import java.util.Arrays;
import java.util.LinkedList; import java.util.LinkedList;
import java.util.List; import java.util.List;
@Config @Config
public final class MecanumDrive { public final class MecanumDrive {
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;
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 MecanumDrive(HardwareMap hardwareMap, Pose2d 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, "fl");
leftBack = hardwareMap.get(DcMotorEx.class, "bl");
rightBack = hardwareMap.get(DcMotorEx.class, "br");
rightFront = hardwareMap.get(DcMotorEx.class, "fr");
leftFront.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.BRAKE);
leftBack.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.BRAKE);
rightBack.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.BRAKE);
rightFront.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.BRAKE);
// TODO: reverse motor directions if needed
//
leftFront.setDirection(DcMotorSimple.Direction.REVERSE);
leftBack.setDirection(DcMotorSimple.Direction.REVERSE);
// 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 LazyHardwareMapImu(hardwareMap, "imu", new RevHubOrientationOnRobot(
PARAMS.logoFacingDirection, PARAMS.usbFacingDirection));
voltageSensor = hardwareMap.voltageSensor.iterator().next();
localizer = new PinpointLocalizer(hardwareMap, PARAMS.inPerTick, pose);
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 PoseVelocity2d updatePoseEstimate() {
PoseVelocity2d vel = localizer.update();
poseHistory.add(localizer.getPose());
while (poseHistory.size() > 100) {
poseHistory.removeFirst();
}
estimatedPoseWriter.write(new PoseMessage(localizer.getPose()));
return vel;
}
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
);
}
public static class Params { public static class Params {
// IMU orientation // IMU orientation
// TODO: fill in these values based on // TODO: fill in these values based on
@@ -78,8 +206,8 @@ public final class MecanumDrive {
public double maxProfileAccel = 180; public double maxProfileAccel = 180;
// turn profile parameters (in radians) // turn profile parameters (in radians)
public double maxAngVel = 4* Math.PI; // shared with path public double maxAngVel = 4 * Math.PI; // shared with path
public double maxAngAccel = 4* Math.PI; public double maxAngAccel = 4 * Math.PI;
// path controller gains // path controller gains
public double axialGain = 4; public double axialGain = 4;
@@ -91,35 +219,6 @@ public final class MecanumDrive {
public double headingVelGain = 0.0; // shared with turn 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;
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 class DriveLocalizer implements Localizer {
public final Encoder leftFront, leftBack, rightBack, rightFront; public final Encoder leftFront, leftBack, rightBack, rightFront;
public final IMU imu; public final IMU imu;
@@ -144,13 +243,13 @@ public final class MecanumDrive {
} }
@Override @Override
public void setPose(Pose2d pose) { public Pose2d getPose() {
this.pose = pose; return pose;
} }
@Override @Override
public Pose2d getPose() { public void setPose(Pose2d pose) {
return pose; this.pose = pose;
} }
@Override @Override
@@ -216,63 +315,10 @@ public final class MecanumDrive {
} }
} }
public MecanumDrive(HardwareMap hardwareMap, Pose2d 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, "fl");
leftBack = hardwareMap.get(DcMotorEx.class, "bl");
rightBack = hardwareMap.get(DcMotorEx.class, "br");
rightFront = hardwareMap.get(DcMotorEx.class, "fr");
leftFront.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.BRAKE);
leftBack.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.BRAKE);
rightBack.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.BRAKE);
rightFront.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.BRAKE);
// TODO: reverse motor directions if needed
//
leftFront.setDirection(DcMotorSimple.Direction.REVERSE);
leftBack.setDirection(DcMotorSimple.Direction.REVERSE);
// 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 LazyHardwareMapImu(hardwareMap, "imu", new RevHubOrientationOnRobot(
PARAMS.logoFacingDirection, PARAMS.usbFacingDirection));
voltageSensor = hardwareMap.voltageSensor.iterator().next();
localizer = new PinpointLocalizer(hardwareMap, PARAMS.inPerTick, pose);
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 class FollowTrajectoryAction implements Action {
public final TimeTrajectory timeTrajectory; public final TimeTrajectory timeTrajectory;
private double beginTs = -1;
private final double[] xPoints, yPoints; private final double[] xPoints, yPoints;
private double beginTs = -1;
public FollowTrajectoryAction(TimeTrajectory t) { public FollowTrajectoryAction(TimeTrajectory t) {
timeTrajectory = t; timeTrajectory = t;
@@ -450,51 +496,4 @@ public final class MecanumDrive {
c.fillCircle(turn.beginPose.position.x, turn.beginPose.position.y, 2); c.fillCircle(turn.beginPose.position.x, turn.beginPose.position.y, 2);
} }
} }
public PoseVelocity2d updatePoseEstimate() {
PoseVelocity2d vel = localizer.update();
poseHistory.add(localizer.getPose());
while (poseHistory.size() > 100) {
poseHistory.removeFirst();
}
estimatedPoseWriter.write(new PoseMessage(localizer.getPose()));
return vel;
}
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
);
}
} }

204
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/teleop/TeleopV2.java
View File

@@ -1,19 +1,9 @@
package org.firstinspires.ftc.teamcode.teleop; package org.firstinspires.ftc.teamcode.teleop;
import static org.firstinspires.ftc.teamcode.constants.Poses.teleStart; import static org.firstinspires.ftc.teamcode.constants.Poses.*;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_intakePos1; import static org.firstinspires.ftc.teamcode.constants.ServoPositions.*;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_outtakeBall1; import static org.firstinspires.ftc.teamcode.constants.ShooterVars.*;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_outtakeBall2; import static org.firstinspires.ftc.teamcode.tests.PIDServoTest.*;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_outtakeBall3;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.transferServo_in;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.transferServo_out;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.turrDefault;
import static org.firstinspires.ftc.teamcode.constants.ShooterVars.waitTransfer;
import static org.firstinspires.ftc.teamcode.constants.ShooterVars.waitTransferOut;
import static org.firstinspires.ftc.teamcode.tests.ShooterTest.kP;
import static org.firstinspires.ftc.teamcode.tests.ShooterTest.maxStep;
import static org.firstinspires.ftc.teamcode.utils.PositionalServoProgrammer.restPos;
import static org.firstinspires.ftc.teamcode.utils.PositionalServoProgrammer.scalar;
import com.acmerobotics.dashboard.FtcDashboard; import com.acmerobotics.dashboard.FtcDashboard;
import com.acmerobotics.dashboard.config.Config; import com.acmerobotics.dashboard.config.Config;
@@ -26,7 +16,9 @@ import com.qualcomm.robotcore.eventloop.opmode.TeleOp;
import org.firstinspires.ftc.robotcore.external.navigation.DistanceUnit; import org.firstinspires.ftc.robotcore.external.navigation.DistanceUnit;
import org.firstinspires.ftc.teamcode.libs.RR.MecanumDrive; import org.firstinspires.ftc.teamcode.libs.RR.MecanumDrive;
import org.firstinspires.ftc.teamcode.utils.AprilTagWebcam; import org.firstinspires.ftc.teamcode.utils.AprilTagWebcam;
import org.firstinspires.ftc.teamcode.utils.Flywheel;
import org.firstinspires.ftc.teamcode.utils.Robot; import org.firstinspires.ftc.teamcode.utils.Robot;
import org.firstinspires.ftc.teamcode.utils.Servos;
import org.firstinspires.ftc.vision.apriltag.AprilTagDetection; import org.firstinspires.ftc.vision.apriltag.AprilTagDetection;
import java.util.ArrayList; import java.util.ArrayList;
@@ -35,7 +27,8 @@ import java.util.List;
@TeleOp @TeleOp
@Config @Config
public class TeleopV2 extends LinearOpMode { public class TeleopV2 extends LinearOpMode {
Servos servo;
Flywheel flywheel;
public static double manualVel = 3000; public static double manualVel = 3000;
public static double hood = 0.5; public static double hood = 0.5;
public static double hoodDefaultPos = 0.5; public static double hoodDefaultPos = 0.5;
@@ -63,6 +56,7 @@ public class TeleopV2 extends LinearOpMode {
double yOffset = 0.0; double yOffset = 0.0;
double headingOffset = 0.0; double headingOffset = 0.0;
int ticker = 0; int ticker = 0;
int camTicker = 0;
List<Double> s1G = new ArrayList<>(); List<Double> s1G = new ArrayList<>();
List<Double> s2G = new ArrayList<>(); List<Double> s2G = new ArrayList<>();
List<Double> s3G = new ArrayList<>(); List<Double> s3G = new ArrayList<>();
@@ -98,6 +92,11 @@ public class TeleopV2 extends LinearOpMode {
private double transferStamp = 0.0; private double transferStamp = 0.0;
private int tickerA = 1; private int tickerA = 1;
private boolean transferIn = false; private boolean transferIn = false;
double turretPID = 0.0;
double turretPos = 0.5;
double spindexPID = 0.0;
double spindexPos = spindexer_intakePos1;
double error = 0.0;
public static double velPrediction(double distance) { public static double velPrediction(double distance) {
@@ -129,6 +128,8 @@ public class TeleopV2 extends LinearOpMode {
TELE = new MultipleTelemetry( TELE = new MultipleTelemetry(
telemetry, FtcDashboard.getInstance().getTelemetry() telemetry, FtcDashboard.getInstance().getTelemetry()
); );
servo = new Servos(hardwareMap);
flywheel = new Flywheel(hardwareMap);
drive = new MecanumDrive(hardwareMap, teleStart); drive = new MecanumDrive(hardwareMap, teleStart);
@@ -136,9 +137,6 @@ public class TeleopV2 extends LinearOpMode {
aprilTagWebcam.init(new Robot(hardwareMap), TELE); aprilTagWebcam.init(new Robot(hardwareMap), TELE);
robot.turr1.setPosition(0.4);
robot.turr2.setPosition(1 - 0.4);
waitForStart(); waitForStart();
if (isStopRequested()) return; if (isStopRequested()) return;
while (opModeIsActive()) { while (opModeIsActive()) {
@@ -160,6 +158,17 @@ public class TeleopV2 extends LinearOpMode {
robot.frontRight.setPower(frontRightPower); robot.frontRight.setPower(frontRightPower);
robot.backRight.setPower(backRightPower); robot.backRight.setPower(backRightPower);
//TODO: make sure changing position works throughout opmode
if (!servo.spinEqual(spindexPos)){
spindexPID = servo.setSpinPos(spindexPos);
robot.spin1.setPower(spindexPID);
robot.spin2.setPower(-spindexPID);
} else{
robot.spin1.setPower(0);
robot.spin2.setPower(0);
}
//INTAKE: //INTAKE:
if (gamepad1.rightBumperWasPressed()) { if (gamepad1.rightBumperWasPressed()) {
@@ -183,22 +192,15 @@ public class TeleopV2 extends LinearOpMode {
robot.intake.setPower(1); robot.intake.setPower(1);
double position;
if ((getRuntime() % 0.3) > 0.15) { if ((getRuntime() % 0.3) > 0.15) {
position = spindexer_intakePos1 + 0.015; spindexPos = spindexer_intakePos1 + 0.015;
} else { } else {
position = spindexer_intakePos1 - 0.015; spindexPos = spindexer_intakePos1 - 0.015;
} }
robot.spin1.setPosition(position);
robot.spin2.setPosition(1 - position);
} else if (reject) { } else if (reject) {
robot.intake.setPower(-1); robot.intake.setPower(-1);
double position = spindexer_intakePos1; spindexPos = spindexer_intakePos1;
robot.spin1.setPosition(position);
robot.spin2.setPosition(1 - position);
} else { } else {
robot.intake.setPower(0); robot.intake.setPower(0);
} }
@@ -280,51 +282,9 @@ public class TeleopV2 extends LinearOpMode {
//SHOOTER: //SHOOTER:
double penguin = 0; double powPID = flywheel.manageFlywheel((int) vel);
if (ticker % 8 == 0) { robot.transfer.setPower(1);
penguin = (double) robot.shooterEncoder.getCurrentPosition() / 2048;
double stamp = getRuntime();
velo1 = -60 * ((penguin - initPos) / (stamp - stamp1));
initPos = penguin;
stamp1 = stamp;
}
velo = velo1;
double feed = vel / 4500;
if (vel > 500) {
feed = Math.log((668.39 / (vel + 591.96)) - 0.116) / -4.18;
}
// --- PROPORTIONAL CORRECTION ---
double error = vel - velo1;
double correction = kP * error;
// limit how fast power changes (prevents oscillation)
correction = Math.max(-maxStep, Math.min(maxStep, correction));
// --- FINAL MOTOR POWER ---
double powPID = feed + correction;
// clamp to allowed range
powPID = Math.max(0, Math.min(1, powPID));
if (vel - velo > 1000) {
powPID = 1;
} else if (velo - vel > 1000) {
powPID = 0;
}
TELE.addData("PIDPower", powPID);
TELE.addData("vel", velo1);
robot.shooter1.setPower(powPID);
robot.shooter2.setPower(powPID);
robot.transfer.setPower(1);
//TURRET: //TURRET:
@@ -355,7 +315,8 @@ public class TeleopV2 extends LinearOpMode {
offset -= 360; offset -= 360;
} }
double pos = turrDefault; //TODO: test the camera teleop code
double pos = turrDefault + (error/8); // adds the overall error to the default
TELE.addData("offset", offset); TELE.addData("offset", offset);
@@ -367,14 +328,51 @@ public class TeleopV2 extends LinearOpMode {
pos = 0.97; pos = 0.97;
} }
if (y < 0.1 && y > -0.1 && x < 0.1 && x > -0.1 && rx < 0.1 && rx > -0.1){ //not moving
AprilTagDetection d20 = aprilTagWebcam.getTagById(20);
AprilTagDetection d24 = aprilTagWebcam.getTagById(24);
double bearing = 0.0;
if (d20 != null || d24 != null){
if (d20 != null) {
bearing = d20.ftcPose.bearing;
}
if (d24 != null) {
bearing = d24.ftcPose.bearing;
}
overrideTurr = true;
turretPos = servo.getTurrPos() - (bearing/1300);
TELE.addData("Bear", bearing);
double bearingCorrection = bearing / 1300;
// deadband: ignore tiny noise
if (Math.abs(bearing) > 0.3 && camTicker < 8) {
// only accumulate if bearing direction is consistent
if (Math.signum(bearingCorrection) == Math.signum(error) || error == 0) {
error += bearingCorrection;
}
}
camTicker++;
}
} else {
camTicker = 0;
overrideTurr = false;
}
if (manualTurret) { if (manualTurret) {
pos = turrDefault + (manualOffset / 100); pos = turrDefault + (manualOffset / 100);
} }
if (!overrideTurr) { if (!overrideTurr) {
turretPos = pos;
robot.turr1.setPosition(pos);
robot.turr2.setPosition(1 - pos);
} }
if (gamepad2.dpad_right) { if (gamepad2.dpad_right) {
@@ -455,12 +453,9 @@ public class TeleopV2 extends LinearOpMode {
reject = true; reject = true;
if (getRuntime() % 3 > 1.5) { if (getRuntime() % 3 > 1.5) {
robot.spin1.setPosition(0); spindexPos = 1;
robot.spin2.setPosition(1);
} else { } else {
spindexPos = 0;
robot.spin1.setPosition(1);
robot.spin2.setPosition(0);
} }
robot.transferServo.setPosition(transferServo_out); robot.transferServo.setPosition(transferServo_out);
@@ -478,39 +473,14 @@ public class TeleopV2 extends LinearOpMode {
int currentSlot = shootOrder.get(0); // Peek, do NOT remove yet int currentSlot = shootOrder.get(0); // Peek, do NOT remove yet
boolean shootingDone = false; boolean shootingDone = false;
AprilTagDetection d20 = aprilTagWebcam.getTagById(20);
AprilTagDetection d24 = aprilTagWebcam.getTagById(24);
if (d20 != null) {
overrideTurr = true;
double bearing = d20.ftcPose.bearing;
double finalPos = robot.turr1.getPosition() - (bearing / 1300);
robot.turr1.setPosition(finalPos);
robot.turr2.setPosition(1 - finalPos);
TELE.addData("Bear", bearing);
}
if (d24 != null) {
overrideTurr = true;
double bearing = d24.ftcPose.bearing;
double finalPos = robot.turr1.getPosition() - (bearing / 1300);
robot.turr1.setPosition(finalPos);
robot.turr2.setPosition(1 - finalPos);
}
if (!outtake1) { if (!outtake1) {
outtake1 = (spindexPosEqual(spindexer_outtakeBall1)); outtake1 = (servo.spinEqual(spindexer_outtakeBall1));
} }
if (!outtake2) { if (!outtake2) {
outtake2 = (spindexPosEqual(spindexer_outtakeBall2)); outtake2 = (servo.spinEqual(spindexer_outtakeBall2));
} }
if (!outtake3) { if (!outtake3) {
outtake3 = (spindexPosEqual(spindexer_outtakeBall3)); outtake3 = (servo.spinEqual(spindexer_outtakeBall3));
} }
switch (currentSlot) { switch (currentSlot) {
@@ -553,8 +523,7 @@ public class TeleopV2 extends LinearOpMode {
} else { } else {
// Finished shooting all balls // Finished shooting all balls
robot.spin1.setPosition(spindexer_intakePos1); spindexPos = spindexer_intakePos1;
robot.spin2.setPosition(1 - spindexer_intakePos1);
shootA = true; shootA = true;
shootB = true; shootB = true;
shootC = true; shootC = true;
@@ -767,15 +736,9 @@ public class TeleopV2 extends LinearOpMode {
return countTrue > countWindow / 2.0; // more than 50% true return countTrue > countWindow / 2.0; // more than 50% true
} }
boolean spindexPosEqual(double spindexer) {
return (scalar * ((robot.spin1Pos.getVoltage() - restPos) / 3.3) > spindexer - 0.01 &&
scalar * ((robot.spin1Pos.getVoltage() - restPos) / 3.3) < spindexer + 0.01);
}
public boolean shootTeleop(double spindexer, boolean spinOk, double stamp) { public boolean shootTeleop(double spindexer, boolean spinOk, double stamp) {
// Set spin positions // Set spin positions
robot.spin1.setPosition(spindexer); spindexPos = spindexer;
robot.spin2.setPosition(1 - spindexer);
// Check if spindexer has reached the target position // Check if spindexer has reached the target position
if (spinOk || getRuntime() - stamp > 1.5) { if (spinOk || getRuntime() - stamp > 1.5) {
@@ -930,9 +893,4 @@ public class TeleopV2 extends LinearOpMode {
} }
return true; // default return true; // default
} }
public double turretPos() {
return (scalar * ((robot.turr1Pos.getVoltage() - restPos) / 3.3));
}
} }

1013
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/teleop/TeleopV3.java Normal file
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File diff suppressed because it is too large Load Diff

55
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/tests/ColorTest.java Normal file
View File

@@ -0,0 +1,55 @@
package org.firstinspires.ftc.teamcode.tests;
import com.acmerobotics.dashboard.FtcDashboard;
import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import com.qualcomm.robotcore.eventloop.opmode.TeleOp;
import org.firstinspires.ftc.robotcore.external.navigation.DistanceUnit;
import org.firstinspires.ftc.teamcode.utils.Robot;
@Config
@TeleOp
public class ColorTest extends LinearOpMode {
Robot robot;
MultipleTelemetry TELE;
@Override
public void runOpMode() throws InterruptedException {
robot = new Robot(hardwareMap);
TELE = new MultipleTelemetry(telemetry, FtcDashboard.getInstance().getTelemetry());
waitForStart();
if (isStopRequested()) return;
while(opModeIsActive()){
double green1 = robot.color1.getNormalizedColors().green;
double blue1 = robot.color1.getNormalizedColors().blue;
double red1 = robot.color1.getNormalizedColors().red;
TELE.addData("Color1 toColor", robot.color1.getNormalizedColors().toColor());
TELE.addData("Color1 green", green1 / (green1 + blue1 + red1));
TELE.addData("Color1 distance (mm)", robot.color1.getDistance(DistanceUnit.MM));
// ----- COLOR 2 -----
double green2 = robot.color2.getNormalizedColors().green;
double blue2 = robot.color2.getNormalizedColors().blue;
double red2 = robot.color2.getNormalizedColors().red;
TELE.addData("Color2 toColor", robot.color2.getNormalizedColors().toColor());
TELE.addData("Color2 green", green2 / (green2 + blue2 + red2));
TELE.addData("Color2 distance (mm)", robot.color2.getDistance(DistanceUnit.MM));
// ----- COLOR 3 -----
double green3 = robot.color3.getNormalizedColors().green;
double blue3 = robot.color3.getNormalizedColors().blue;
double red3 = robot.color3.getNormalizedColors().red;
TELE.addData("Color3 toColor", robot.color3.getNormalizedColors().toColor());
TELE.addData("Color3 green", green3 / (green3 + blue3 + red3));
TELE.addData("Color3 distance (mm)", robot.color3.getDistance(DistanceUnit.MM));
TELE.update();
}
}
}

223
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/tests/IntakeTest.java Normal file
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@@ -0,0 +1,223 @@
package org.firstinspires.ftc.teamcode.tests;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.*;
import com.acmerobotics.dashboard.FtcDashboard;
import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
import com.qualcomm.hardware.lynx.LynxModule;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import com.qualcomm.robotcore.eventloop.opmode.TeleOp;
import org.firstinspires.ftc.robotcore.external.navigation.DistanceUnit;
import org.firstinspires.ftc.teamcode.utils.Robot;
import org.firstinspires.ftc.teamcode.utils.Servos;
import java.util.ArrayList;
import java.util.List;
@Config
@TeleOp
public class IntakeTest extends LinearOpMode {
Robot robot;
MultipleTelemetry TELE;
Servos servo;
public boolean green1 = false;
public boolean green2 = false;
public boolean green3 = false;
List<Double> s1G = new ArrayList<>();
List<Double> s2G = new ArrayList<>();
List<Double> s3G = new ArrayList<>();
List<Double> s1T = new ArrayList<>();
List<Double> s2T = new ArrayList<>();
List<Double> s3T = new ArrayList<>();
List<Boolean> s1 = new ArrayList<>();
List<Boolean> s2 = new ArrayList<>();
List<Boolean> s3 = new ArrayList<>();
public static int mode = 0; // 0 for teleop, 1 for auto
public static double manualPow = 0.15;
double stamp = 0;
int ticker = 0;
boolean steadySpin = false;
double powPID = 0.0;
boolean intake = true;
double spindexerPos = spindexer_intakePos1;
boolean wasMoving = false;
double currentPos = 0.0;
double initPos = 0.0;
boolean reverse = false;
@Override
public void runOpMode() throws InterruptedException {
List<LynxModule> allHubs = hardwareMap.getAll(LynxModule.class);
for (LynxModule hub : allHubs) {
hub.setBulkCachingMode(LynxModule.BulkCachingMode.MANUAL);
}
robot = new Robot(hardwareMap);
servo = new Servos(hardwareMap);
TELE = new MultipleTelemetry(telemetry, FtcDashboard.getInstance().getTelemetry());
waitForStart();
if (isStopRequested()) return;
while (opModeIsActive()) {
if (mode == 0) {
if (gamepad1.right_bumper) {
ticker++;
if (ticker % 16 == 0){
currentPos = servo.getSpinPos();
if (Math.abs(currentPos - initPos) == 0.0){
reverse = !reverse;
}
initPos = currentPos;
}
if (reverse){
robot.spin1.setPower(manualPow);
robot.spin2.setPower(-manualPow);
} else {
robot.spin1.setPower(-manualPow);
robot.spin2.setPower(manualPow);
}
robot.intake.setPower(1);
stamp = getRuntime();
TELE.addData("Reverse?", reverse);
TELE.update();
} else {
robot.spin1.setPower(0);
robot.spin2.setPower(0);
if (getRuntime() - stamp < 1) {
robot.intake.setPower(-(getRuntime() - stamp)*2);
} else {
robot.intake.setPower(0);
}
ticker = 0;
}
} else if (mode == 1) {
if (gamepad1.right_bumper && intake){
robot.intake.setPower(1);
} else if (gamepad1.left_bumper){
robot.intake.setPower(-1);
} else {
robot.intake.setPower(0);
}
colorDetect();
spindexer();
if (ballIn(1) && steadySpin && intake && getRuntime() - stamp > 0.5){
if (!ballIn(2)){
if (servo.spinEqual(spindexer_intakePos1)){
spindexerPos = spindexer_intakePos2;
} else if (servo.spinEqual(spindexer_intakePos2)){
spindexerPos = spindexer_intakePos3;
} else if (servo.spinEqual(spindexer_intakePos3)){
spindexerPos = spindexer_intakePos1;
}
} else if (!ballIn(3)){
if (servo.spinEqual(spindexer_intakePos1)){
spindexerPos = spindexer_intakePos3;
} else if (servo.spinEqual(spindexer_intakePos2)){
spindexerPos = spindexer_intakePos1;
} else if (servo.spinEqual(spindexer_intakePos3)){
spindexerPos = spindexer_intakePos2;
}
}
}
} else if (mode == 2){ // switch to this mode before switching modes or to reset balls
powPID = 0;
spindexerPos = spindexer_intakePos1;
stamp = getRuntime();
ticker = 0;
spindexer();
intake = true;
}
for (LynxModule hub : allHubs) {
hub.clearBulkCache();
}
double y = -gamepad1.right_stick_y; // Remember, Y stick value is reversed
double x = gamepad1.right_stick_x * 1.1; // Counteract imperfect strafing
double rx = gamepad1.left_stick_x;
double denominator = Math.max(Math.abs(y) + Math.abs(x) + Math.abs(rx), 1);
double frontLeftPower = (y + x + rx) / denominator;
double backLeftPower = (y - x + rx) / denominator;
double frontRightPower = (y - x - rx) / denominator;
double backRightPower = (y + x - rx) / denominator;
robot.frontLeft.setPower(frontLeftPower);
robot.backLeft.setPower(backLeftPower);
robot.frontRight.setPower(frontRightPower);
robot.backRight.setPower(backRightPower);
TELE.addData("Manual Power", manualPow);
TELE.addData("PID Power", powPID);
TELE.addData("B1", ballIn(1));
TELE.addData("B2", ballIn(2));
TELE.addData("B3", ballIn(3));
TELE.addData("Spindex Pos", servo.getSpinPos());
TELE.update();
}
}
public void colorDetect() {
double s1D = robot.color1.getDistance(DistanceUnit.MM);
double s2D = robot.color2.getDistance(DistanceUnit.MM);
double s3D = robot.color3.getDistance(DistanceUnit.MM);
TELE.addData("Color 1 Distance", s1D);
TELE.addData("Color 2 Distance", s2D);
TELE.addData("Color 3 Distance", s3D);
TELE.update();
if (s1D < 43) {
s1T.add(getRuntime());
}
if (s2D < 60) {
s2T.add(getRuntime());
}
if (s3D < 33) {
s3T.add(getRuntime());
}
}
public void spindexer() {
boolean atTarget = servo.spinEqual(spindexerPos);
if (!atTarget) {
powPID = servo.setSpinPos(spindexerPos);
robot.spin1.setPower(powPID);
robot.spin2.setPower(-powPID);
steadySpin = false;
wasMoving = true; // remember we were moving
stamp = getRuntime();
} else {
robot.spin1.setPower(0);
robot.spin2.setPower(0);
steadySpin = true;
wasMoving = false;
}
}
boolean ballIn(int slot) {
List<Double> times;
if (slot == 1) {times = s1T;}
else if (slot == 2) {times = s2T;}
else if (slot == 3) {times = s3T;}
else return false;
if (!times.isEmpty()){
return times.get(times.size() - 1) > getRuntime() - 2;
} else {
return false;
}
}
}

69
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/tests/LimelightTest.java Normal file
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@@ -0,0 +1,69 @@
package org.firstinspires.ftc.teamcode.tests;
import com.acmerobotics.dashboard.FtcDashboard;
import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
import com.qualcomm.hardware.limelightvision.LLResult;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import com.qualcomm.robotcore.eventloop.opmode.TeleOp;
import org.firstinspires.ftc.teamcode.utils.Robot;
import org.firstinspires.ftc.teamcode.utils.Turret;
@Config
@TeleOp
//TODO: fix to get the apriltag that it is reading
public class LimelightTest extends LinearOpMode {
MultipleTelemetry TELE;
Turret turret;
Robot robot;
public static int pipeline = 0; //0 is for test; 1 for obelisk; 2 is for blue track; 3 is for red track
public static int mode = 0; //0 for bare testing, 1 for obelisk, 2 for blue track, 3 for red track
public static boolean turretMode = false;
public static double turretPos = 0.501;
@Override
public void runOpMode() throws InterruptedException {
TELE = new MultipleTelemetry(telemetry, FtcDashboard.getInstance().getTelemetry());
robot = new Robot(hardwareMap);
turret = new Turret(robot, TELE, robot.limelight);
robot.limelight.pipelineSwitch(pipeline);
waitForStart();
if (isStopRequested()) return;
while (opModeIsActive()){
if (mode == 0){
robot.limelight.pipelineSwitch(pipeline);
LLResult result = robot.limelight.getLatestResult();
if (result != null) {
if (result.isValid()) {
TELE.addData("tx", result.getTx());
TELE.addData("ty", result.getTy());
TELE.update();
}
}
} else if (mode == 1){
int obeliskID = turret.detectObelisk();
TELE.addData("Limelight ID", obeliskID);
TELE.update();
} else if (mode == 2 || mode == 3){ // Use redAlliance variable to switch between red and blue
double tx = turret.getBearing();
double ty = turret.getTy();
double x = turret.getLimelightX();
double y = turret.getLimelightY();
TELE.addData("tx", tx);
TELE.addData("ty", ty);
TELE.addData("x", x);
TELE.addData("y", y);
TELE.update();
} else {
robot.limelight.pipelineSwitch(0);
}
if (turretMode){
if (turretPos != 0.501){
turret.manualSetTurret(turretPos);
}
}
}
}
}

64
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/tests/PIDServoTest.java Normal file
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@@ -0,0 +1,64 @@
package org.firstinspires.ftc.teamcode.tests;
import com.acmerobotics.dashboard.FtcDashboard;
import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
import com.arcrobotics.ftclib.controller.PIDFController;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import com.qualcomm.robotcore.eventloop.opmode.TeleOp;
import org.firstinspires.ftc.teamcode.utils.Robot;
@TeleOp
@Config
public class PIDServoTest extends LinearOpMode {
public static double p = 2, i = 0, d = 0, f = 0;
public static double target = 0.5;
public static int mode = 0; //0 is for turret, 1 is for spindexer
public static double scalar = 1.01;
public static double restPos = 0.0;
Robot robot;
double pos = 0.0;
@Override
public void runOpMode() throws InterruptedException {
PIDFController controller = new PIDFController(p, i, d, f);
controller.setTolerance(0.001);
robot = new Robot(hardwareMap);
telemetry = new MultipleTelemetry(telemetry, FtcDashboard.getInstance().getTelemetry());
waitForStart();
if (isStopRequested()) return;
while (opModeIsActive()) {
controller.setPIDF(p, i, d, f);
if (mode == 1) {
pos = scalar * ((robot.spin1Pos.getVoltage() - restPos) / 3.3);
double pid = controller.calculate(pos, target);
robot.spin1.setPower(pid);
robot.spin2.setPower(-pid);
}
telemetry.addData("pos", pos);
telemetry.addData("Spindex Voltage", robot.spin1Pos.getVoltage());
telemetry.addData("target", target);
telemetry.addData("Mode", mode);
telemetry.update();
}
}
}

140
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/tests/ShooterTest.java
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@@ -1,5 +1,9 @@
package org.firstinspires.ftc.teamcode.tests; package org.firstinspires.ftc.teamcode.tests;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_intakePos1;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.transferServo_in;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.transferServo_out;
import com.acmerobotics.dashboard.FtcDashboard; import com.acmerobotics.dashboard.FtcDashboard;
import com.acmerobotics.dashboard.config.Config; import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry; import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
@@ -7,27 +11,41 @@ import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import com.qualcomm.robotcore.eventloop.opmode.TeleOp; import com.qualcomm.robotcore.eventloop.opmode.TeleOp;
import com.qualcomm.robotcore.hardware.DcMotorEx; import com.qualcomm.robotcore.hardware.DcMotorEx;
import org.firstinspires.ftc.teamcode.utils.Flywheel;
import org.firstinspires.ftc.teamcode.utils.Robot; import org.firstinspires.ftc.teamcode.utils.Robot;
import org.firstinspires.ftc.teamcode.utils.Spindexer;
@Config @Config
@TeleOp @TeleOp
public class ShooterTest extends LinearOpMode { public class ShooterTest extends LinearOpMode {
public static int mode = 1;
public static int mode = 0;
public static double parameter = 0.0; public static double parameter = 0.0;
// --- CONSTANTS YOU TUNE --- // --- CONSTANTS YOU TUNE ---
public static double MAX_RPM = 4500; // your measured max RPM
public static double kP = 0.001; // small proportional gain (tune this)
public static double maxStep = 0.06; // prevents sudden jumps
//TODO: @Daniel FIX THE BELOW CONSTANTS A LITTLE IF NEEDED //TODO: @Daniel FIX THE BELOW CONSTANTS A LITTLE IF NEEDED
public static double transferPower = 0.0; public static double Velocity = 0.0;
public static double P = 255.0;
public static double I = 0.0;
public static double D = 0.0;
public static double F = 7.5;
public static double transferPower = 1.0;
public static double hoodPos = 0.501; public static double hoodPos = 0.501;
public static double turretPos = 0.501; public static double turretPos = 0.501;
public static boolean shoot = false;
public static boolean intake = false;
Robot robot; Robot robot;
private double lastEncoderRevolutions = 0.0; Flywheel flywheel;
private double lastTimeStamp = 0.0;
double shootStamp = 0.0;
boolean shootAll = false;
public double spinPow = 0.09;
public static boolean enableHoodAutoOpen = false;
public double hoodAdjust = 0.0;
public static double hoodAdjustFactor = 1.0;
Spindexer spindexer ;
@Override @Override
public void runOpMode() throws InterruptedException { public void runOpMode() throws InterruptedException {
@@ -35,7 +53,8 @@ public class ShooterTest extends LinearOpMode {
robot = new Robot(hardwareMap); robot = new Robot(hardwareMap);
DcMotorEx leftShooter = robot.shooter1; DcMotorEx leftShooter = robot.shooter1;
DcMotorEx rightShooter = robot.shooter2; DcMotorEx rightShooter = robot.shooter2;
DcMotorEx encoder = robot.shooter1; flywheel = new Flywheel(hardwareMap);
spindexer = new Spindexer(hardwareMap);
MultipleTelemetry TELE = new MultipleTelemetry( MultipleTelemetry TELE = new MultipleTelemetry(
telemetry, FtcDashboard.getInstance().getTelemetry() telemetry, FtcDashboard.getInstance().getTelemetry()
@@ -47,60 +66,75 @@ public class ShooterTest extends LinearOpMode {
while (opModeIsActive()) { while (opModeIsActive()) {
double kF = 1.0 / MAX_RPM; // baseline feedforward
double encoderRevolutions = (double) encoder.getCurrentPosition() / 2048;
double velocity = -60 * (encoderRevolutions - lastEncoderRevolutions) / (getRuntime() - lastTimeStamp);
TELE.addLine("Mode: 0 = Manual, 1 = Vel, 2 = Pos");
TELE.addLine("Parameter = pow, vel, or pos");
TELE.addData("leftShooterPower", leftShooter.getPower());
TELE.addData("rightShooterPower", rightShooter.getPower());
TELE.addData("shaftEncoderPos", encoderRevolutions);
TELE.addData("shaftEncoderVel", velocity);
double velPID;
if (mode == 0) { if (mode == 0) {
rightShooter.setPower(parameter); rightShooter.setPower(parameter);
leftShooter.setPower(parameter); leftShooter.setPower(parameter);
} else if (mode == 1) { } else if (mode == 1) {
flywheel.setPIDF(P, I, D, F);
// --- FEEDFORWARD BASE POWER --- flywheel.manageFlywheel((int) Velocity);
double feed = kF * parameter; // Example: vel=2500 → feed=0.5
// --- PROPORTIONAL CORRECTION ---
double error = parameter - velocity;
double correction = kP * error;
// limit how fast power changes (prevents oscillation)
correction = Math.max(-maxStep, Math.min(maxStep, correction));
// --- FINAL MOTOR POWER ---
velPID = feed + correction;
// clamp to allowed range
velPID = Math.max(0, Math.min(1, velPID));
rightShooter.setPower(velPID);
leftShooter.setPower(velPID);
} }
lastTimeStamp = getRuntime();
lastEncoderRevolutions = (double) encoder.getCurrentPosition() / 2048;
if (hoodPos != 0.501) { if (hoodPos != 0.501) {
robot.hood.setPosition(hoodPos); if (enableHoodAutoOpen) {
robot.hood.setPosition(hoodPos+(hoodAdjustFactor*(flywheel.getVelo()/Velocity)));
} else {
robot.hood.setPosition(hoodPos);
}
} }
if (turretPos!=0.501){ if (intake) {
robot.turr1.setPosition(turretPos); robot.intake.setPower(1);
robot.turr2.setPosition(turretPos);
} else {
robot.intake.setPower(0);
} }
robot.transfer.setPower(transferPower);
if (shoot) {
shootStamp = getRuntime();
shootAll = true;
shoot = false;
robot.transfer.setPower(transferPower);
}
if (shootAll) {
//intake = false;
//reject = false;
// TODO: Change starting position based on desired order to shoot green ball
//spindexPos = spindexer_intakePos1;
if (getRuntime() - shootStamp < 3.5) {
robot.transferServo.setPosition(transferServo_in);
robot.spin1.setPower(-spinPow);
robot.spin2.setPower(spinPow);
} else {
robot.transferServo.setPosition(transferServo_out);
//spindexPos = spindexer_intakePos1;
shootAll = false;
robot.transferServo.setPosition(transferServo_out);
robot.transfer.setPower(0);
robot.spin1.setPower(0);
robot.spin2.setPower(0);
spindexer.resetSpindexer();
spindexer.processIntake();
}
} else {
spindexer.processIntake();
}
TELE.addData("Velocity", flywheel.getVelo());
TELE.addData("Velocity 1", flywheel.getVelo1());
TELE.addData("Velocity 2", flywheel.getVelo2());
TELE.addData("Power", robot.shooter1.getPower());
TELE.addData("Steady?", flywheel.getSteady());
TELE.addData("Position", robot.shooter1.getCurrentPosition());
TELE.update(); TELE.update();

50
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/tests/TurretTest.java Normal file
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@@ -0,0 +1,50 @@
package org.firstinspires.ftc.teamcode.tests;
import com.acmerobotics.dashboard.FtcDashboard;
import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
import com.acmerobotics.roadrunner.Pose2d;
import com.qualcomm.robotcore.eventloop.opmode.Autonomous;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import org.firstinspires.ftc.teamcode.libs.RR.MecanumDrive;
import org.firstinspires.ftc.teamcode.utils.Robot;
import org.firstinspires.ftc.teamcode.utils.Turret;
@Autonomous
@Config
public class TurretTest extends LinearOpMode {
public static boolean zeroTurr = false;
@Override
public void runOpMode() throws InterruptedException {
Robot robot = new Robot(hardwareMap);
MultipleTelemetry TELE = new MultipleTelemetry(
telemetry, FtcDashboard.getInstance().getTelemetry()
);
Turret turret = new Turret(robot, TELE, robot.limelight);
waitForStart();
MecanumDrive drive = new MecanumDrive(hardwareMap, new Pose2d(15, 0,0));
while(opModeIsActive()){
drive.updatePoseEstimate();
turret.trackGoal(drive.localizer.getPose());
TELE.addData("tpos", turret.getTurrPos());
TELE.addData("Limelight tx", turret.getBearing());
TELE.addData("Limelight ty", turret.getTy());
TELE.addData("Limelight X", turret.getLimelightX());
TELE.addData("Limelight Y", turret.getLimelightY());
if(zeroTurr){
turret.zeroTurretEncoder();
}
TELE.update();
}
}
}

103
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/utils/Flywheel.java
View File

@@ -1,92 +1,81 @@
package org.firstinspires.ftc.teamcode.utils; package org.firstinspires.ftc.teamcode.utils;
import static org.firstinspires.ftc.teamcode.constants.ShooterVars.kP; import com.qualcomm.robotcore.hardware.DcMotor;
import static org.firstinspires.ftc.teamcode.constants.ShooterVars.maxStep; import com.qualcomm.robotcore.hardware.HardwareMap;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry; import com.qualcomm.robotcore.hardware.PIDFCoefficients;
public class Flywheel { public class Flywheel {
Robot robot; Robot robot;
public PIDFCoefficients shooterPIDF1, shooterPIDF2;
MultipleTelemetry TELE;
double initPos = 0.0;
double stamp = 0.0;
double stamp1 = 0.0;
double ticker = 0.0;
double stamp2 = 0.0;
double currentPos = 0.0;
boolean prevSteady = false;
double velo = 0.0; double velo = 0.0;
double prevVelo = 0.0; public double velo1 = 0.0;
public double velo2 = 0.0;
double targetVelocity = 0.0; double targetVelocity = 0.0;
double powPID = 0.0; double powPID = 0.0;
boolean steady = false; boolean steady = false;
public Flywheel (HardwareMap hardwareMap) {
public Flywheel () { robot = new Robot(hardwareMap);
//robot = new Robot(hardwareMap); shooterPIDF1 = new PIDFCoefficients
(robot.shooterPIDF_P, robot.shooterPIDF_I, robot.shooterPIDF_D, robot.shooterPIDF_F);
shooterPIDF2 = new PIDFCoefficients
(robot.shooterPIDF_P, robot.shooterPIDF_I, robot.shooterPIDF_D, robot.shooterPIDF_F);
} }
public double getVelo () { public double getVelo () {
return velo; return velo;
} }
public double getVelo1 () {
return velo1;
}
public double getVelo2 () {
return velo2;
}
public boolean getSteady() { public boolean getSteady() {
return steady; return steady;
} }
private double getTimeSeconds () // Set the robot PIDF for the next cycle.
{ public void setPIDF(double p, double i, double d, double f) {
return (double) System.currentTimeMillis()/1000.0; shooterPIDF1.p = p;
shooterPIDF1.i = i;
shooterPIDF1.d = d;
shooterPIDF1.f = f;
shooterPIDF2.p = p;
shooterPIDF2.i = i;
shooterPIDF2.d = d;
shooterPIDF2.f = f;
} }
// Convert from RPM to Ticks per Second
private double RPM_to_TPS (double RPM) { return (RPM*28.0)/60.0;}
public double manageFlywheel(int commandedVelocity, double shooter1CurPos) { // Convert from Ticks per Second to RPM
targetVelocity = (double) commandedVelocity; private double TPS_to_RPM (double TPS) { return (TPS*60.0)/28.0;}
ticker++; public double manageFlywheel(double commandedVelocity) {
if (ticker % 8 == 0) { targetVelocity = commandedVelocity;
currentPos = shooter1CurPos / 2048;
stamp = getTimeSeconds(); //getRuntime();
velo = -60 * ((currentPos - initPos) / (stamp - stamp1));
initPos = currentPos;
stamp1 = stamp;
}
// Flywheel control code here
if (targetVelocity - velo > 500) {
powPID = 1.0;
} else if (velo - targetVelocity > 500){
powPID = 0.0;
} else {
double feed = Math.log((668.39 / (targetVelocity + 591.96)) - 0.116) / -4.18;
// --- PROPORTIONAL CORRECTION --- // Add code here to set PIDF based on desired RPM
double error = targetVelocity - velo;
double correction = kP * error;
// limit how fast power changes (prevents oscillation) robot.shooter1.setPIDFCoefficients(DcMotor.RunMode.RUN_USING_ENCODER, shooterPIDF1);
correction = Math.max(-maxStep, Math.min(maxStep, correction)); robot.shooter2.setPIDFCoefficients(DcMotor.RunMode.RUN_USING_ENCODER, shooterPIDF2);
robot.shooter1.setVelocity(RPM_to_TPS(targetVelocity));
robot.shooter2.setVelocity(RPM_to_TPS(targetVelocity));
// --- FINAL MOTOR POWER --- // Record Current Velocity
powPID = feed + correction; velo1 = TPS_to_RPM(robot.shooter1.getVelocity());
velo2 = TPS_to_RPM(robot.shooter2.getVelocity());
// clamp to allowed range velo = Math.max(velo1,velo2);
powPID = Math.max(0, Math.min(1, powPID));
}
// really should be a running average of the last 5 // really should be a running average of the last 5
if ((Math.abs(targetVelocity - velo) < 150.0) && (Math.abs(targetVelocity - prevVelo) < 150.0)) steady = (Math.abs(targetVelocity - velo) < 200.0);
{
steady = true;
}
else
{
steady = false;
}
return powPID; return powPID;
} }
public void update() public void update()
{ {
}; }
}; }

110
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/utils/FlywheelV2.java Normal file
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@@ -0,0 +1,110 @@
package org.firstinspires.ftc.teamcode.utils;
import com.acmerobotics.dashboard.config.Config;
@Config
public class FlywheelV2 {
public static double kP = 0.001; // small proportional gain (tune this)
public static double maxStep = 0.06; // prevents sudden jumps
double initPos1 = 0.0;
double initPos2 = 0.0;
double stamp = 0.0;
double stamp1 = 0.0;
double ticker = 0.0;
double currentPos1 = 0.0;
double currentPos2 = 0.0;
double velo = 0.0;
double velo1 = 0.0;
double velo1a = 0.0;
double velo1b = 0.0;
double velo2 = 0.0;
double velo3 = 0.0;
double velo4 = 0.0;
double velo5 = 0.0;
double targetVelocity = 0.0;
double powPID = 0.0;
boolean steady = false;
public FlywheelV2() {
//robot = new Robot(hardwareMap);
}
public double getVelo(double shooter1CurPos, double shooter2CurPos) {
ticker++;
if (ticker % 2 == 0) {
velo5 = velo4;
velo4 = velo3;
velo3 = velo2;
velo2 = velo1;
currentPos1 = shooter1CurPos / 28;
currentPos2 = shooter2CurPos / 28;
stamp = getTimeSeconds(); //getRuntime();
velo1a = 60 * ((currentPos1 - initPos1) / (stamp - stamp1));
velo1b = 60 * ((currentPos2 - initPos2) / (stamp - stamp1));
initPos1 = currentPos1;
initPos2 = currentPos2;
stamp1 = stamp;
if (velo1a < 200){
velo1 = velo1b;
} else if (velo1b < 200){
velo1 = velo1a;
} else {
velo1 = (velo1a + velo1b) / 2;
}
}
return ((velo1 + velo2 + velo3 + velo4 + velo5) / 5);
}
public double getVelo1() { return (velo1a + velo2 + velo3 + velo4 + velo5) / 5; }
public double getVelo2() { return (velo1b + velo2 + velo3 + velo4 + velo5) / 5; }
public boolean getSteady() {
return steady;
}
private double getTimeSeconds() {
return (double) System.currentTimeMillis() / 1000.0;
}
public double manageFlywheel(int commandedVelocity, double shooter1CurPos, double shooter2CurPos) {
targetVelocity = commandedVelocity;
velo = getVelo(shooter1CurPos, shooter2CurPos);
// Flywheel PID code here
if (targetVelocity - velo > 4500) {
powPID = 1.0;
} else if (velo - targetVelocity > 4500) {
powPID = 0.0;
} else {
double a = 2539.07863;
double c = 1967.6498;
double d = -0.289647;
double h = -1.1569;
double feed = Math.log10((a / (targetVelocity + c)) + d) / h;
// --- PROPORTIONAL CORRECTION ---
double error = targetVelocity - velo;
double correction = kP * error;
// limit how fast power changes (prevents oscillation)
correction = Math.max(-maxStep, Math.min(maxStep, correction));
// --- FINAL MOTOR POWER ---
powPID = feed + correction;
// clamp to allowed range
powPID = Math.max(0, Math.min(1, powPID));
}
steady = (Math.abs(targetVelocity - velo) < 100.0);
return powPID;
}
public void update() {
}
}

60
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/utils/PositionalServoProgrammer.java
View File

@@ -1,33 +1,56 @@
package org.firstinspires.ftc.teamcode.utils; package org.firstinspires.ftc.teamcode.utils;
import static org.firstinspires.ftc.teamcode.tests.PIDServoTest.*;
import com.acmerobotics.dashboard.FtcDashboard; import com.acmerobotics.dashboard.FtcDashboard;
import com.acmerobotics.dashboard.config.Config; import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry; import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode; import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import com.qualcomm.robotcore.eventloop.opmode.TeleOp; import com.qualcomm.robotcore.eventloop.opmode.TeleOp;
import org.firstinspires.ftc.vision.apriltag.AprilTagDetection;
@TeleOp @TeleOp
@Config @Config
public class PositionalServoProgrammer extends LinearOpMode { public class PositionalServoProgrammer extends LinearOpMode {
Robot robot; Robot robot;
MultipleTelemetry TELE; MultipleTelemetry TELE;
Servos servo;
public static double spindexPos = 0.501; public static double spindexPos = 0.501;
public static double spindexPow = 0.0;
public static double spinHoldPow = 0.0;
public static double turretPos = 0.501; public static double turretPos = 0.501;
public static double turretPow = 0.0;
public static double turrHoldPow = 0.0;
public static double transferPos = 0.501; public static double transferPos = 0.501;
public static double hoodPos = 0.501; public static double hoodPos = 0.501;
public static int mode = 0; //0 for positional, 1 for power
Turret turret;
public static double scalar = 1.112;
public static double restPos = 0.15;
@Override @Override
public void runOpMode() throws InterruptedException { public void runOpMode() throws InterruptedException {
robot = new Robot(hardwareMap); robot = new Robot(hardwareMap);
TELE = new MultipleTelemetry(telemetry, FtcDashboard.getInstance().getTelemetry()); TELE = new MultipleTelemetry(telemetry, FtcDashboard.getInstance().getTelemetry());
servo = new Servos(hardwareMap);
turret = new Turret(robot, TELE, robot.limelight );
waitForStart(); waitForStart();
if (isStopRequested()) return; if (isStopRequested()) return;
while (opModeIsActive()){ while (opModeIsActive()){
if (spindexPos != 0.501){ if (spindexPos != 0.501 && !servo.spinEqual(spindexPos) && mode == 0){
robot.spin1.setPosition(spindexPos); double pos = servo.setSpinPos(spindexPos);
robot.spin2.setPosition(1-spindexPos); robot.spin1.setPower(pos);
robot.spin2.setPower(-pos);
} else if (mode == 0){
robot.spin1.setPower(spinHoldPow);
robot.spin2.setPower(spinHoldPow);
} else {
robot.spin1.setPower(spindexPow);
robot.spin2.setPower(-spindexPow);
} }
if (turretPos != 0.501){ if (turretPos != 0.501){
robot.turr1.setPosition(turretPos); robot.turr1.setPosition(turretPos);
@@ -39,14 +62,25 @@ public class PositionalServoProgrammer extends LinearOpMode {
if (hoodPos != 0.501){ if (hoodPos != 0.501){
robot.hood.setPosition(hoodPos); robot.hood.setPosition(hoodPos);
} }
TELE.addData("spindexer", scalar*((robot.spin1Pos.getVoltage() - restPos) / 3.3)); // To check configuration of spindexer:
TELE.addData("hood", 1-scalar*((robot.hoodPos.getVoltage() - restPos) / 3.3)); // Set "mode" to 1 and spindexPow to 0.1
TELE.addData("transferServo", scalar*((robot.transferServoPos.getVoltage() - restPos) / 3.3)); // If the spindexer is turning clockwise, the servos are reversed. Swap the configuration of the two servos, DO NOT TOUCH THE ACTUAL CODE
TELE.addData("turret", scalar*((robot.turr1Pos.getVoltage() - restPos) / 3.3)); // Do the previous test again to confirm
TELE.addData("spindexerA", robot.spin1Pos.getVoltage()); // Set "mode" to 0 but keep spindexPos at 0.501
TELE.addData("hoodA", robot.hoodPos.getVoltage()); // Manually turn the spindexer until "spindexer pos" is set close to 0
TELE.addData("transferServoA", robot.transferServoPos.getVoltage()); // Check each spindexer voltage:
TELE.addData("turretA", robot.turr1Pos.getVoltage()); // If "spindexer voltage 1" is closer to 0 than "spindexer voltage 2," then you are done!
// If "spindexer voltage 2" is closer to 0 than "spindexer voltage 1," swap the two spindexer analog inputs in the configuration, DO NOT TOUCH THE ACTUAL CODE
//TODO: @KeshavAnandCode do the above please
TELE.addData("spindexer pos", servo.getSpinPos());
TELE.addData("turret pos", robot.turr1.getPosition());
TELE.addData("spindexer voltage 1", robot.spin1Pos.getVoltage());
TELE.addData("spindexer voltage 2", robot.spin2Pos.getVoltage());
TELE.addData("hood pos", robot.hood.getPosition());
TELE.addData("transferServo voltage", robot.transferServoPos.getVoltage());
TELE.addData("spindexer pow", robot.spin1.getPower());
TELE.addData("tpos ", turret.getTurrPos() );
TELE.update(); TELE.update();
} }
} }

113
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/utils/Robot.java
View File

@@ -1,89 +1,62 @@
package org.firstinspires.ftc.teamcode.utils; package org.firstinspires.ftc.teamcode.utils;
import com.acmerobotics.dashboard.config.Config;
import com.qualcomm.hardware.limelightvision.Limelight3A;
import com.qualcomm.hardware.rev.RevColorSensorV3; import com.qualcomm.hardware.rev.RevColorSensorV3;
import com.qualcomm.robotcore.hardware.AnalogInput; import com.qualcomm.robotcore.hardware.AnalogInput;
import com.qualcomm.robotcore.hardware.CRServo;
import com.qualcomm.robotcore.hardware.DcMotor; import com.qualcomm.robotcore.hardware.DcMotor;
import com.qualcomm.robotcore.hardware.DcMotorEx; import com.qualcomm.robotcore.hardware.DcMotorEx;
import com.qualcomm.robotcore.hardware.DcMotorSimple; import com.qualcomm.robotcore.hardware.DcMotorSimple;
import com.qualcomm.robotcore.hardware.DigitalChannel;
import com.qualcomm.robotcore.hardware.HardwareMap; import com.qualcomm.robotcore.hardware.HardwareMap;
import com.qualcomm.robotcore.hardware.PIDFCoefficients;
import com.qualcomm.robotcore.hardware.Servo; import com.qualcomm.robotcore.hardware.Servo;
import org.firstinspires.ftc.robotcore.external.hardware.camera.WebcamName; import org.firstinspires.ftc.robotcore.external.hardware.camera.WebcamName;
import org.firstinspires.ftc.vision.apriltag.AprilTagProcessor; import org.firstinspires.ftc.vision.apriltag.AprilTagProcessor;
@Config
public class Robot { public class Robot {
//Initialize Public Components //Initialize Public Components
public static boolean usingLimelight = true;
public static boolean usingCamera = false;
public DcMotorEx frontLeft; public DcMotorEx frontLeft;
public DcMotorEx frontRight; public DcMotorEx frontRight;
public DcMotorEx backLeft; public DcMotorEx backLeft;
public DcMotorEx backRight; public DcMotorEx backRight;
public DcMotorEx intake; public DcMotorEx intake;
public DcMotorEx transfer; public DcMotorEx transfer;
public PIDFCoefficients shooterPIDF;
public double shooterPIDF_P = 255.0;
public double shooterPIDF_I = 0.0;
public double shooterPIDF_D = 0.0;
public double shooterPIDF_F = 7.5;
public double[] shooterPIDF_StepSizes = {10.0, 1.0, 0.001, 0.0001};
public DcMotorEx shooter1; public DcMotorEx shooter1;
public DcMotorEx shooter2; public DcMotorEx shooter2;
public Servo hood; public Servo hood;
public Servo transferServo; public Servo transferServo;
public Servo rejecter;
public Servo turr1; public Servo turr1;
public Servo turr2; public Servo turr2;
public CRServo spin1;
public Servo spin1; public CRServo spin2;
public Servo spin2;
public DigitalChannel pin0;
public DigitalChannel pin1;
public DigitalChannel pin2;
public DigitalChannel pin3;
public DigitalChannel pin4;
public DigitalChannel pin5;
public AnalogInput analogInput;
public AnalogInput analogInput2;
public AnalogInput spin1Pos; public AnalogInput spin1Pos;
public AnalogInput spin2Pos; public AnalogInput spin2Pos;
public AnalogInput hoodPos;
public AnalogInput turr1Pos; public AnalogInput turr1Pos;
public AnalogInput turr2Pos;
public AnalogInput transferServoPos; public AnalogInput transferServoPos;
public AprilTagProcessor aprilTagProcessor; public AprilTagProcessor aprilTagProcessor;
public WebcamName webcam; public WebcamName webcam;
public DcMotorEx shooterEncoder;
public RevColorSensorV3 color1; public RevColorSensorV3 color1;
public RevColorSensorV3 color2; public RevColorSensorV3 color2;
public RevColorSensorV3 color3; public RevColorSensorV3 color3;
public Limelight3A limelight;
public Robot(HardwareMap hardwareMap) { public Robot(HardwareMap hardwareMap) {
//Define components w/ hardware map //Define components w/ hardware map
//TODO: fix the configuration of these - I trust you to figure it out yourself @KeshavAnandCode
frontLeft = hardwareMap.get(DcMotorEx.class, "fl"); frontLeft = hardwareMap.get(DcMotorEx.class, "fl");
frontRight = hardwareMap.get(DcMotorEx.class, "fr"); frontRight = hardwareMap.get(DcMotorEx.class, "fr");
backLeft = hardwareMap.get(DcMotorEx.class, "bl"); backLeft = hardwareMap.get(DcMotorEx.class, "bl");
@@ -97,51 +70,39 @@ public class Robot {
backRight.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.FLOAT); backRight.setZeroPowerBehavior(DcMotor.ZeroPowerBehavior.FLOAT);
intake = hardwareMap.get(DcMotorEx.class, "intake"); intake = hardwareMap.get(DcMotorEx.class, "intake");
rejecter = hardwareMap.get(Servo.class, "rejecter");
shooter1 = hardwareMap.get(DcMotorEx.class, "shooter1"); shooter1 = hardwareMap.get(DcMotorEx.class, "shooter1");
shooter2 = hardwareMap.get(DcMotorEx.class, "shooter2"); shooter2 = hardwareMap.get(DcMotorEx.class, "shooter2");
//TODO: figure out which shooter motor is reversed using ShooterTest and change it in code @KeshavAnandCode
shooter1.setDirection(DcMotorSimple.Direction.REVERSE); shooter1.setDirection(DcMotorSimple.Direction.REVERSE);
shooterPIDF = new PIDFCoefficients(shooterPIDF_P, shooterPIDF_I, shooterPIDF_D, shooterPIDF_F);
shooterEncoder = shooter1; shooter1.setMode(DcMotor.RunMode.RUN_USING_ENCODER);
shooter1.setPIDFCoefficients(DcMotor.RunMode.RUN_USING_ENCODER, shooterPIDF);
shooter1.setVelocity(0);
shooter2.setMode(DcMotor.RunMode.RUN_USING_ENCODER);
shooter2.setPIDFCoefficients(DcMotor.RunMode.RUN_USING_ENCODER, shooterPIDF);
shooter2.setVelocity(0);
hood = hardwareMap.get(Servo.class, "hood"); hood = hardwareMap.get(Servo.class, "hood");
hoodPos = hardwareMap.get(AnalogInput.class, "hoodPos");
turr1 = hardwareMap.get(Servo.class, "t1"); turr1 = hardwareMap.get(Servo.class, "t1");
turr1Pos = hardwareMap.get(AnalogInput.class, "t1Pos");
turr2 = hardwareMap.get(Servo.class, "t2"); turr2 = hardwareMap.get(Servo.class, "t2");
turr2Pos = hardwareMap.get(AnalogInput.class, "t2Pos"); turr1Pos = hardwareMap.get(AnalogInput.class, "t1Pos"); // Encoder of turret plugged in intake port
spin1 = hardwareMap.get(Servo.class, "spin1"); //TODO: check spindexer configuration (both servo and analog input) - check comments in PositionalServoProgrammer
spin1 = hardwareMap.get(CRServo.class, "spin1");
spin1Pos = hardwareMap.get(AnalogInput.class, "spin1Pos"); spin1Pos = hardwareMap.get(AnalogInput.class, "spin1Pos");
spin2 = hardwareMap.get(Servo.class, "spin2"); spin2 = hardwareMap.get(CRServo.class, "spin2");
spin2Pos = hardwareMap.get(AnalogInput.class, "spin2Pos"); spin2Pos = hardwareMap.get(AnalogInput.class, "spin2Pos");
pin0 = hardwareMap.get(DigitalChannel.class, "pin0"); spin1.setDirection(DcMotorSimple.Direction.REVERSE);
spin2.setDirection(DcMotorSimple.Direction.REVERSE);
pin1 = hardwareMap.get(DigitalChannel.class, "pin1");
pin2 = hardwareMap.get(DigitalChannel.class, "pin2");
pin3 = hardwareMap.get(DigitalChannel.class, "pin3");
pin4 = hardwareMap.get(DigitalChannel.class, "pin4");
pin5 = hardwareMap.get(DigitalChannel.class, "pin5");
analogInput = hardwareMap.get(AnalogInput.class, "analog");
analogInput2 = hardwareMap.get(AnalogInput.class, "analog2");
transfer = hardwareMap.get(DcMotorEx.class, "transfer"); transfer = hardwareMap.get(DcMotorEx.class, "transfer");
@@ -150,15 +111,19 @@ public class Robot {
transferServoPos = hardwareMap.get(AnalogInput.class, "tSPos"); transferServoPos = hardwareMap.get(AnalogInput.class, "tSPos");
transfer.setDirection(DcMotorSimple.Direction.REVERSE); transfer.setDirection(DcMotorSimple.Direction.REVERSE);
transfer.setMode(DcMotor.RunMode.RUN_WITHOUT_ENCODER);
aprilTagProcessor = AprilTagProcessor.easyCreateWithDefaults();
webcam = hardwareMap.get(WebcamName.class, "Webcam 1");
color1 = hardwareMap.get(RevColorSensorV3.class, "c1"); color1 = hardwareMap.get(RevColorSensorV3.class, "c1");
color2 = hardwareMap.get(RevColorSensorV3.class, "c2"); color2 = hardwareMap.get(RevColorSensorV3.class, "c2");
color3 = hardwareMap.get(RevColorSensorV3.class, "c3"); color3 = hardwareMap.get(RevColorSensorV3.class, "c3");
if (usingLimelight) {
limelight = hardwareMap.get(Limelight3A.class, "limelight");
} else if (usingCamera) {
webcam = hardwareMap.get(WebcamName.class, "Webcam 1");
aprilTagProcessor = AprilTagProcessor.easyCreateWithDefaults();
}
} }
} }

58
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/utils/Servos.java Normal file
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@@ -0,0 +1,58 @@
package org.firstinspires.ftc.teamcode.utils;
import com.acmerobotics.dashboard.config.Config;
import com.arcrobotics.ftclib.controller.PIDFController;
import com.qualcomm.robotcore.hardware.HardwareMap;
@Config
public class Servos {
//PID constants
// TODO: get PIDF constants
public static double spinP = 2.0, spinI = 0, spinD = 0.3, spinF = 0.02;
public static double turrP = 1.1, turrI = 0.25, turrD = 0.0625, turrF = 0;
public static double spin_scalar = 1.0086;
public static double spin_restPos = 0.0;
public static double turret_scalar = 1.009;
public static double turret_restPos = 0.0;
Robot robot;
PIDFController spinPID;
PIDFController turretPID;
public Servos(HardwareMap hardwareMap) {
robot = new Robot(hardwareMap);
spinPID = new PIDFController(spinP, spinI, spinD, spinF);
turretPID = new PIDFController(turrP, turrI, turrD, turrF);
turretPID.setTolerance(0.001);
}
// In the code below, encoder = robot.servo.getVoltage()
public double getSpinPos() {
return spin_scalar * ((robot.spin1Pos.getVoltage() - spin_restPos) / 3.3);
}
//TODO: PID warp so 0 and 1 are usable positions
public double setSpinPos(double pos) {
spinPID.setPIDF(spinP, spinI, spinD, spinF);
return spinPID.calculate(this.getSpinPos(), pos);
}
public boolean spinEqual(double pos) {
return Math.abs(pos - this.getSpinPos()) < 0.03;
}
public double getTurrPos() {
return 1.0;
}
public double setTurrPos(double pos) {
return 1.0;
}
public boolean turretEqual(double pos) {
return true;
}
}

492
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/utils/Spindexer.java Normal file
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@@ -0,0 +1,492 @@
package org.firstinspires.ftc.teamcode.utils;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
import com.arcrobotics.ftclib.controller.PIDFController;
import com.qualcomm.robotcore.hardware.HardwareMap;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_intakePos1;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_intakePos2;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_intakePos3;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_outtakeBall1;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_outtakeBall2;
import static org.firstinspires.ftc.teamcode.constants.ServoPositions.spindexer_outtakeBall3;
import static org.firstinspires.ftc.teamcode.utils.Servos.spinD;
import static org.firstinspires.ftc.teamcode.utils.Servos.spinF;
import static org.firstinspires.ftc.teamcode.utils.Servos.spinI;
import static org.firstinspires.ftc.teamcode.utils.Servos.spinP;
import org.firstinspires.ftc.robotcore.external.navigation.DistanceUnit;
import org.firstinspires.ftc.teamcode.constants.Types;
import org.firstinspires.ftc.teamcode.libs.RR.MecanumDrive;
public class Spindexer {
Robot robot;
Servos servos;
Flywheel flywheel;
MecanumDrive drive;
double lastKnownSpinPos = 0.0;
MultipleTelemetry TELE;
PIDFController spinPID = new PIDFController(spinP, spinI, spinD, spinF);
double spinCurrentPos = 0.0;
public int commandedIntakePosition = 0;
public double distanceRearCenter = 0.0;
public double distanceFrontDriver = 0.0;
public double distanceFrontPassenger = 0.0;
public Types.Motif desiredMotif = Types.Motif.NONE;
// For Use
enum RotatedBallPositionNames {
REARCENTER,
FRONTDRIVER,
FRONTPASSENGER
}
// Array of commandedIntakePositions with contents
// {RearCenter, FrontDriver, FrontPassenger}
static final int[][] RotatedBallPositions = {{0,2,1}, {1,0,2}, {2,1,0}};
class spindexerBallRoatation {
int rearCenter = 0; // aka commanded Position
int frontDriver = 0;
int frontPassenger = 0;
}
enum IntakeState {
UNKNOWN_START,
UNKNOWN_MOVE,
UNKNOWN_DETECT,
INTAKE,
FINDNEXT,
MOVING,
FULL,
SHOOTNEXT,
SHOOTMOVING,
SHOOTWAIT,
SHOOT_ALL_PREP,
SHOOT_ALL_READY
};
public IntakeState currentIntakeState = IntakeState.UNKNOWN_START;
public int unknownColorDetect = 0;
enum BallColor {
UNKNOWN,
GREEN,
PURPLE
};
class BallPosition {
boolean isEmpty = true;
int foundEmpty = 0;
BallColor ballColor = BallColor.UNKNOWN;
}
BallPosition[] ballPositions = new BallPosition[3];
public boolean init () {
return true;
}
public Spindexer(HardwareMap hardwareMap) {
robot = new Robot(hardwareMap);
servos = new Servos(hardwareMap);
flywheel = new Flywheel(hardwareMap);
//TELE = new MultipleTelemetry(telemetry, FtcDashboard.getInstance().getTelemetry());
lastKnownSpinPos = servos.getSpinPos();
ballPositions[0] = new BallPosition();
ballPositions[1] = new BallPosition();
ballPositions[2] = new BallPosition();
}
double[] outakePositions =
{spindexer_outtakeBall1, spindexer_outtakeBall2, spindexer_outtakeBall3};
double[] intakePositions =
{spindexer_intakePos1, spindexer_intakePos2, spindexer_intakePos3};
public int counter = 0;
// private double getTimeSeconds ()
// {
// return (double) System.currentTimeMillis()/1000.0;
// }
// public double getPos() {
// robot.spin1Pos.getVoltage();
// robot.spin1Pos.getMaxVoltage();
// return (robot.spin1Pos.getVoltage()/robot.spin1Pos.getMaxVoltage());
// }
// public void manageSpindexer() {
//
// }
public void resetBallPosition (int pos) {
ballPositions[pos].isEmpty = true;
ballPositions[pos].foundEmpty = 0;
ballPositions[pos].ballColor = BallColor.UNKNOWN;
}
public void resetSpindexer () {
for (int i = 0; i < 3; i++) {
resetBallPosition(i);
}
currentIntakeState = IntakeState.UNKNOWN_START;
}
// Detects if a ball is found and what color.
// Returns true is there was a new ball found in Position 1
// FIXIT: Reduce number of times that we read the color sensors for loop times.
public boolean detectBalls(boolean detectRearColor, boolean detectFrontColor) {
boolean newPos1Detection = false;
int spindexerBallPos = 0;
// Read Distances
distanceRearCenter = robot.color1.getDistance(DistanceUnit.MM);
distanceFrontDriver = robot.color2.getDistance(DistanceUnit.MM);
distanceFrontPassenger = robot.color3.getDistance(DistanceUnit.MM);
// Position 1
if (distanceRearCenter < 43) {
// Mark Ball Found
newPos1Detection = true;
if (detectRearColor) {
// Detect which color
double green = robot.color1.getNormalizedColors().green;
double red = robot.color1.getNormalizedColors().red;
double blue = robot.color1.getNormalizedColors().blue;
double gP = green / (green + red + blue);
// FIXIT - Add filtering to improve accuracy.
if (gP >= 0.4) {
ballPositions[commandedIntakePosition].ballColor = BallColor.PURPLE; // purple
} else {
ballPositions[commandedIntakePosition].ballColor = BallColor.GREEN; // purple
}
}
}
// Position 2
// Find which ball position this is in the spindexer
spindexerBallPos = RotatedBallPositions[commandedIntakePosition][RotatedBallPositionNames.FRONTDRIVER.ordinal()];
if (distanceFrontDriver < 60) {
// reset FoundEmpty because looking for 3 in a row before reset
ballPositions[spindexerBallPos].foundEmpty = 0;
if (detectFrontColor) {
double green = robot.color2.getNormalizedColors().green;
double red = robot.color2.getNormalizedColors().red;
double blue = robot.color2.getNormalizedColors().blue;
double gP = green / (green + red + blue);
if (gP >= 0.4) {
ballPositions[spindexerBallPos].ballColor = BallColor.PURPLE; // purple
} else {
ballPositions[spindexerBallPos].ballColor = BallColor.GREEN; // purple
}
}
} else {
if (!ballPositions[spindexerBallPos].isEmpty) {
if (ballPositions[spindexerBallPos].foundEmpty > 3) {
resetBallPosition(spindexerBallPos);
}
ballPositions[spindexerBallPos].foundEmpty++;
}
}
// Position 3
spindexerBallPos = RotatedBallPositions[commandedIntakePosition][RotatedBallPositionNames.FRONTPASSENGER.ordinal()];
if (distanceFrontPassenger < 33) {
// reset FoundEmpty because looking for 3 in a row before reset
ballPositions[spindexerBallPos].foundEmpty = 0;
if (detectFrontColor) {
double green = robot.color3.getNormalizedColors().green;
double red = robot.color3.getNormalizedColors().red;
double blue = robot.color3.getNormalizedColors().blue;
double gP = green / (green + red + blue);
if (gP >= 0.4) {
ballPositions[spindexerBallPos].ballColor = BallColor.PURPLE; // purple
} else {
ballPositions[spindexerBallPos].ballColor = BallColor.GREEN; // purple
}
}
} else {
if (!ballPositions[spindexerBallPos].isEmpty) {
if (ballPositions[spindexerBallPos].foundEmpty > 3) {
resetBallPosition(spindexerBallPos);
}
ballPositions[spindexerBallPos].foundEmpty++;
}
}
// TELE.addData("Velocity", velo);
// TELE.addLine("Detecting");
// TELE.addData("Distance 1", s1D);
// TELE.addData("Distance 2", s2D);
// TELE.addData("Distance 3", s3D);
// TELE.addData("B1", b1);
// TELE.addData("B2", b2);
// TELE.addData("B3", b3);
// TELE.update();
return newPos1Detection;
}
public void moveSpindexerToPos(double pos) {
spinCurrentPos = servos.getSpinPos();
double spindexPID = spinPID.calculate(spinCurrentPos, pos);
robot.spin1.setPower(spindexPID);
robot.spin2.setPower(-spindexPID);
}
public void stopSpindexer() {
robot.spin1.setPower(0);
robot.spin2.setPower(0);
}
public boolean isFull () {
return (!ballPositions[0].isEmpty && !ballPositions[1].isEmpty && !ballPositions[2].isEmpty);
}
public boolean processIntake() {
switch (currentIntakeState) {
case UNKNOWN_START:
// For now just set position ONE if UNKNOWN
commandedIntakePosition = 0;
servos.setSpinPos(intakePositions[0]);
currentIntakeState = Spindexer.IntakeState.UNKNOWN_MOVE;
break;
case UNKNOWN_MOVE:
// Stopping when we get to the new position
if (servos.spinEqual(intakePositions[commandedIntakePosition])) {
currentIntakeState = Spindexer.IntakeState.UNKNOWN_DETECT;
stopSpindexer();
unknownColorDetect = 0;
} else {
// Keep moving the spindexer
moveSpindexerToPos(intakePositions[commandedIntakePosition]);
}
break;
case UNKNOWN_DETECT:
if (unknownColorDetect >5) {
currentIntakeState = Spindexer.IntakeState.FINDNEXT;
} else {
//detectBalls(true, true);
unknownColorDetect++;
}
break;
case INTAKE:
// Ready for intake and Detecting a New Ball
if (detectBalls(true, false)) {
ballPositions[commandedIntakePosition].isEmpty = false;
currentIntakeState = Spindexer.IntakeState.FINDNEXT;
} else {
// Maintain Position
moveSpindexerToPos(intakePositions[commandedIntakePosition]);
}
break;
case FINDNEXT:
// Find Next Open Position and start movement
double currentSpindexerPos = servos.getSpinPos();
double commandedtravelDistance = 2.0;
double proposedTravelDistance = Math.abs(intakePositions[0] - currentSpindexerPos);
if (ballPositions[0].isEmpty && (proposedTravelDistance < commandedtravelDistance)) {
// Position 1
commandedIntakePosition = 0;
servos.setSpinPos(intakePositions[commandedIntakePosition]);
currentIntakeState = Spindexer.IntakeState.MOVING;
commandedtravelDistance = proposedTravelDistance;
}
proposedTravelDistance = Math.abs(intakePositions[1] - currentSpindexerPos);
if (ballPositions[1].isEmpty && (proposedTravelDistance < commandedtravelDistance)) {
// Position 2
commandedIntakePosition = 1;
servos.setSpinPos(intakePositions[commandedIntakePosition]);
currentIntakeState = Spindexer.IntakeState.MOVING;
commandedtravelDistance = proposedTravelDistance;
}
proposedTravelDistance = Math.abs(intakePositions[2] - currentSpindexerPos);
if (ballPositions[2].isEmpty && (proposedTravelDistance < commandedtravelDistance)) {
// Position 3
commandedIntakePosition = 2;
servos.setSpinPos(intakePositions[commandedIntakePosition]);
currentIntakeState = Spindexer.IntakeState.MOVING;
commandedtravelDistance = proposedTravelDistance;
}
if (currentIntakeState != Spindexer.IntakeState.MOVING) {
// Full
commandedIntakePosition = bestFitMotif();
currentIntakeState = Spindexer.IntakeState.FULL;
}
moveSpindexerToPos(intakePositions[commandedIntakePosition]);
break;
case MOVING:
// Stopping when we get to the new position
if (servos.spinEqual(intakePositions[commandedIntakePosition])) {
currentIntakeState = Spindexer.IntakeState.INTAKE;
stopSpindexer();
//detectBalls(false, false);
} else {
// Keep moving the spindexer
moveSpindexerToPos(intakePositions[commandedIntakePosition]);
}
break;
case FULL:
// Double Check Colors
detectBalls(false, false); // Minimize hardware calls
if (ballPositions[0].isEmpty || ballPositions[1].isEmpty || ballPositions[2].isEmpty) {
// Error handling found an empty spot, get it ready for a ball
currentIntakeState = Spindexer.IntakeState.FINDNEXT;
}
// Maintain Position
moveSpindexerToPos(intakePositions[commandedIntakePosition]);
break;
case SHOOT_ALL_PREP:
// We get here with function call to prepareToShootMotif
// Stopping when we get to the new position
if (servos.spinEqual(intakePositions[commandedIntakePosition])) {
currentIntakeState = Spindexer.IntakeState.SHOOT_ALL_READY;
} else {
// Keep moving the spindexer
moveSpindexerToPos(intakePositions[commandedIntakePosition]); // Possible error: should it be using "outakePositions" instead of "intakePositions"
}
break;
case SHOOT_ALL_READY:
// Double Check Colors
//detectBalls(false, false); // Minimize hardware calls
if (ballPositions[0].isEmpty && ballPositions[1].isEmpty && ballPositions[2].isEmpty) {
// All ball shot move to intake state
currentIntakeState = Spindexer.IntakeState.FINDNEXT;
}
// Maintain Position
moveSpindexerToPos(intakePositions[commandedIntakePosition]);
break;
case SHOOTNEXT:
// Find Next Open Position and start movement
if (!ballPositions[0].isEmpty) {
// Position 1
commandedIntakePosition = 0;
servos.setSpinPos(outakePositions[commandedIntakePosition]);
currentIntakeState = Spindexer.IntakeState.SHOOTMOVING;
} else if (ballPositions[1].isEmpty) { // Possible error: should it be !ballPosition[1].isEmpty?
// Position 2
commandedIntakePosition = 1;
servos.setSpinPos(outakePositions[commandedIntakePosition]);
currentIntakeState = Spindexer.IntakeState.SHOOTMOVING;
} else if (ballPositions[2].isEmpty) { // Possible error: should it be !ballPosition[2].isEmpty?
// Position 3
commandedIntakePosition = 2;
servos.setSpinPos(intakePositions[commandedIntakePosition]); // Possible error: should it be using "outakePositions" instead of "intakePositions"
currentIntakeState = Spindexer.IntakeState.SHOOTMOVING;
} else {
// Empty return to intake state
currentIntakeState = IntakeState.FINDNEXT;
}
moveSpindexerToPos(intakePositions[commandedIntakePosition]); // Possible error: should it be using "outakePositions" instead of "intakePositions"
break;
case SHOOTMOVING:
// Stopping when we get to the new position
if (servos.spinEqual(outakePositions[commandedIntakePosition])) {
currentIntakeState = Spindexer.IntakeState.SHOOTWAIT;
} else {
// Keep moving the spindexer
moveSpindexerToPos(intakePositions[commandedIntakePosition]); // Possible error: should it be using "outakePositions" instead of "intakePositions"
}
break;
case SHOOTWAIT:
// Stopping when we get to the new position
if (servos.spinEqual(intakePositions[commandedIntakePosition])) {
currentIntakeState = Spindexer.IntakeState.INTAKE;
stopSpindexer();
//detectBalls(true, false);
} else {
// Keep moving the spindexer
moveSpindexerToPos(intakePositions[commandedIntakePosition]);
}
break;
default:
// Statements to execute if no case matches
}
//TELE.addData("commandedIntakePosition", commandedIntakePosition);
//TELE.update();
// Signal a successful intake
return false;
}
public void setDesiredMotif (Types.Motif newMotif) {
desiredMotif = newMotif;
}
// Returns the best fit for the motiff
public int bestFitMotif () {
switch (desiredMotif) {
case GPP:
if (ballPositions[0].ballColor == BallColor.GREEN) {
return 2;
} else if (ballPositions[1].ballColor == BallColor.GREEN) {
return 0;
} else {
return 1;
}
//break;
case PGP:
if (ballPositions[0].ballColor == BallColor.GREEN) {
return 0;
} else if (ballPositions[1].ballColor == BallColor.GREEN) {
return 1;
} else {
return 3;
}
//break;
case PPG:
if (ballPositions[0].ballColor == BallColor.GREEN) {
return 1;
} else if (ballPositions[1].ballColor == BallColor.GREEN) {
return 0;
} else {
return 2;
}
//break;
case NONE:
return 0;
//break;
}
return 0;
}
void prepareToShootMotif () {
commandedIntakePosition = bestFitMotif();
}
void shootAllToIntake () {
currentIntakeState = Spindexer.IntakeState.FINDNEXT;
}
public void update()
{
}
}

141
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/utils/Targeting.java Normal file
View File

@@ -0,0 +1,141 @@
package org.firstinspires.ftc.teamcode.utils;
import android.provider.Settings;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
import com.qualcomm.robotcore.hardware.DcMotor;
import com.qualcomm.robotcore.hardware.HardwareMap;
public class Targeting {
MultipleTelemetry TELE;
double cancelOffsetX = 0.0; // was -40.0
double cancelOffsetY = 0.0; // was 7.0
double unitConversionFactor = 0.95;
int tileSize = 24; //inches
public double robotInchesX, robotInchesY = 0.0;
public int robotGridX, robotGridY = 0;
public static class Settings {
public double flywheelRPM = 0.0;
public double hoodAngle = 0.0;
public Settings (double flywheelRPM, double hoodAngle) {
this.flywheelRPM = flywheelRPM;
this.hoodAngle = hoodAngle;
}
}
// Known settings discovered using shooter test.
// Keep the fidelity at 1 floor tile for now but we could also half it if more
// accuracy is needed.
public static final Settings[][] KNOWNTARGETING;
static {
KNOWNTARGETING = new Settings[6][6];
// ROW 0 - Closet to the goals
KNOWNTARGETING[0][0] = new Settings (2300.0, 0.93);
KNOWNTARGETING[0][1] = new Settings (2300.0, 0.93);
KNOWNTARGETING[0][2] = new Settings (2500.0, 0.78);
KNOWNTARGETING[0][3] = new Settings (2800.0, 0.68);
KNOWNTARGETING[0][4] = new Settings (3000.0, 0.58);
KNOWNTARGETING[0][5] = new Settings (3000.0, 0.58);
// ROW 1
KNOWNTARGETING[1][0] = new Settings (2300.0, 0.93);
KNOWNTARGETING[1][1] = new Settings (2300.0, 0.93);
KNOWNTARGETING[1][2] = new Settings (2600.0, 0.78);
KNOWNTARGETING[1][3] = new Settings (2800.0, 0.62);
KNOWNTARGETING[1][4] = new Settings (3000.0, 0.55);
KNOWNTARGETING[1][5] = new Settings (3200.0, 0.50);
// ROW 2
KNOWNTARGETING[2][0] = new Settings (2500.0, 0.78);
KNOWNTARGETING[2][1] = new Settings (2500.0, 0.78);
KNOWNTARGETING[2][2] = new Settings (2700.0, 0.60);
KNOWNTARGETING[2][3] = new Settings (2900.0, 0.53);
KNOWNTARGETING[2][4] = new Settings (3100.0, 0.50);
KNOWNTARGETING[2][5] = new Settings (3100.0, 0.50);
// ROW 3
KNOWNTARGETING[3][0] = new Settings (2900.0, 0.50);
KNOWNTARGETING[3][1] = new Settings (2900.0, 0.50);
KNOWNTARGETING[3][2] = new Settings (2900.0, 0.50);
KNOWNTARGETING[3][3] = new Settings (3100.0, 0.47);
KNOWNTARGETING[3][4] = new Settings (3100.0, 0.47);
KNOWNTARGETING[3][5] = new Settings (3100.0, 0.47);
// ROW 4
KNOWNTARGETING[4][0] = new Settings (4540.0, 0.1);
KNOWNTARGETING[4][1] = new Settings (4541.0, 0.1);
KNOWNTARGETING[4][2] = new Settings (4542.0, 0.1);
KNOWNTARGETING[4][3] = new Settings (4543.0, 0.1);
KNOWNTARGETING[4][4] = new Settings (4544.0, 0.1);
KNOWNTARGETING[4][5] = new Settings (4545.0, 0.1);
// ROW 1
KNOWNTARGETING[5][0] = new Settings (4550.0, 0.1);
KNOWNTARGETING[5][1] = new Settings (4551.0, 0.1);
KNOWNTARGETING[5][2] = new Settings (4552.0, 0.1);
KNOWNTARGETING[5][3] = new Settings (4553.0, 0.1);
KNOWNTARGETING[5][4] = new Settings (4554.0, 0.1);
KNOWNTARGETING[5][5] = new Settings (4555.0, 0.1);
}
public Targeting()
{
}
public Settings calculateSettings(double robotX, double robotY, double robotHeading, double robotVelocity, boolean interpolate) {
Settings recommendedSettings = new Settings(0.0, 0.0);
double cos45 = Math.cos(Math.toRadians(-45));
double sin45 = Math.sin(Math.toRadians(-45));
double rotatedY = (robotX + cancelOffsetX) * sin45 + (robotY + cancelOffsetY) * cos45;
double rotatedX = (robotX + cancelOffsetX) * cos45 - (robotY + cancelOffsetY) * sin45;
// Convert robot coordinates to inches
robotInchesX = rotatedX * unitConversionFactor;
robotInchesY = rotatedY * unitConversionFactor;
// Find approximate location in the grid
int gridX = Math.abs(Math.floorDiv((int) robotInchesX, tileSize) + 1);
int gridY = Math.abs(Math.floorDiv((int) robotInchesY, tileSize));
//clamp
robotGridX = Math.max(0, Math.min(gridX, KNOWNTARGETING[0].length - 1));
robotGridY = Math.max(0, Math.min(gridY, KNOWNTARGETING.length - 1));
// basic search
if(!interpolate) {
if ((robotGridY < 6) && (robotGridX <6)) {
recommendedSettings.flywheelRPM = KNOWNTARGETING[robotGridX][robotGridY].flywheelRPM;
recommendedSettings.hoodAngle = KNOWNTARGETING[robotGridX][robotGridY].hoodAngle;
}
return recommendedSettings;
} else {
// bilinear interpolation
int x0 = robotGridX;
int x1 = Math.min(x0 + 1, KNOWNTARGETING[0].length - 1);
int y0 = gridY;
int y1 = Math.min(y0 + 1, KNOWNTARGETING.length - 1);
double x = (robotInchesX - (x0 * tileSize)) / tileSize;
double y = (robotInchesY - (y0 * tileSize)) / tileSize;
double rpm00 = KNOWNTARGETING[y0][x0].flywheelRPM;
double rpm10 = KNOWNTARGETING[y0][x1].flywheelRPM;
double rpm01 = KNOWNTARGETING[y1][x0].flywheelRPM;
double rpm11 = KNOWNTARGETING[y1][x1].flywheelRPM;
double angle00 = KNOWNTARGETING[y0][x0].hoodAngle;
double angle10 = KNOWNTARGETING[y0][x1].hoodAngle;
double angle01 = KNOWNTARGETING[y1][x0].hoodAngle;
double angle11 = KNOWNTARGETING[y1][x1].hoodAngle;
recommendedSettings.flywheelRPM = (1 - x) * (1 - y) * rpm00 + x * (1 - y) * rpm10 + (1 - x) * y * rpm01 + x * y * rpm11;
recommendedSettings.hoodAngle = (1 - x) * (1 - y) * angle00 + x * (1 - y) * angle10 + (1 - x) * y * angle01 + x * y * angle11;
return recommendedSettings;
}
}
}

227
TeamCode/src/main/java/org/firstinspires/ftc/teamcode/utils/Turret.java Normal file
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@@ -0,0 +1,227 @@
package org.firstinspires.ftc.teamcode.utils;
import static org.firstinspires.ftc.teamcode.constants.Color.redAlliance;
import com.acmerobotics.dashboard.config.Config;
import com.acmerobotics.dashboard.telemetry.MultipleTelemetry;
import com.acmerobotics.roadrunner.Pose2d;
import com.arcrobotics.ftclib.controller.PIDFController;
import com.qualcomm.hardware.limelightvision.LLResult;
import com.qualcomm.hardware.limelightvision.LLResultTypes;
import com.qualcomm.hardware.limelightvision.Limelight3A;
import com.qualcomm.robotcore.hardware.DcMotor;
import org.firstinspires.ftc.robotcore.external.navigation.Pose3D;
import java.util.List;
@Config
public class Turret {
public static double turretTolerance = 0.02;
public static double turrPosScalar = 0.00011264432;
public static double turret180Range = 0.4;
public static double turrDefault = 0.4;
// TODO: tune these values for limelight
// At the top with other static variables:
public static double kP = 0.015; // Proportional gain - tune this first
public static double kI = 0.0005; // Integral gain - add slowly if needed
public static double kD = 0.002; // Derivative gain - helps prevent overshoot
public static double kF = 0.002; // Derivative gain - helps prevent overshoot
public static double maxOffset = 10; // degrees - safety limit
// Add these as instance variables:
private double lastTagBearing = 0.0;
private double offsetIntegral = 0.0;
public static double cameraBearingEqual = 1;
public static double turrMin = 0.2;
public static double turrMax = 0.8;
public static double mult = 0.0;
private boolean lockOffset = false;
Robot robot;
MultipleTelemetry TELE;
Limelight3A webcam;
private int obeliskID = 0;
private double offset = 0.0;
private PIDFController controller = new PIDFController(kP, kI, kD, kF);
double tx = 0.0;
double ty = 0.0;
double limelightPosX = 0.0;
double limelightPosY = 0.0;
public static double clampTolerance = 0.03;
public Turret(Robot rob, MultipleTelemetry tele, Limelight3A cam) {
this.TELE = tele;
this.robot = rob;
this.webcam = cam;
webcam.start();
if (redAlliance){
webcam.pipelineSwitch(3);
} else {
webcam.pipelineSwitch(2);
}
}
public void zeroTurretEncoder() {
robot.intake.setMode(DcMotor.RunMode.STOP_AND_RESET_ENCODER);
robot.intake.setMode(DcMotor.RunMode.RUN_WITHOUT_ENCODER);
}
public double getTurrPos() {
return turrPosScalar * (robot.turr1Pos.getVoltage() / 3.3) + turrDefault;
}
public void manualSetTurret(double pos){
robot.turr1.setPosition(pos);
robot.turr2.setPosition(1-pos);
}
public boolean turretEqual(double pos) {
return Math.abs(pos - this.getTurrPos()) < turretTolerance;
}
private void limelightRead(){ // only for tracking purposes, not general reads
if (redAlliance){
webcam.pipelineSwitch(3);
} else {
webcam.pipelineSwitch(2);
}
LLResult result = webcam.getLatestResult();
if (result != null) {
if (result.isValid()) {
tx = result.getTx();
ty = result.getTy();
// MegaTag1 code for receiving position
Pose3D botpose = result.getBotpose();
if (botpose != null){
limelightPosX = botpose.getPosition().x;
limelightPosY = botpose.getPosition().y;
}
}
}
}
public double getBearing() {
tx = 1000;
limelightRead();
return tx;
}
public double getTy(){
limelightRead();
return ty;
}
public double getLimelightX(){
limelightRead();
return limelightPosX;
}
public double getLimelightY(){
limelightRead();
return limelightPosY;
}
public int detectObelisk() {
webcam.pipelineSwitch(1);
LLResult result = webcam.getLatestResult();
if (result != null && result.isValid()) {
List<LLResultTypes.FiducialResult> fiducials = result.getFiducialResults();
for (LLResultTypes.FiducialResult fiducial : fiducials) {
obeliskID = fiducial.getFiducialId();
}
}
return obeliskID;
}
public int getObeliskID() {
return obeliskID;
}
public void zeroOffset() {
offset = 0.0;
}
public void lockOffset(boolean lock) {
lockOffset = lock;
}
/*
Param @deltaPos = Pose2d when subtracting robot x, y, heading from goal x, y, heading
*/
public void trackGoal(Pose2d deltaPos) {
controller.setPIDF(kP, kI, kD, kF);
/* ---------------- FIELD → TURRET GEOMETRY ---------------- */
// Angle from robot to goal in robot frame
double desiredTurretAngleDeg = Math.toDegrees(
Math.atan2(deltaPos.position.y, deltaPos.position.x)
);
// Robot heading (field → robot)
double robotHeadingDeg = Math.toDegrees(deltaPos.heading.toDouble());
// Turret angle needed relative to robot
double turretAngleDeg = desiredTurretAngleDeg - robotHeadingDeg;
turretAngleDeg = -turretAngleDeg;
// Normalize to [-180, 180]
while (turretAngleDeg > 180) turretAngleDeg -= 360;
while (turretAngleDeg < -180) turretAngleDeg += 360;
/* ---------------- APRILTAG CORRECTION ---------------- */
//
double tagBearingDeg = getBearing(); // + = target is to the left
turretAngleDeg += offset;
/* ---------------- ANGLE → SERVO ---------------- */
double turretPos = turrDefault + (turretAngleDeg * (turret180Range * 2.0) / 360);
// Clamp to servo range
double currentEncoderPos = this.getTurrPos();
if (!turretEqual(turretPos)) {
double diff = turretPos - currentEncoderPos;
turretPos = turretPos + diff * mult;
}
if (currentEncoderPos < (turrMin + clampTolerance) || currentEncoderPos > (turrMax - clampTolerance)) {
// Clamp to servo range
turretPos = Math.max(turrMin, Math.min(turretPos, turrMax));
} else { // TODO: add so it only adds error when standstill
if (tagBearingDeg != 1000.0 && Math.abs(tagBearingDeg) > cameraBearingEqual && !lockOffset) {
// PID-based offset correction for faster, smoother tracking
// Proportional: respond to current error
offset = -controller.calculate(tagBearingDeg);
}
}
robot.turr1.setPosition(turretPos);
robot.turr2.setPosition(1.0 - turretPos);
/* ---------------- TELEMETRY ---------------- */
TELE.addData("Turret Angle", turretAngleDeg);
TELE.addData("Bearing", tagBearingDeg);
TELE.addData("Offset", offset);
}
}

6
build.gradle
View File

@@ -25,5 +25,9 @@ allprojects {
} }
repositories { repositories {
mavenCentral() repositories {
mavenCentral()
google()
maven { url 'https://maven.pedropathing.com' }
}
} }