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110 Commits
parthiv-de ... 782b6ec78f

Author SHA1 Message Date
Johannes
782b6ec78f Update competition_codes/state/sunprarie_state_main.py 2026-01-12 03:37:32 +00:00
Johannes
edd49e0a9b Update competition_codes/state/sunprarie_state_main.py 2026-01-12 03:36:10 +00:00
Johannes
ea9723a67d Update competition_codes/state/sunprarie_state_main.py 2026-01-12 03:30:25 +00:00
Johannes
67c6554c61 Update competition_codes/state/sunprarie_state_main.py 2026-01-11 20:16:08 +00:00
Johannes
2d57f65a58 Update competition_codes/state/sunprarie_state_main.py 2026-01-11 01:19:39 +00:00
Johannes
eb9b2ca30f Update competition_codes/state/sunprarie_state_main.py 2026-01-11 00:57:25 +00:00
Johannes
54dd1db320 Update competition_codes/state/sunprarie_state_main.py 2026-01-11 00:47:37 +00:00
Johannes
e46897548b Update competition_codes/state/sunprarie_state_main.py 2026-01-10 03:02:02 +00:00
Johannes
70c4df4a12 Update competition_codes/state/sunprarie_state_main.py 2026-01-10 03:01:48 +00:00
Johannes
0e009d2da4 Update competition_codes/state/sunprarie_state_main.py 2026-01-09 14:33:43 +00:00
Atharv Nagavarapu
e306b7dce1 Delete utils/starter_drivebase_code.py 2026-01-09 13:30:08 +00:00
Atharv Nagavarapu
aed13bedff Delete utils/constants.py 2026-01-09 13:29:06 +00:00
Atharv Nagavarapu
3e4dab3c9c Delete utils/color_sensor_navi.py 2026-01-09 13:28:45 +00:00
Atharv Nagavarapu
65373a16d3 Update old_combined/main5.py 2026-01-09 13:27:35 +00:00
Atharv Nagavarapu
ccd30af870 Update old_combined/4main.py 2026-01-09 13:27:28 +00:00
Atharv Nagavarapu
664defae73 Update old_combined/3main.py 2026-01-09 13:25:14 +00:00
Atharv Nagavarapu
b0fd33d6b0 Update old_combined/2main.py 2026-01-09 13:25:06 +00:00
Atharv Nagavarapu
dbf5fc4880 Update old_combined/1main.py 2026-01-09 13:24:59 +00:00
Atharv Nagavarapu
b3ab479bc4 Update final/old_combined/1main.py 2026-01-09 13:24:33 +00:00
Atharv Nagavarapu
ba3e833434 Update competition_codes/twist_scrimmage/twist_scrimmage.py 2026-01-09 13:22:52 +00:00
Atharv Nagavarapu
3bbf3fb2e6 Update competition_codes/twist_scrimmagetwist_scrimmage.py 2026-01-09 13:22:47 +00:00
Atharv Nagavarapu
79158d0f15 Update competition_codes/regional-final/RegionalFinalOld.py 2026-01-09 13:22:24 +00:00
Atharv Nagavarapu
b93ab2f788 Delete test_10_17_2025.py 2026-01-09 01:30:03 +00:00
Atharv Nagavarapu
44bbcf176d Delete config.py 2026-01-09 01:29:48 +00:00
Atharv Nagavarapu
a395daba02 Delete RoshoDaGoat.py 2026-01-09 01:29:36 +00:00
Johannes
fa28fbb086 Update competition_codes/state/sunprarie_state_main.py 2026-01-08 23:21:51 +00:00
Rishikesh Lolapu
8b152a371d Add competition_codes/state/Updated state.py 2026-01-08 23:11:34 +00:00
Johannes
50d125a09e Update competition_codes/state/sunprarie_state_main.py 
Forgot to add run task before
 2026-01-07 00:17:23 +00:00
Johannes
a116a9b3bb Update competition_codes/state/sunprarie_state_main.py 2026-01-06 22:24:05 +00:00
Johannes
4942f28e67 Update competition_codes/state/sunprarie_state_main.py 
Battery diagnostics added.
 2026-01-06 22:23:43 +00:00
Johannes
3efdf8ecbc Update competition_codes/state/sunprarie_state_main.py 
Slight changes to motor angles in Run_5.
 2026-01-05 01:24:12 +00:00
Johannes
4233cc5f74 Update competition_codes/state/sunprarie_state_main.py 
Various updates to a few of the codes.
 2026-01-04 18:09:47 +00:00
Johannes
6dbcfbe146 Update competition_codes/state/sunprarie_state_main.py 
Changes to Run 12
 2026-01-03 18:38:23 +00:00
Vickram
54aa537877 Fixed motor angles for the left arm 2025-12-29 22:45:02 +00:00
Johannes
aa69eed534 Update competition_codes/state/sunprarie_state_main.py 
Updates to run 10.
 2025-12-29 19:25:24 +00:00
Johannes
d5e7e5816a Add competition_codes/state/run11_experimental.py 2025-12-29 05:44:44 +00:00
Johannes
6755e783f4 Add competition_codes/state/run10_experimental.py 2025-12-29 05:44:11 +00:00
Johannes
d9dec685c3 Update competition_codes/state/sunprarie_state_main.py 
Slight updates to Send over and the first mission run.
 2025-12-28 01:55:38 +00:00
Johannes
5a5b6d2d16 Update competition_codes/state/sunprarie_state_main.py 
Code optimization and additions to 1st run.
 2025-12-24 16:34:38 +00:00
Johannes
a902f29952 Add competition_codes/state/sunprarie_state_main.py 2025-12-22 23:00:02 +00:00
nifrali
3014305d69 Update competition_codes/sectionals/mukwonago_sectionals_final.py 
Fixed return
 2025-12-09 17:34:12 +00:00
Atharv Nagavarapu
f38a3cc625 Update README.md 2025-12-08 19:18:33 +00:00
Atharv Nagavarapu
5a805e75fc Update README.md 2025-12-08 19:16:10 +00:00
Atharv Nagavarapu
4d94a35503 Update competition_codes/sectionals/mukwonago_sectionals_final.py 2025-12-08 19:15:10 +00:00
Atharv Nagavarapu
4539ee361f Update README.md 2025-12-08 19:13:17 +00:00
Atharv Nagavarapu
288c4eac26 Update README.md 2025-12-08 17:29:02 +00:00
nifrali
4f21cdc99c Update competition_codes/sectionals/sectional_main_dec_6.py 
Updated values
 2025-12-08 00:05:09 +00:00
Rishikesh Lolapu
a0bec55e97 Update competition_codes/sectionals/sectional_main_dec_6.py 2025-12-07 21:10:25 +00:00
Johannes
f838d6b566 Update competition_codes/sectionals/sectional_main_dec_6.py 2025-12-06 20:36:10 +00:00
Johannes
27e1e2f751 Update competition_codes/sectionals/sectional_main_dec_6.py 2025-12-06 20:35:00 +00:00
Johannes
f1f800783f Update competition_codes/sectionals/sectional_main_dec_6.py 
Updates for gear ratio change
 2025-12-06 20:16:37 +00:00
Rishikesh Lolapu
d0225f0417 Merge pull request 'Update competition_codes/sectionals/sectional_main_dec_6.py' (#50) from Rishi_dev into dev 
Reviewed-on: #50
 2025-12-06 20:09:25 +00:00
Rishikesh Lolapu
ddc0f2ccca Update competition_codes/sectionals/sectional_main_dec_6.py 2025-12-06 18:01:47 +00:00
Atharv Nagavarapu
61d1cf709c Merge pull request 'Rishi_dev' (#49) from Rishi_dev into dev 
Reviewed-on: #49
 2025-12-06 17:48:09 +00:00
Rishikesh Lolapu
59a4c42060 Update competition_codes/sectionals/sectional_main_experimental.py 2025-12-06 17:47:05 +00:00
Atharv Nagavarapu
0247088be2 Merge pull request 'dev' (#48) from dev into Rishi_dev 
Reviewed-on: #48
 2025-12-06 17:46:32 +00:00
Atharv Nagavarapu
42ceb9f38e Delete utils/tests/Diagnostics.py 2025-12-06 17:45:34 +00:00
Atharv Nagavarapu
f926fbba79 Delete utils/tests/ColorSensor.py 2025-12-06 17:45:31 +00:00
Atharv Nagavarapu
63d4b27648 Delete utils/tests/FullDiagnostics/FullDiagnostics.py 2025-12-06 17:44:25 +00:00
Atharv Nagavarapu
1db4458e16 Delete utils/tests/FullDiagnostics/BatteryDiagnostics.py 2025-12-06 17:44:20 +00:00
Vickram
821924e875 Upload files to "utils/tests/FullDiagnostics" 2025-12-06 17:22:50 +00:00
Vickram
61d3dd3c06 Delete utils/tests/BatteryDiagnostics.py/BatteryDiagnostics.py 2025-12-06 17:21:24 +00:00
Vickram
1a966fd553 Upload files to "utils/tests/BatteryDiagnostics.py" 2025-12-06 17:20:58 +00:00
Vickram
ca0a9df801 Delete BatteryDiagnostics.py/BatteryDiagnostics.py 2025-12-06 17:20:14 +00:00
Vickram
8b2ab7b9c2 Upload files to "BatteryDiagnostics.py" 2025-12-06 17:19:39 +00:00
Johannes
6fee096cf8 Update competition_codes/sectionals/sectional_main_experimental.py 2025-12-06 14:26:20 +00:00
Atharv
e8607d02ae Update utils/tests/ColorSensor.py 2025-12-05 16:28:00 +00:00
Rishikesh Lolapu
d507a9c204 Update competition_codes/sectionals/sectional_main_experimental.py 2025-12-04 23:46:26 +00:00
Vickram
8bee9efe6b Add utils/tests/Diagnostics.py 
Returns all information about the robot
 2025-12-04 23:41:29 +00:00
Johannes
d235d602ce Update competition_codes/sectionals/sectional_main_experimental.py 2025-12-04 23:33:57 +00:00
Johannes
e8c25a4e90 Update competition_codes/sectionals/sectional_main_experimental.py 2025-12-04 03:01:19 +00:00
Johannes
f389ff7101 Update competition_codes/sectionals/sectional_main_experimental.py 2025-12-04 01:46:03 +00:00
Atharv
51f4d4237c Merge pull request 'atharv-dev' (#47) from atharv-dev into dev 
Reviewed-on: #47
 2025-11-25 23:11:26 +00:00
Atharv
489ff94601 Update competition_codes/sectionals/sectional_main_experimental.py 2025-11-25 20:27:57 +00:00
Atharv
05be290f90 Update competition_codes/sectionals/sectional_main_experimental.py 2025-11-25 20:23:48 +00:00
Atharv
d4e44bb53f Merge pull request 'for-sectionals/experimental' (#46) from for-sectionals/experimental into atharv-dev 
Reviewed-on: #46
 2025-11-25 20:21:38 +00:00
nifrali
751e008854 Experimentals 2025-11-25 13:17:33 -06:00
Rishikesh Lolapu
d5e9a97fc6 RegionalFinal.py 
This is the final code. If changes are needed, please contact (31lolapr@elmbrookstudents.org).
 2025-11-15 17:13:26 +00:00
Atharv
9e429cf8f1 Update README.md 2025-11-12 01:15:22 +00:00
Atharv
eae9c77bcf Update README.md 2025-11-12 01:14:40 +00:00
Atharv
73ca30ed4c Delete commit-graphnew.html 2025-11-12 01:13:09 +00:00
Atharv
b08d80b4b6 Delete graph.txt 2025-11-12 01:13:04 +00:00
Atharv
7047a0d227 Delete commit-graph.html 2025-11-12 01:12:58 +00:00
Atharv
e254c65c56 Merge pull request 'Update missions/tip the scale.py' (#43) from parthiv-dev into dev 
Reviewed-on: #43
 2025-11-12 01:12:37 +00:00
Atharv
b3ec4861c7 Merge pull request 'Add codes_for_scrimmage/regional-final/Final_combined.py' (#42) from Rishi_dev into dev 
Reviewed-on: #42
 2025-11-12 01:12:07 +00:00
alkadienePhoton
9f5a41eace Merge branch 'dev' of https://codes.fll-65266.org/FLL_65266_LEGO_DYNAMICS/solutions_season_unearthed into dev 
Works
 2025-11-11 19:11:13 -06:00
alkadienePhoton
686875a066 Fixed conflicts 2025-11-11 19:10:54 -06:00
alkadienePhoton
6d54f9c2d7 Fixed conflicts 2025-11-11 19:10:21 -06:00
Rishikesh Lolapu
10960a8473 Add codes_for_scrimmage/regional-final/Final_combined.py 2025-11-12 01:06:33 +00:00
Atharv
19f79b91d1 Update utils/FINAL_STARTER_BLANK_CODE.py 2025-11-12 00:37:21 +00:00
Atharv
1c0896cbeb Add utils/FINAL_STARTER_BLANK_CODE.py 
ayaan is SO ANNOYING BRO
 2025-11-12 00:31:22 +00:00
Johannes
d2738e2615 Update codes_for_scrimmage/hazmat/mainhazmatUPD.py 2025-11-09 22:26:09 +00:00
Johannes
1ee90ac2e1 Update missions/M8_5.py 2025-11-09 22:16:39 +00:00
Atharv
31f482f576 Update LINEUPS.md 2025-11-09 01:52:54 +00:00
Atharv
30a5392e56 Update LINEUPS.md 2025-11-09 01:20:19 +00:00
Atharv
3b22d28e98 Update LINEUPS.md 2025-11-09 01:12:56 +00:00
alkadienePhoton
9cdb70dd80 Merging with actual stuff fixed #2 2025-11-08 17:51:13 -06:00
alkadienePhoton
c3c875e80e Merging with actual stuff fixed 2025-11-08 17:50:29 -06:00
alkadienePhoton
809789837d Merging 2025-11-08 17:48:31 -06:00
Atharv
39bfe7b307 Merge pull request 'parthiv-dev' (#39) from parthiv-dev into dev 
Reviewed-on: #39
 2025-11-08 23:45:13 +00:00
alkadienePhoton
80d6300fc0 Merge branch 'dev' of https://codes.fll-65266.org/FLL_65266_LEGO_DYNAMICS/solutions_season_unearthed into dev 
merging dev
 2025-11-08 17:43:45 -06:00
alkadienePhoton
b25a2a5feb Merge branch 'Vickram_dev_' into dev 
Merging Vickram_dev_ into dev
 2025-11-08 17:40:27 -06:00
Atharv
2d614c0e38 Update LINEUPS.md 
well now we have 5 missions?
 2025-11-08 22:25:56 +00:00
Johannes
c7801d17c0 Update codes_for_scrimmage/hazmat/mainhazmatUPD.py 2025-11-07 23:14:24 +00:00
Vickram
6e82f4d476 Add missions/New_MapReveal/New_MapReveal_Mineshaft.py 
Rishi's updated code
 2025-11-07 23:12:55 +00:00
Johannes
9061eef311 Update codes_for_scrimmage/hazmat/mainhazmatUPD.py 2025-11-06 01:12:19 +00:00
Atharv
21e8bd68c2 Merge pull request 'dev' (#33) from dev into Johannes_Dev 
Reviewed-on: #33
 2025-10-31 11:57:09 +00:00
Atharv
b4385dcecd Merge pull request 'dev' (#32) from dev into atharv-dev 
Reviewed-on: #32
 2025-10-31 11:56:39 +00:00
Vickram
7e1d310e24 New rishi code 2025-10-31 00:29:07 +00:00
Vickram
37b025088f Merge pull request 'dev' (#30) from dev into Vickram_dev_ 
Reviewed-on: #30
 2025-10-31 00:27:53 +00:00
32 changed files with 1999 additions and 593 deletions
Expand all files Collapse all files

12
LINEUPS.md
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@@ -2,14 +2,14 @@
## These are the line-up positions for the robot game for various missions.
- Mission Run #1 (Mission #1) [Right/Blue Home] - The left yellow part of the right arm attachment is positioned with its right edge on the 5th thin line from the left. Note that this is NOT positioned from the back of the robot.
- Mission Run #1 (Run #1) [Right/Blue Home] - The left yellow part of the right arm attachment is positioned with its right edge on the 5th thin line from the left. Note that this is NOT positioned from the back of the robot. Also, when counting these lines, make sure you count from the inside curve, not the outside.
- Mission Run #2 (Send Over) [Right/Blue Home] - The robot should be lined up on the vertical edge of the left home. The robot's right side should be positioned on the 1st thin line from the top. Note that the 0th line is the one that is not part of the curve.
<img src="https://codes.fll-65266.org/FLL_65266_LEGO_DYNAMICS/solutions_season_unearthed/raw/branch/do-not-merge/r1l.png" alt="Alt text" width="300"/>
- Mission Run #3 (Sand mission) [Right/Blue Home] - The robot should be lined up on the vertical edge of the left home. The robot's left side should be positioned on the 1/2th thin line from the bottom.
- Mission Run #2 (Tip the scales) [Right/Blue Home] - The middle of the left edge of the robot should be positioned on the 2nd thick line from the left.
- Mission Run #4 (Boat mission) [Left/Red Home] - The robot should be lined up on the vertical edge of the left home. The robot's right side should be positioned on the 2nd thick line from the bottom.
- Mission Run #3 (Send Over) [Right/Blue Home] - The robot should be lined up on the vertical edge of the right home. The robot's right edge should be positioned on the 1st thin line from the top. Note that the 0th line is the one that is in the inner curve.
- Mission Run #5 (Bautism) [Left/Red Home] - The robot's left edge should be positioned at the 1st thick, 2nd thin line from the left.
- Mission Run #4 (Run #4) [Left/Red Home] - The robot's left edge should be positioned on the 2nd thick line from the left.
- Mission Run #6 (Not-so-heavy Lifting) [Right/Blue Home] - The robot's right edge should be positioned at the 1st thick from the right.
- Mission Run #5 (Boat mission) [Left/Red Home] - There are two alignments for this. When sending off the robot for part 1, the robot should be facing the right home. It's right edge should be positioned at the very bottom edge of the board. Once it completes the pulling part, once it comes back begin part 2. For part 2, the middle of the robot's right side should be positioned in the middle of the 3rd thick and the 3rd thick, 1st thin lines from the top. For both runs the robot should be facing the blue home.

13
README.md
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@@ -63,17 +63,14 @@ Repository
### Installation & Deployment - from the server - everyday
1. Download the file codes_for_scrimmage/hazmat/mainhazmatUPD.py
1. Download the file competition_codes/sectionals/sectional_main_dec_6.py
- You can do this through the repo, by using cURL, or by using git.
- Repo - Go to [codes_for_scrimmage/hazmat/mainhazmatUPD.py](codes_for_scrimmage/hazmat/mainhazmatUPD.py) and click the "Download" button.
- cURL or another HTTP data transferrer -
```curl -o mainhazmatUPD.py https://codes.fll-65266.org/FLL_65266_LEGO_DYNAMICS/solutions_season_unearthed/raw/branch/main/codes_for_scrimmage/hazmat/mainhazmatUPD.py```
- Repo - Go to the [latest release](https://codes.fll-65266.org/FLL_65266_LEGO_DYNAMICS/solutions_season_unearthed/releases) and click the "Download as ZIP" button to get the full repository.
- Single file - Go to the latest release and click the file link to get the raw master file.
- git CLI -
```git clone -b dev https://codes.fll-65266.org/FLL_65266_LEGO_DYNAMICS/solutions_season_unearthed.git && cd solutions_season_unearthed/codes_for_scrimmage/hazmat```
```git clone https://codes.fll-65266.org/FLL_65266_LEGO_DYNAMICS/solutions_season_unearthed.git```
Then use mainhazmatUPD.py.
Then use the master file.
2. Open https://code.pybricks.com/ and select the "Import a file" button on the top of the left bar. Import the .py file. Pair your robot via Bluetooth in Pybricks by selecting the Bluetooth button.

42
RoshoDaGoat.py
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@@ -1,42 +0,0 @@
from pybricks.hubs import PrimeHub
from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor, ForceSensor
from pybricks.parameters import Button, Color, Direction, Port, Side, Stop
from pybricks.robotics import DriveBase
from pybricks.tools import wait, StopWatch, run_task, multitask
hub = PrimeHub()
# Initialize both motors. In this example, the motor on the
# left must turn counterclockwise to make the robot go forward.
left_motor = Motor(Port.A, Direction.COUNTERCLOCKWISE)
right_motor = Motor(Port.B)
arm_motor = Motor(Port.D, Direction.CLOCKWISE)
arm_motor_left= Motor(Port.C, Direction.CLOCKWISE)
# Initialize the drive base. In this example, the wheel diameter is 56mm.
# The distance between the two wheel-ground contact points is 112mm.
drive_base = DriveBase(left_motor, right_motor, wheel_diameter=68.8, axle_track=180)
print('The default settings are: ' + str(drive_base.settings()))
drive_base.settings(300,1000,300,750)
# Optionally, uncomment the line below to use the gyro for improved accuracy.
drive_base.use_gyro(True)
async def main():
await drive_base.straight(519)
await arm_motor_left.run_angle(-10000, 300)
await arm_motor_left.run_angle(10000, 600)
await drive_base.straight(160)
await drive_base.turn(-30)
await drive_base.straight(50)
await arm_motor.run_angle(3000, 3000)
await drive_base.straight(-150)
await drive_base.turn(135)
await drive_base.straight(50)
await arm_motor.run_angle(10000, -3000)
await drive_base.straight(-100)
await drive_base.turn(-54)
await arm_motor.run_angle(10000, -3000)
await drive_base.straight(200)
await arm_motor.run_angle(10000, 10000)
run_task(main())

0
codes_for_scrimmage/hazmat/HazmatCodeChanges.py → competition_codes/hazmat/HazmatCodeChanges.py
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0
codes_for_scrimmage/hazmat/Heavy_lifting_final.py → competition_codes/hazmat/Heavy_lifting_final.py
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0
codes_for_scrimmage/hazmat/M8_5.py → competition_codes/hazmat/M8_5.py
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0
codes_for_scrimmage/hazmat/Send_Over_Final.py → competition_codes/hazmat/Send_Over_Final.py
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0
codes_for_scrimmage/hazmat/hazmat_main.py → competition_codes/hazmat/hazmat_main.py
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47
codes_for_scrimmage/hazmat/mainhazmatUPD.py → competition_codes/hazmat/mainhazmatUPD.py
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@@ -45,22 +45,28 @@ async def monitor_distance():
# New Section
async def Run1(): # From M8_5.py
right_arm.run_angle(1000,450)
left_arm.run_angle(500,80)
left_arm.run_angle(500,-90)
await drive_base.straight(200)
await drive_base.turn(-40)
await drive_base.straight(325)
await left_arm.run_angle(500,-80)
await left_arm.run_angle(500,90)
await drive_base.straight(-100)
await drive_base.straight(50)
await left_arm.run_angle(500,170)
await left_arm.run_angle(500,-180)
await drive_base.straight(-270)
await drive_base.turn(40)
await drive_base.straight(135)
left_arm.run_angle(1000,670)
await drive_base.straight(-90)
left_arm.run_angle(500,180)
await drive_base.turn(-20)
await drive_base.turn(15)
await drive_base.straight(-173)
await drive_base.turn(45)
await drive_base.straight(120)
left_arm.run_angle(1000,-670)
await right_arm.run_angle(5000,-450, Stop.HOLD)
await right_arm.run_angle(5000,450, Stop.HOLD)
@@ -70,7 +76,7 @@ async def Run1(): # From M8_5.py
right_arm.run_angle(5000,450, Stop.HOLD)
await drive_base.turn(-35)
await drive_base.straight(300)
await drive_base.straight(297)
await drive_base.turn(63)
await drive_base.straight(170)
@@ -78,12 +84,9 @@ async def Run1(): # From M8_5.py
await drive_base.straight(87)
await drive_base.turn(-15)
await drive_base.straight(-120)
await drive_base.straight(-90)
await drive_base.turn(-100)
await drive_base.straight(300)
await drive_base.turn(-45)
await drive_base.straight(500)
await drive_base.arc(-500,None,600)
async def Run2(): # From Heavy_lifting_final.py
await drive_base.straight(200)
@@ -142,16 +145,16 @@ async def Run4(): # From Send_Over_Final.py
# Add Rishi's code here
async def Run5():
await drive_base.straight(700)
await drive_base.turn(-18)
await drive_base.straight(600)
await drive_base.straight(-100)
await drive_base.straight(150)
await drive_base.turn(60)
await drive_base.straight(100)
await drive_base.straight(-205)
await drive_base.turn(63)
await drive_base.straight(125)
await arm_motor.run_angle(1000, -1200)
await drive_base.straight(84)
await arm_motor.run_angle(300, 1200)
await drive_base.straight(-875)
await drive_base.turn(-86)
await drive_base.straight(120)
await drive_base.turn(-45)
await drive_base.straight(-200)
await drive_base.turn(75)
# Add - Adi's code here
async def Run6():

0
codes_for_scrimmage/hazmat/tip the scale.py → competition_codes/hazmat/tip the scale.py
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221
competition_codes/regional-final/Final_combined.py Normal file
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@@ -0,0 +1,221 @@
from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor, ForceSensor
from pybricks.parameters import Button, Color, Direction, Port, Side, Stop
from pybricks.tools import run_task, multitask
from pybricks.tools import wait, StopWatch
from pybricks.robotics import DriveBase
from pybricks.hubs import PrimeHub
# Initialize hub and devices
hub = PrimeHub()
left_motor = Motor(Port.A, Direction.COUNTERCLOCKWISE)
right_motor = Motor(Port.B)
left_arm = Motor(Port.C)
right_arm = Motor(Port.D)
lazer_ranger = UltrasonicSensor(Port.E)
color_sensor = ColorSensor(Port.F)
# DriveBase configuration
WHEEL_DIAMETER = 68.8 # mm (adjust for your wheels)
AXLE_TRACK = 180 # mm (distance between wheels)
drive_base = DriveBase(left_motor, right_motor, WHEEL_DIAMETER, AXLE_TRACK)
drive_base.settings(600, 500, 300, 200)
drive_base.use_gyro(True)
WALL_DISTANCE = 300 # mm
async def drive_forward():
"""Drive forward continuously using DriveBase."""
drive_base.drive(400, 0)
async def monitor_distance():
"""Monitor ultrasonic sensor and stop when wall is detected."""
while True:
distance = await lazer_ranger.distance()
print('Distancing...',distance)
if distance < WALL_DISTANCE:
# Stop the drivebase
await drive_base.stop
print(f"Wall detected at {distance}mm!")
break
# Small delay to prevent overwhelming the sensor
await wait(50)
# New Section
async def Run1(): # From M8_5.py
right_arm.run_angle(1000,450)
left_arm.run_angle(500,90)
await drive_base.straight(200)
await drive_base.turn(-40)
await drive_base.straight(325)
await left_arm.run_angle(500,-90)
await drive_base.straight(-100)
await drive_base.straight(50)
await left_arm.run_angle(500,180)
await drive_base.straight(-90)
left_arm.run_angle(500,-180)
await drive_base.turn(-20)
await drive_base.turn(15)
await drive_base.straight(-173)
await drive_base.turn(45)
await drive_base.straight(120)
left_arm.run_angle(1000,670)
await right_arm.run_angle(5000,-450, Stop.HOLD)
await right_arm.run_angle(5000,450, Stop.HOLD)
await right_arm.run_angle(5000,-450, Stop.HOLD)
await right_arm.run_angle(5000,450, Stop.HOLD)
await right_arm.run_angle(5000,-450, Stop.HOLD)
right_arm.run_angle(5000,450, Stop.HOLD)
await drive_base.turn(-35)
await drive_base.straight(297)
await drive_base.turn(63)
await drive_base.straight(170)
await drive_base.turn(-80)
await drive_base.straight(87)
await drive_base.turn(-15)
await drive_base.straight(-90)
await drive_base.turn(-100)
await drive_base.arc(-500,None,600)
async def Run2(): # From Heavy_lifting_final.py
await drive_base.straight(200)
await drive_base.turn(-20)
await drive_base.straight(536)
await drive_base.turn(60, Stop.HOLD)
await drive_base.straight(30)
await right_arm.run_angle(5000, 2900)
await drive_base.straight(40)
await right_arm.run_angle(5000, -4000)
await drive_base.straight(-60)
await drive_base.turn(-60)
await drive_base.straight(-670)
async def Run3(): # tip the scale.py
right_arm.run_angle(500,400)
await drive_base.straight(800)
await drive_base.turn(90)
await drive_base.straight(86)
await right_arm.run_angle(800,-600)
await right_arm.run_angle(900,800)
await drive_base.straight(-100)
await drive_base.turn(90)
await drive_base.straight(800)
drive_base.brake()
async def Run4(): # From Send_Over_Final.py
await drive_base.straight(920)
await drive_base.turn(-90,Stop.HOLD)
await drive_base.straight(65)
#Solve
drive_base.turn(-10)
await left_arm.run_angle(10000,-4000)
await drive_base.straight(-110)
await drive_base.turn(90)
await multitask(
drive_forward(),
monitor_distance()
)
# Add Rishi's code here
async def Run5():
await drive_base.straight(700)
await drive_base.turn(-20)
await drive_base.straight(110)
await drive_base.straight(-210)
await drive_base.turn(63)
await drive_base.straight(130)
await right_arm.run_angle(1000, -1200)
await drive_base.straight(84)
await right_arm.run_angle(300, 1200)
await drive_base.straight(-875)
# Add - Adi's code here
async def Run6():
await drive_base.straight(500)
await right_arm.run_angle(300,500)
await drive_base.straight(-75)
await right_arm.run_angle(300, -900)
await drive_base.straight(-350)
await wait(1000)
await drive_base.straight(800)
await drive_base.straight(-200)
await drive_base.turn(-15)
await drive_base.straight(350)
await drive_base.turn(-100)
await drive_base.straight(-80)
await left_arm.run_angle(500, -900)
await drive_base.straight(50)
await drive_base.straight(50)
await left_arm.run_angle(700, 250)
await drive_base.turn(30)
await drive_base.straight(-60)
await drive_base.turn(80)
await drive_base.straight(-900)
# Function to classify color based on HSV
def detect_color(h, s, v, reflected):
if reflected > 4:
if h < 4 or h > 350: # red
return "Red"
elif 3 < h < 40 and s > 70: # orange
return "Orange"
elif 47 < h < 56: # yellow
return "Yellow"
elif 70 < h < 160: # green - do it vertically not horizontally for accuracy
return "Green"
elif 210 < h < 225: # blue - do it vertically not horizontally for accuracy
return "Blue"
elif 260 < h < 350: # purple
return "Purple"
else:
return "Unknown"
return "Unknown"
async def main():
while True:
h, s, v = await color_sensor.hsv()
reflected = await color_sensor.reflection()
color = detect_color(h, s, v, reflected)
if color == "Red":
print('Running Mission 3')
await Run3() #red
elif color == "Orange":
print('Running Mission 6')
await Run6() #orange
elif color == "Yellow":
print('Running Mission 4')
await Run4() #yellow
elif color == "Green":
print('Running Mission 1')
await Run1() #green - vertically
elif color == "Blue":
print('Running Mission 5')
await Run5() #blue - vertically
elif color == "Purple":
print('Running Mission 2')
await Run2() #purple - vertically
else:
print(f"Unknown color detected (Hue: {h}, Sat: {s}, Val: {v})")
await wait(10)
# Run the main function
run_task(main())

220
competition_codes/regional-final/RegionalFinalOld.py Normal file
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@@ -0,0 +1,220 @@
from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor, ForceSensor
from pybricks.parameters import Button, Color, Direction, Port, Side, Stop
from pybricks.tools import run_task, multitask
from pybricks.tools import wait, StopWatch
from pybricks.robotics import DriveBase
from pybricks.hubs import PrimeHub
# Initialize hub and devices
hub = PrimeHub()
left_motor = Motor(Port.A, Direction.COUNTERCLOCKWISE)
right_motor = Motor(Port.B)
left_arm = Motor(Port.C)
right_arm = Motor(Port.D)
lazer_ranger = UltrasonicSensor(Port.E)
color_sensor = ColorSensor(Port.F)
# DriveBase configuration
WHEEL_DIAMETER = 68.8 # mm (adjust for your wheels)
AXLE_TRACK = 180 # mm (distance between wheels)
drive_base = DriveBase(left_motor, right_motor, WHEEL_DIAMETER, AXLE_TRACK)
drive_base.settings(600, 500, 300, 200)
drive_base.use_gyro(True)
WALL_DISTANCE = 300 # mm
async def drive_forward():
"""Drive forward continuously using DriveBase."""
drive_base.drive(400, 0)
async def monitor_distance():
"""Monitor ultrasonic sensor and stop when wall is detected."""
while True:
distance = await lazer_ranger.distance()
print('Distancing...',distance)
if distance < WALL_DISTANCE:
# Stop the drivebase
await drive_base.stop
print(f"Wall detected at {distance}mm!")
break
# Small delay to prevent overwhelming the sensor
await wait(50)
# New Section
async def Run1(): # From M8_5.py
right_arm.run_angle(1000,450)
left_arm.run_angle(500,90)
await drive_base.straight(200)
await drive_base.turn(-40)
await drive_base.straight(325)
await left_arm.run_angle(500,-90)
await drive_base.straight(-100)
await drive_base.straight(50)
await left_arm.run_angle(500,180)
await drive_base.straight(-90)
left_arm.run_angle(500,-180)
await drive_base.turn(-20)
await drive_base.turn(15)
await drive_base.straight(-173)
await drive_base.turn(45)
await drive_base.straight(120)
left_arm.run_angle(1000,670)
await right_arm.run_angle(5000,-450, Stop.HOLD)
await right_arm.run_angle(5000,450, Stop.HOLD)
await right_arm.run_angle(5000,-450, Stop.HOLD)
await right_arm.run_angle(5000,450, Stop.HOLD)
await right_arm.run_angle(5000,-450, Stop.HOLD)
right_arm.run_angle(5000,450, Stop.HOLD)
await drive_base.turn(-35)
await drive_base.straight(297)
await drive_base.turn(63)
await drive_base.straight(170)
await drive_base.turn(-80)
await drive_base.straight(87)
await drive_base.turn(-15)
await drive_base.straight(-90)
await drive_base.turn(-100)
await drive_base.arc(-500,None,600)
async def Run2(): # From Heavy_lifting_final.py
await drive_base.straight(200)
await drive_base.turn(-20)
await drive_base.straight(536)
await drive_base.turn(60, Stop.HOLD)
await drive_base.straight(30)
await right_arm.run_angle(5000, 2900)
await drive_base.straight(40)
await right_arm.run_angle(5000, -4000)
await drive_base.straight(-60)
await drive_base.turn(-60)
await drive_base.straight(-670)
async def Run3(): # tip the scale.py
right_arm.run_angle(500,400)
await drive_base.straight(800)
await drive_base.turn(90)
await drive_base.straight(86)
await right_arm.run_angle(800,-600)
await right_arm.run_angle(900,800)
await drive_base.straight(-100)
await drive_base.turn(90)
await drive_base.straight(800)
drive_base.brake()
async def Run4(): # From Send_Over_Final.py
await drive_base.straight(920)
await drive_base.turn(-90,Stop.HOLD)
await drive_base.straight(65)
#Solve
drive_base.turn(-10)
await left_arm.run_angle(10000,-4000)
await drive_base.straight(-110)
await drive_base.turn(90)
await multitask(
drive_forward(),
monitor_distance()
)
# Add Rishi's code here
async def Run5():
await drive_base.straight(700)
await drive_base.turn(-20)
await drive_base.straight(110)
await drive_base.straight(-210)
await drive_base.turn(63)
await drive_base.straight(130)
await right_arm.run_angle(1000, -1200)
await drive_base.straight(84)
await right_arm.run_angle(300, 1200)
await drive_base.straight(-900)
# Add - Adi's code here
async def Run6():
await drive_base.straight(500)
await right_arm.run_angle(300,500)
await drive_base.straight(-75)
await right_arm.run_angle(300, -900)
await drive_base.straight(-350)
await wait(1000)
await drive_base.straight(800)
await drive_base.straight(-200)
await drive_base.turn(-15)
await drive_base.straight(350)
await drive_base.turn(-102.5)
await drive_base.straight(-80)
await left_arm.run_angle(500, -900)
await drive_base.straight(50)
await drive_base.straight(50)
await left_arm.run_angle(700, 270)
await drive_base.turn(30)
await drive_base.straight(-60)
# Function to classify color based on HSV
def detect_color(h, s, v, reflected):
if reflected > 4:
if h < 4 or h > 350: # red
return "Red"
elif 3 < h < 40 and s > 70: # orange
return "Orange"
elif 47 < h < 56: # yellow
return "Yellow"
elif 70 < h < 160: # green - do it vertically not horizontally for accuracy
return "Green"
elif 210 < h < 225: # blue - do it vertically not horizontally for accuracy
return "Blue"
elif 260 < h < 350: # purple
return "Purple"
else:
return "Unknown"
return "Unknown"
async def main():
while True:
h, s, v = await color_sensor.hsv()
reflected = await color_sensor.reflection()
color = detect_color(h, s, v, reflected)
if color == "Red":
print('Running Mission 3')
await Run3() #red
elif color == "Orange":
print('Running Mission 6')
await Run6() #orange
elif color == "Yellow":
print('Running Mission 4')
await Run4() #yellow
elif color == "Green":
print('Running Mission 1')
await Run1() #green - vertically
elif color == "Blue":
print('Running Mission 5')
await Run5() #blue - vertically
elif color == "Purple":
print('Running Mission 2')
await Run2() #purple - vertically
else:
print(f"Unknown color detected (Hue: {h}, Sat: {s}, Val: {v})")
await wait(10)
# Run the main function
run_task(main())

383
competition_codes/sectionals/mukwonago_sectionals_final.py Normal file
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@@ -0,0 +1,383 @@
from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor, ForceSensor
from pybricks.parameters import Button, Color, Direction, Port, Side, Stop
from pybricks.tools import run_task, multitask
from pybricks.tools import wait, StopWatch
from pybricks.robotics import DriveBase
from pybricks.hubs import PrimeHub
# Initialize hub and devices
hub = PrimeHub()
left_motor = Motor(Port.A, Direction.COUNTERCLOCKWISE)
right_motor = Motor(Port.B,Direction.CLOCKWISE) # Specify default direction
left_arm = Motor(Port.C, Direction.CLOCKWISE) # Specify default direction
right_arm = Motor(Port.D, Direction.CLOCKWISE,[[12,36],[12,20,24]]) #Added gear train list for gear ration
lazer_ranger = UltrasonicSensor(Port.E)
color_sensor = ColorSensor(Port.F)
# DriveBase configuration
WHEEL_DIAMETER = 68.8 # mm (adjust for your wheels)
AXLE_TRACK = 180 # mm (distance between wheels)
drive_base = DriveBase(left_motor, right_motor, WHEEL_DIAMETER, AXLE_TRACK)
drive_base.settings(600, 500, 300, 200)
drive_base.use_gyro(True)
WALL_DISTANCE = 200 # mm
async def drive_forward():
"""Drive forward continuously using DriveBase."""
drive_base.drive(400, 0)
async def drive_backward():
"""Drive forward continuously using DriveBase."""
drive_base.drive(400, 0)
async def monitor_distance():
"""Monitor ultrasonic sensor and stop when wall is detected."""
while True:
distance = await lazer_ranger.distance()
print('Distancing...',distance)
if distance < WALL_DISTANCE:
# Stop the drivebase
drive_base.stop()
print(f"Wall detected at {distance}mm!")
break
if distance is None:
continue
# Small delay to prevent overwhelming the sensor
await wait(50)
"""
Run#1
- Removed forge and who lived here part
- What's on sale + Silo
- Green Key
"""
async def Run1():
await solve_whats_on_sale()
await solve_silo()
# return to base
await drive_base.straight(-90)
#await drive_base.turn(-100)
await drive_base.arc(200,None,-300)
drive_base.stop()
async def solve_whats_on_sale():
right_arm.run_angle(500,30)
left_arm.run_angle(500,90)
await drive_base.straight(200)
await drive_base.turn(-40)
await drive_base.straight(325)
await left_arm.run_angle(500,-90)
await drive_base.straight(-100)
await drive_base.straight(50)
await left_arm.run_angle(500,180)
await drive_base.straight(-90)
left_arm.run_angle(500,-180)
await drive_base.turn(-20)
await drive_base.turn(15)
async def solve_silo():
await drive_base.straight(-173)
await drive_base.turn(45)
await drive_base.straight(120)
left_arm.run_angle(1000,670)
await right_arm.run_angle(4000,-30, Stop.HOLD)
await right_arm.run_angle(4000,30, Stop.HOLD)
await right_arm.run_angle(4000,-30, Stop.HOLD)
await right_arm.run_angle(4000,30, Stop.HOLD)
await right_arm.run_angle(4000,-30, Stop.HOLD)
right_arm.run_angle(4000,30, Stop.HOLD)
"""
Run#2
- This to solve forge, who lived here and heavy lifting combined
- Red Key
"""
async def Run2():
await solve_forge()
await solve_heavy_lifting()
await solve_who_lived_here()
# return to base
await drive_base.arc(-500,None,600)
drive_base.stop()
async def solve_forge():
await right_arm.run_target(50,50)
# await right_arm.run_angle(50,-30)
await drive_base.arc(350,113, None)
await drive_base.straight(20)
await drive_base.turn(-60)
await drive_base.straight(-47)
async def solve_heavy_lifting():
await right_arm.run_angle(500,-160) # arm down
await wait(100)
await drive_base.turn(20) # turn right a little bit
await right_arm.run_angle(500,160) #arm up
await drive_base.turn(-20) #reset position
async def solve_who_lived_here():
await drive_base.straight(50)
await drive_base.turn(-15)
await drive_base.straight(50)
await drive_base.turn(-25)
await drive_base.straight(-50)
await drive_base.turn(-100)
"""
Run#2.1
- Alternate solution for Forge, Who lived here and Heavy Lifting combined
- Light Blue Key
- Different alignment
"""
async def Run2_1():
await solve_forge_straight()
await solve_heavy_lifting()
await solve_who_lived_here()
# return to base
await drive_base.arc(-500,None,600)
drive_base.stop()
async def solve_forge_straight():
await right_arm.run_target(50,50)
await right_arm.run_angle(50,-30)
await drive_base.straight(700)
# await drive_base.turn(-30)
# await drive_base.straight(20)
await drive_base.turn(-40)
await drive_base.straight(-30)
"""
Run#3
- Combined angler artifacts and tip the scale
- Yellow key
"""
async def Run3():
await solve_angler_artifacts()
await solve_tip_the_scale()
#cross over to red side
await multitask(
drive_forward(),
monitor_distance()
)
async def solve_angler_artifacts():
await drive_base.straight(940)
await drive_base.turn(-90,Stop.HOLD)
await drive_base.straight(65)
#Solve
drive_base.turn(-10)
await left_arm.run_angle(10000,-3000)
await drive_base.straight(-110)
await drive_base.turn(90)
await drive_base.arc(-150,-103, None)
async def solve_tip_the_scale():
await drive_base.turn(3)
await drive_base.straight(142.5)
await right_arm.run_angle(800,-150)
await right_arm.run_angle(900,150)
await drive_base.straight(-100)
await drive_base.turn(-65)
await drive_base.straight(300,Stop.COAST_SMART)
await drive_base.arc(10,-47, None)
#await drive_base.turn(-23, Stop.COAST_SMART)
"""
Run #4
- Solves the Mineshaft explorer + 2/3 Surface Brush + 1/3 Map Reveal
- Blue Key
"""
async def Run4():
await drive_base.straight(700)
await drive_base.turn(-18)
await drive_base.straight(120)
await drive_base.straight(-210)
await drive_base.turn(61)
await drive_base.straight(133)
await right_arm.run_angle(400, -200)
await drive_base.straight(90)
await right_arm.run_angle(100, 95)
#await drive_base.straight(-875)
#return with arc
await drive_base.straight(-600)
await drive_base.arc(10,-47, None)
await drive_base.straight(-400,Stop.COAST_SMART)
async def solve_brush_reveal():
await drive_base.straight(700)
await drive_base.turn(-20)
await drive_base.straight(110)
await drive_base.straight(-210)
async def solve_mineshaft_explorer():
await drive_base.turn(63)
await drive_base.straight(130)
await right_arm.run_angle(1000, -90)
await drive_base.straight(84)
await right_arm.run_angle(300, 90)
"""
Run#5
- Solves Salvage Operation + Statue Rebuild
- Orange Key
"""
async def Run5():
await drive_base.straight(550)
await right_arm.run_angle(300,100)
await drive_base.straight(-75)
await right_arm.run_angle(300, -100)
await drive_base.straight(300)
await drive_base.straight(-200)
await drive_base.turn(-15)
#solving statue
await drive_base.straight(350)
await drive_base.turn(-104)
await drive_base.straight(-80)
await left_arm.run_angle(500, -900)
await drive_base.straight(120)
await drive_base.turn(5)
await left_arm.run_angle(500, 290)
await drive_base.turn(18)
await drive_base.straight(-100)
await drive_base.turn(-90)
await drive_base.straight(900)
drive_base.stop()
async def solve_salvage_operation():
await drive_base.straight(500)
await right_arm.run_angle(300,500)
await drive_base.straight(-75)
await right_arm.run_angle(300, -900)
await drive_base.straight(-350)
await wait(1000)
await drive_base.straight(800)
await drive_base.straight(-200)
await drive_base.turn(-15)
await drive_base.straight(350)
async def solve_statue_rebuild():
await drive_base.turn(-100)
await drive_base.straight(-80)
await left_arm.run_angle(500, -900)
await drive_base.straight(50)
await drive_base.straight(50)
await left_arm.run_angle(700, 250)
await drive_base.turn(30)
"""
Run#6
- Solve 2/3 Site Markings
- Run only if have time
- Purple Key
"""
async def Run6_7(): # experiment with ferris wheel for Site Markings
#solve_site_mark_1()
#solve_site_mark_2()
await drive_base.straight(640)
await drive_base.straight(-150)
await drive_base.turn(-8)
await left_arm.run_angle(500, -520)
await drive_base.straight(300)
await wait(50)
await left_arm.run_angle(500, 700)
#return to base
await drive_base.straight(-300)
drive_base.stop()
async def solve_site_mark_1():
await drive_base.straight(500)
await right_arm.run_angle(100, -10)
await wait(50)
await drive_base.straight(-300)
await drive_base.arc(-150, -140, None)
async def solve_site_mark_2():
await drive_base.straight(-300)
await wait(50)
await right_arm.run_angle(50, 50)
# Function to classify color based on HSV
def detect_color(h, s, v, reflected):
if reflected > 4:
if h < 4 or h > 350: # red
return "Red"
elif 3 < h < 40 and s > 70: # orange
return "Orange"
elif 47 < h < 56: # yellow
return "Yellow"
elif 70 < h < 160: # green - do it vertically not horizontally for accuracy
return "Green"
elif 195 < h < 198: # light blue
return "Light_Blue"
elif 210 < h < 225: # blue - do it vertically not horizontally for accuracy
return "Blue"
elif 260 < h < 350: # purple
return "Purple"
else:
return "Unknown"
return "Unknown"
async def main():
while True:
h, s, v = await color_sensor.hsv()
print(color_sensor.color())
print(h,s,v)
reflected = await color_sensor.reflection()
color = detect_color(h, s, v, reflected)
print(color)
if color == "Green":
print('Running Mission 1')
await Run1()
elif color == "Red":
print('Running Mission 2')
await Run2()
elif color == "Yellow":
print('Running Mission 3')
await Run3()
elif color == "Blue":
print('Running Mission 4')
await Run4()
elif color == "Orange":
print('Running Mission 5')
await Run5()
elif color == "Purple":
print('Running Mission 6_7')
await Run6_7()
elif color == "Light_Blue":
print("Running Mission 2_1")
await Run2_1()
else:
print(f"Unknown color detected (Hue: {h}, Sat: {s}, Val: {v})")
await wait(10)
# Run the main function
run_task(main())

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competition_codes/state/Updated state.py Normal file
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#Important Notice: All codes should be tested while the robot's battery is at 100%, and all updates must be made when the robot is at full charge.
import umath
from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor, ForceSensor
from pybricks.parameters import Button, Color, Direction, Port, Side, Stop
from pybricks.tools import run_task, multitask
from pybricks.tools import wait, StopWatch
from pybricks.robotics import DriveBase
from pybricks.hubs import PrimeHub
# Initialize hub and devices
hub = PrimeHub()
left_motor = Motor(Port.A, Direction.COUNTERCLOCKWISE)
right_motor = Motor(Port.B,Direction.CLOCKWISE) # Specify default direction
left_arm = Motor(Port.C, Direction.CLOCKWISE, [[12,36]],[[12,20,24]] ) # Specify default direction
right_arm = Motor(Port.D, Direction.CLOCKWISE,[[12,36],[12,20,24]]) #Added gear train list for gear ration
lazer_ranger = UltrasonicSensor(Port.E)
color_sensor = ColorSensor(Port.F)
# DriveBase configuration
WHEEL_DIAMETER = 68.8 # mm (adjust for your wheels)
AXLE_TRACK = 180 # mm (distance between wheels)
drive_base = DriveBase(left_motor, right_motor, WHEEL_DIAMETER, AXLE_TRACK)
drive_base.settings(600, 500, 300, 200)
drive_base.use_gyro(True)
"""
Debugging helps
"""
DEBUG = 1 # Enable when you want to show logs
# Example conversion function (adjust min/max values as needed for your hub)
async def get_battery_percentage(voltage_mV:float):
max_voltage = 8400.0 # max battery level https://assets.education.lego.com/v3/assets/blt293eea581807678a/bltb87f4ba8db36994a/5f8801b918967612e58a69a6/techspecs_techniclargehubrechargeablebattery.pdf?locale=en-us
min_voltage = 5000.0 # min battery level
percentage = ((float(voltage_mV) - min_voltage) / float(max_voltage - min_voltage) )* 100
return max(0, min(100, percentage)) # Ensure percentage is between 0 and 100
async def wait_button_release():
"""Wait for all buttons to be released"""
while hub.buttons.pressed():
await wait(500)
await wait(1000) # Debounce delay
WALL_DISTANCE = 200 # mm
async def drive_forward():
"""Drive forward continuously using DriveBase."""
drive_base.drive(1000,0)
async def drive_backward():
"""Drive forward continuously using DriveBase."""
drive_base.drive(400, 0)
async def monitor_distance():
"""Monitor ultrasonic sensor and stop when wall is detected."""
while True:
distance = await lazer_ranger.distance()
print('Distancing...',distance)
if distance < WALL_DISTANCE:
# Stop the drivebase
drive_base.stop()
print(f"Wall detected at {distance}mm!")
break
if distance is None:
continue
# Small delay to prevent overwhelming the sensor
await wait(50)
# Use this to set default
def set_default_speed():
drive_base.settings(600, 500, 300, 200)
# Use this to change drive base movement
def set_speed(straight_speed, st_acc, turn_speed, turn_acc):
drive_base.settings(straight_speed, st_acc, turn_speed, turn_acc)
"""
Run#1
- Removed forge and who lived here part
- What's on sale + Silo
- Green Key
"""
async def Run1():
# Fast approach to near-stall position
await left_arm.run_angle(2000, 180) # Fast movement upward
# Gentle stall detection (shorter distance = faster)
await left_arm.run_until_stalled(1500, duty_limit=15)
left_arm.reset_angle(0)
print(f"Initial left arm angle : {left_arm.angle()}")
await solve_whats_on_sale_v2()
await solve_silo()
# return to base
await drive_base.straight(-90)
#await drive_base.turn(-100)
await drive_base.arc(200,None,-300)
drive_base.stop()
async def solve_whats_on_sale():
right_arm.run_angle(500,30)
#Automated inconsistency
#left_arm.run_angle(500,-119.5)
left_arm.run_target(500,-121.5, Stop.HOLD)
print(f"Position left arm angle : {left_arm.angle()}")
await drive_base.straight(180)
await drive_base.turn(-40)
await drive_base.straight(335)
await left_arm.run_angle(500,-20)
await drive_base.straight(-100)
await drive_base.straight(60)
await left_arm.run_angle(500,50)
await drive_base.straight(-100)
left_arm.run_angle(500,-50)
await drive_base.turn(-20)
left_arm.run_angle(1000,180)
await drive_base.turn(15)
async def solve_whats_on_sale_v2():
right_arm.run_angle(500,30)
# Bring down left arm to position
await left_arm.run_angle(2000, -120)
#await left_arm.run_until_stalled(-500,duty_limit=15)
print(f"Position left arm angle : {left_arm.angle()}")
left_arm.reset_angle(0)
await drive_base.straight(180)
await drive_base.turn(-40)
await drive_base.straight(335)
await left_arm.run_angle(500,-20)
await drive_base.straight(-100)
await drive_base.straight(60)
await left_arm.run_angle(500,50)
await drive_base.straight(-100)
left_arm.run_angle(500,-50)
await drive_base.turn(-20)
left_arm.run_angle(1000,180)
await drive_base.turn(15)
async def solve_silo():
await drive_base.straight(-80)
await drive_base.turn(42)
await drive_base.straight(95)
SPEED = 10000 # speed in degree per second
SWING_ANGLE = 60 # the angle!
REBOUND_ADJ = 20
# Repeat this motion 4 times
for _ in range(4):
await right_arm.run_angle(SPEED,SWING_ANGLE, Stop.HOLD) # Swing up
await right_arm.run_angle(SPEED,(-1 * SWING_ANGLE),Stop.HOLD) # Swing down
right_arm.run_angle(4000,60, Stop.HOLD)
"""
Run#2
- This to solve forge, who lived here and heavy lifting combined
- Red Key
"""
async def Run2():
await solve_forge()
await solve_heavy_lifting()
await solve_who_lived_here()
# return to base
await drive_base.arc(-500,None,600)
drive_base.stop()
async def solve_forge():
await right_arm.run_target(50,50)
# await right_arm.run_angle(50,-30)
await drive_base.arc(350,113, None)
await drive_base.straight(20)
await drive_base.turn(-60)
await drive_base.straight(-47)
async def solve_heavy_lifting():
await right_arm.run_angle(2000,-160) # arm down
await wait(100)
await drive_base.turn(30) # turn right a little bit
await right_arm.run_angle(2000,160) #arm up
await drive_base.turn(-30) #reset position
async def solve_who_lived_here():
await drive_base.straight(50)
await drive_base.turn(-15)
await drive_base.straight(50)
await drive_base.turn(-25)
await drive_base.straight(-50)
await drive_base.turn(-40)
await drive_base.straight(50)
right_arm.run_angle(1000,-160)
await drive_base.turn(-60)
await right_arm.run_angle(2000,160)
"""
Run#2.1
- Alternate solution for Forge, Who lived here and Heavy Lifting combined
- Light Blue Key
- Different alignment
"""
async def Run2_1():
await solve_forge_straight()
await solve_heavy_lifting()
await solve_who_lived_here()
# return to base
await drive_base.arc(-500,None,600)
drive_base.stop()
async def solve_forge_straight():
await right_arm.run_target(50,50)
await right_arm.run_angle(50,-30)
await drive_base.straight(700)
# await drive_base.turn(-30)
# await drive_base.straight(20)
await drive_base.turn(-40)
await drive_base.straight(-30)
"""
Run#3
- Combined angler artifacts and tip the scale
- Yellow key
"""
async def Run3():
await solve_angler_artifacts()
await solve_tip_the_scale()
#cross over to red side
await multitask(
drive_forward(),
monitor_distance()
)
async def solve_angler_artifacts():
await drive_base.straight(870)
await drive_base.turn(-90,Stop.HOLD)
await drive_base.straight(45)
#Solve
drive_base.turn(-10)
await left_arm.run_angle(10000,-750)
await drive_base.straight(-130)
await drive_base.turn(67)
async def solve_tip_the_scale():
await drive_base.straight(-200)
await drive_base.straight(60)
await drive_base.turn(22)
"""
Run #4
- Solves the Mineshaft explorer + 2/3 Surface Brush + 1/3 Map Reveal
- Blue Key
"""
async def Run4():
await drive_base.straight(700)
await drive_base.turn(-18)
await drive_base.straight(120)
await drive_base.straight(-210)
await drive_base.turn(61)
await drive_base.straight(133)
await right_arm.run_angle(400, -200)
await drive_base.straight(90)
await right_arm.run_angle(100, 95)
await drive_base.straight(-875)
async def solve_brush_reveal():
await drive_base.straight(700)
await drive_base.turn(-20)
await drive_base.straight(110)
await drive_base.straight(-210)
async def solve_mineshaft_explorer():
await drive_base.turn(63)
await drive_base.straight(130)
await right_arm.run_angle(1000, -90)
await drive_base.straight(84)
await right_arm.run_angle(300, 90)
"""
Run#5
- Solves Salvage Operation + Statue Rebuild
- Orange Key
"""
async def Run5():
# Getting the sand down
await drive_base.straight(550)
await right_arm.run_angle(300,100)
await drive_base.straight(-75)
await right_arm.run_angle(300, -100)
# Shoving the boat into place
await drive_base.straight(300)
await drive_base.straight(-200)
await drive_base.turn(-15)
# Solving statue
await drive_base.straight(350)
await drive_base.turn(-104)
await drive_base.straight(-80)
await left_arm.run_angle(500, -300)
await drive_base.straight(120)
await drive_base.turn(5)
# Lift up statue
await left_arm.run_angle(500, 100, Stop.HOLD)
await drive_base.turn(18)
await drive_base.straight(-100)
await drive_base.turn(-90)
await drive_base.straight(900)
drive_base.stop()
async def solve_salvage_operation():
await drive_base.straight(500)
await right_arm.run_angle(300,500)
await drive_base.straight(-75)
await right_arm.run_angle(300, -900)
await drive_base.straight(-350)
await wait(1000)
await drive_base.straight(800)
await drive_base.straight(-200)
await drive_base.turn(-15)
await drive_base.straight(350)
async def solve_statue_rebuild():
await drive_base.turn(-100)
await drive_base.straight(-80)
await left_arm.run_angle(500, -900)
await drive_base.straight(50)
await drive_base.straight(50)
await left_arm.run_angle(700,200)
await drive_base.turn(30)
"""
Run#6
- Solve 2/3 Site Markings
- Run only if have time
- Purple Key
"""
async def Run6_7(): # experiment with ferris wheel for Site Markings
solve_site_mark_1()
solve_site_mark_2()
#return to base
await drive_base.straight(-300)
drive_base.stop()
async def solve_site_mark_1():
await drive_base.straight(500)
await right_arm.run_angle(100, -10)
await wait(50)
await drive_base.straight(-300)
await drive_base.arc(-150, -140, None)
async def solve_site_mark_2():
await drive_base.straight(-300)
await wait(50)
await right_arm.run_angle(50, 50)
async def Run10(): # experimental map reveal attachment
await drive_base.straight(600)
drive_base.settings(150, 750, 50, 500)
await drive_base.turn(-30)
await drive_base.straight(260)
left_arm.run_angle(300,218)
set_default_speed()
await drive_base.straight(-80)
await drive_base.turn(30)
await drive_base.straight(-300)
await drive_base.straight(400)
#await left_arm.run_angle(50,120)
await drive_base.straight(-200)
await left_arm.run_angle(300,-215)
await drive_base.straight(-600)
drive_base.stop()
async def Run11(): # experimental surface brushing attachment
await drive_base.straight(600)
drive_base.settings(150, 750, 50, 500)
await drive_base.turn(-30)
await drive_base.straight(250)
#left_arm.run_angle(300,218)
set_default_speed()
await drive_base.straight(-100)
await drive_base.turn(30)
await drive_base.straight(-190)
#await drive_base.straight(400)
#await left_arm.run_angle(50,120)
#await drive_base.straight(-200)
await left_arm.run_angle(300,-300)
await drive_base.straight(-600)
drive_base.stop()
async def Run12():
await drive_base.straight(900)
await drive_base.turn(83)
await left_arm.run_angle(3000, -300)
await right_arm.run_angle(1100, -180)
drive_base.settings(150, 50, 50, 50)
await drive_base.straight(120)
left_arm.reset_angle(0)
await left_arm.run_angle(50, 50)
await right_arm.run_angle(50, 90)
await drive_base.straight(-100)
drive_base.settings(950, 750, 750, 750)
await drive_base.turn(110)
await drive_base.straight(1000)
# Function to classify color based on HSV
def detect_color(h, s, v, reflected):
if reflected > 4:
if h < 4 or h > 350: # red
return "Red"
elif 3 < h < 40 and s > 70: # orange
return "Orange"
elif 47 < h < 56: # yellow
return "Yellow"
elif 70 < h < 160: # green - do it vertically not horizontally for accuracy
return "Green"
elif 195 < h < 198: # light blue
return "Light_Blue"
elif 210 < h < 225: # blue - do it vertically not horizontally for accuracy
return "Blue"
elif 260 < h < 350: # purple
return "Purple"
else:
return "Unknown"
return "Unknown"
async def main():
while True:
pressed = hub.buttons.pressed()
h, s, v = await color_sensor.hsv()
reflected = await color_sensor.reflection()
color = detect_color(h, s, v, reflected)
if DEBUG :
#print(color_sensor.color())
#print(h,s,v)
#print(color)
print(f"button pressed: {pressed}")
if color == "Green":
print('Running Mission 1')
await Run1()
elif color == "Red":
print('Running Mission 2')
await Run2()
elif color == "Yellow":
print('Running Mission 3')
await Run3()
elif color == "Blue":
print('Running Mission 4')
await Run4()
elif color == "Orange":
print('Running Mission 5')
await Run5()
elif color == "Purple":
print('Running Mission 6')
await Run11()
elif color == "Light_Blue":
print("Running Mission 2_1")
await Run12()
else:
print(f"Unknown color detected (Hue: {h}, Sat: {s}, Val: {v})")
#pass
# Show battery % for debugging
if Button.BLUETOOTH in pressed: # using bluetooth button here since away from color sensor
# Get the battery voltage in millivolts (mV)
battery_voltage_mV = hub.battery.voltage()
# Use the function with your voltage reading
percentage = await get_battery_percentage(float(battery_voltage_mV))
if DEBUG:
print(f"Battery voltage: {battery_voltage_mV} mV")
print(f"Battery level: {percentage:.3f}%")
print("FLL Robot System Ready!")
await hub.display.text(f"{percentage:.0f}")
break
elif pressed == None:
continue
await wait(10)
# Run the main function
run_task(main())

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competition_codes/state/run10_experimental.py Normal file
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await drive_base.straight(600)
drive_base.settings(150, 750, 50, 500)
await drive_base.turn(-30)
await drive_base.straight(260)
left_arm.run_angle(300,218)
set_default_speed()
await drive_base.straight(-80)
await drive_base.turn(30)
await drive_base.straight(-300)
await drive_base.straight(400)
#await left_arm.run_angle(50,120)
await drive_base.straight(-200)
await left_arm.run_angle(300,-215)
await drive_base.straight(-600)
drive_base.stop()

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competition_codes/state/run11_experimental.py Normal file
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await drive_base.straight(600)
drive_base.settings(150, 750, 50, 500)
await drive_base.turn(-30)
await drive_base.straight(250)
#left_arm.run_angle(300,218)
set_default_speed()
await drive_base.straight(-80)
await drive_base.turn(30)
await drive_base.straight(-180)
#await drive_base.straight(400)
#await left_arm.run_angle(50,120)
#await drive_base.straight(-200)
await left_arm.run_angle(300,-300)
await drive_base.straight(-600)
drive_base.stop()

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competition_codes/state/sunprarie_state_main.py Normal file
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#Important Notice: All codes should be tested while the robot's battery is at 100%, and all updates must be made when the robot is at full charge.
import umath
from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor, ForceSensor
from pybricks.parameters import Button, Color, Direction, Port, Side, Stop
from pybricks.tools import run_task, multitask
from pybricks.tools import wait, StopWatch
from pybricks.robotics import DriveBase
from pybricks.hubs import PrimeHub
# Initialize hub and devices
hub = PrimeHub()
left_motor = Motor(Port.A, Direction.COUNTERCLOCKWISE)
right_motor = Motor(Port.B,Direction.CLOCKWISE) # Specify default direction
left_arm = Motor(Port.C, Direction.CLOCKWISE, [[12,36]],[[12,20,24]] ) # Specify default direction
right_arm = Motor(Port.D, Direction.CLOCKWISE,[[12,36],[12,20,24]]) #Added gear train list for gear ration
lazer_ranger = UltrasonicSensor(Port.E)
color_sensor = ColorSensor(Port.F)
# DriveBase configuration
WHEEL_DIAMETER = 68.8 # mm (adjust for your wheels)
AXLE_TRACK = 180 # mm (distance between wheels)
drive_base = DriveBase(left_motor, right_motor, WHEEL_DIAMETER, AXLE_TRACK)
drive_base.settings(600, 500, 300, 200)
drive_base.use_gyro(True)
"""
Debugging helps
"""
DEBUG = 1 # Enable when you want to show logs
# Example conversion function (adjust min/max values as needed for your hub)
async def get_battery_percentage(voltage_mV:float):
max_voltage = 8400.0 # max battery level https://assets.education.lego.com/v3/assets/blt293eea581807678a/bltb87f4ba8db36994a/5f8801b918967612e58a69a6/techspecs_techniclargehubrechargeablebattery.pdf?locale=en-us
min_voltage = 5000.0 # min battery level
percentage = ((float(voltage_mV) - min_voltage) / float(max_voltage - min_voltage) )* 100
return max(0, min(100, percentage)) # Ensure percentage is between 0 and 100
async def wait_button_release():
"""Wait for all buttons to be released"""
while hub.buttons.pressed():
await wait(500)
await wait(1000) # Debounce delay
WALL_DISTANCE = 200 # mm
async def drive_forward():
"""Drive forward continuously using DriveBase."""
drive_base.drive(1000,0)
async def drive_backward():
"""Drive forward continuously using DriveBase."""
drive_base.drive(400, 0)
async def monitor_distance():
"""Monitor ultrasonic sensor and stop when wall is detected."""
while True:
distance = await lazer_ranger.distance()
print('Distancing...',distance)
if distance < WALL_DISTANCE:
# Stop the drivebase
drive_base.stop()
print(f"Wall detected at {distance}mm!")
break
if distance is None:
continue
# Small delay to prevent overwhelming the sensor
await wait(50)
# Use this to set default
def set_default_speed():
drive_base.settings(600, 500, 300, 200)
# Use this to change drive base movement
def set_speed(straight_speed, st_acc, turn_speed, turn_acc):
drive_base.settings(straight_speed, st_acc, turn_speed, turn_acc)
"""
Run#1
- Removed forge and who lived here part
- What's on sale + Silo
- Green Key
"""
async def Run1():
# Fast approach to near-stall position
await left_arm.run_angle(2000, -190) # Fast movement downward
# Gentle stall detection (shorter distance = faster)
await left_arm.run_until_stalled(-1500, duty_limit=15)
left_arm.reset_angle(0)
print(f"Initial left arm angle : {left_arm.angle()}")
await solve_whats_on_sale_v3()
await solve_silo()
# return to base
await drive_base.straight(-90)
#await drive_base.turn(-100)
await drive_base.arc(200,None,-300)
drive_base.stop()
async def solve_whats_on_sale_v3():
right_arm.run_angle(500,30)
#Automated inconsistency
#left_arm.run_angle(500,-119.5)
left_arm.run_target(500,70, Stop.HOLD)
print(f"Position left arm angle : {left_arm.angle()}")
await drive_base.straight(180)
await drive_base.turn(-40)
await drive_base.straight(335)
await left_arm.run_angle(500,-20)
await drive_base.straight(-100)
await drive_base.straight(60)
await left_arm.run_angle(500,50)
await drive_base.straight(-100)
left_arm.run_angle(500,-50)
await drive_base.turn(-20)
left_arm.run_angle(1000,180)
await drive_base.turn(15)
async def solve_whats_on_sale_v2():
right_arm.run_angle(500,30)
# Bring down left arm to position
await left_arm.run_angle(2000, -120)
#await left_arm.run_until_stalled(-500,duty_limit=15)
print(f"Position left arm angle : {left_arm.angle()}")
left_arm.reset_angle(0)
await drive_base.straight(180)
await drive_base.turn(-40)
await drive_base.straight(335)
await left_arm.run_angle(500,-20)
await drive_base.straight(-100)
await drive_base.straight(60)
await left_arm.run_angle(500,50)
await drive_base.straight(-100)
left_arm.run_angle(500,-50)
await drive_base.turn(-20)
left_arm.run_angle(1000,180)
await drive_base.turn(15)
async def solve_silo():
await drive_base.straight(-80)
await drive_base.turn(42)
await drive_base.straight(95)
SPEED = 10000 # speed in degree per second
SWING_ANGLE = 60 # the angle!
REBOUND_ADJ = 20
# Repeat this motion 4 times
for _ in range(4):
await right_arm.run_angle(SPEED,SWING_ANGLE, Stop.HOLD) # Swing up
await right_arm.run_angle(SPEED,(-1 * SWING_ANGLE),Stop.HOLD) # Swing down
right_arm.run_angle(4000,60, Stop.HOLD)
"""
Run#2
- This to solve forge, who lived here and heavy lifting combined
- Red Key
"""
async def Run2():
await solve_forge()
await solve_heavy_lifting()
await solve_who_lived_here()
# return to base
await drive_base.arc(-500,None,600)
drive_base.stop()
async def solve_forge():
await right_arm.run_target(50,50)
# await right_arm.run_angle(50,-30)
await drive_base.arc(350,113, None)
await drive_base.straight(20)
await drive_base.turn(-60)
await drive_base.straight(-47)
async def solve_heavy_lifting():
await right_arm.run_angle(2000,-160) # arm down
await wait(100)
await drive_base.turn(30) # turn right a little bit
await right_arm.run_angle(2000,160) #arm up
await drive_base.turn(-30) #reset position
async def solve_who_lived_here():
await drive_base.straight(50)
await drive_base.turn(-15)
await drive_base.straight(50)
await drive_base.turn(-25)
await drive_base.straight(-50)
await drive_base.turn(-40)
await drive_base.straight(50)
right_arm.run_angle(1000,-160)
await drive_base.turn(-60)
await right_arm.run_angle(2000,160)
"""
Run#2.1
- Alternate solution for Forge, Who lived here and Heavy Lifting combined
- Light Blue Key
- Different alignment
"""
async def Run2_1():
await solve_forge_straight()
await solve_heavy_lifting()
await solve_who_lived_here()
# return to base
await drive_base.arc(-500,None,600)
drive_base.stop()
async def solve_forge_straight():
await right_arm.run_target(50,50)
await right_arm.run_angle(50,-30)
await drive_base.straight(700)
# await drive_base.turn(-30)
# await drive_base.straight(20)
await drive_base.turn(-40)
await drive_base.straight(-30)
"""
Run#3
- Combined angler artifacts and tip the scale
- Yellow key
"""
async def Run3():
await solve_angler_artifacts()
await solve_tip_the_scale()
#cross over to red side
await multitask(
drive_forward(),
monitor_distance()
)
async def solve_angler_artifacts():
await drive_base.straight(870)
await drive_base.turn(-90,Stop.HOLD)
await drive_base.straight(45)
#Solve
drive_base.turn(-10)
await left_arm.run_angle(10000,-750)
await drive_base.straight(-130)
await drive_base.turn(67)
async def solve_tip_the_scale():
await drive_base.straight(-200)
await drive_base.straight(60)
await drive_base.turn(22)
"""
Run #4
- Solves the Mineshaft explorer + 2/3 Surface Brush + 1/3 Map Reveal
- Blue Key
"""
async def Run4():
await drive_base.straight(700)
await drive_base.turn(-18)
await drive_base.straight(120)
await drive_base.straight(-210)
await drive_base.turn(61)
await drive_base.straight(133)
await right_arm.run_angle(400, -200)
await drive_base.straight(90)
await right_arm.run_angle(100, 95)
await drive_base.straight(-875)
async def solve_brush_reveal():
await drive_base.straight(700)
await drive_base.turn(-20)
await drive_base.straight(110)
await drive_base.straight(-210)
async def solve_mineshaft_explorer():
await drive_base.turn(63)
await drive_base.straight(130)
await right_arm.run_angle(1000, -90)
await drive_base.straight(84)
await right_arm.run_angle(300, 90)
"""
Run#5
- Solves Salvage Operation + Statue Rebuild
- Orange Key
"""
async def Run5():
# Getting the sand down
await drive_base.straight(550)
await right_arm.run_angle(300,100)
await drive_base.straight(-75)
await right_arm.run_angle(300, -100)
# Shoving the boat into place
await drive_base.straight(300)
await drive_base.straight(-200)
await drive_base.turn(-15)
# Solving statue
await drive_base.straight(350)
await drive_base.turn(-104)
await drive_base.straight(-80)
await left_arm.run_angle(500, -300)
await drive_base.straight(120)
await drive_base.turn(5)
# Lift up statue
await left_arm.run_angle(500, 100, Stop.HOLD)
await drive_base.turn(18)
await drive_base.straight(-100)
await drive_base.turn(-90)
await drive_base.straight(900)
drive_base.stop()
async def solve_salvage_operation():
await drive_base.straight(500)
await right_arm.run_angle(300,500)
await drive_base.straight(-75)
await right_arm.run_angle(300, -900)
await drive_base.straight(-350)
await wait(1000)
await drive_base.straight(800)
await drive_base.straight(-200)
await drive_base.turn(-15)
await drive_base.straight(350)
async def solve_statue_rebuild():
await drive_base.turn(-100)
await drive_base.straight(-80)
await left_arm.run_angle(500, -900)
await drive_base.straight(50)
await drive_base.straight(50)
await left_arm.run_angle(700,200)
await drive_base.turn(30)
"""
Run#6
- Solve 2/3 Site Markings
- Run only if have time
- Purple Key
"""
async def Run6_7(): # experiment with ferris wheel for Site Markings
solve_site_mark_1()
solve_site_mark_2()
#return to base
await drive_base.straight(-300)
drive_base.stop()
async def solve_site_mark_1():
await drive_base.straight(500)
await right_arm.run_angle(100, -10)
await wait(50)
await drive_base.straight(-300)
await drive_base.arc(-150, -140, None)
async def solve_site_mark_2():
await drive_base.straight(-300)
await wait(50)
await right_arm.run_angle(50, 50)
async def Run10(): # experimental map reveal attachment
await drive_base.straight(600)
drive_base.settings(150, 750, 50, 500)
await drive_base.turn(-30)
await drive_base.straight(260)
left_arm.run_angle(300,218)
set_default_speed()
await drive_base.straight(-80)
await drive_base.turn(30)
await drive_base.straight(-300)
await drive_base.straight(400)
#await left_arm.run_angle(50,120)
await drive_base.straight(-200)
await left_arm.run_angle(300,-215)
await drive_base.straight(-600)
drive_base.stop()
async def Run11(): # experimental surface brushing attachment
await drive_base.straight(600)
drive_base.settings(150, 750, 50, 500)
await drive_base.turn(-30)
await drive_base.straight(250)
#left_arm.run_angle(300,218)
set_default_speed()
await drive_base.straight(-230)
await drive_base.turn(30)
#await drive_base.straight(400)
#await left_arm.run_angle(50,120)
#await drive_base.straight(-200)
#await drive_base.straight(-80)
#await left_arm.run_angle(300, -75)
await drive_base.arc(-650,None,-800)
drive_base.stop()
async def Run12():
await drive_base.straight(900)
await drive_base.turn(83)
await left_arm.run_angle(3000, -300)
await right_arm.run_angle(1100, -180)
drive_base.settings(150, 50, 50, 50)
await drive_base.straight(120)
left_arm.reset_angle(0)
await left_arm.run_angle(50, 50)
await right_arm.run_angle(50, 90)
await drive_base.straight(-100)
drive_base.settings(950, 750, 750, 750)
await drive_base.turn(110)
await drive_base.straight(1000)
# Function to classify color based on HSV
def detect_color(h, s, v, reflected):
if reflected > 4:
if h < 4 or h > 350: # red
return "Red"
elif 3 < h < 40 and s > 70: # orange
return "Orange"
elif 47 < h < 56: # yellow
return "Yellow"
elif 70 < h < 160: # green - do it vertically not horizontally for accuracy
return "Green"
elif 195 < h < 198: # light blue
return "Light_Blue"
elif 210 < h < 225: # blue - do it vertically not horizontally for accuracy
return "Blue"
elif 260 < h < 350: # purple
return "Purple"
else:
return "Unknown"
return "Unknown"
async def main():
while True:
pressed = hub.buttons.pressed()
h, s, v = await color_sensor.hsv()
reflected = await color_sensor.reflection()
color = detect_color(h, s, v, reflected)
if DEBUG :
#print(color_sensor.color())
#print(h,s,v)
#print(color)
print(f"button pressed: {pressed}")
if color == "Green":
print('Running Mission 1')
await Run1()
elif color == "Red":
print('Running Mission 2')
await Run2()
elif color == "Yellow":
print('Running Mission 3')
await Run3()
elif color == "Blue":
print('Running Mission 4')
await Run4()
elif color == "Orange":
print('Running Mission 5')
await Run5()
elif color == "Purple":
print('Running Mission 6')
await Run11()
elif color == "Light_Blue":
print("Running Mission 2_1")
await Run12()
else:
print(f"Unknown color detected (Hue: {h}, Sat: {s}, Val: {v})")
#pass
# Show battery % for debugging
if Button.BLUETOOTH in pressed: # using bluetooth button here since away from color sensor
# Get the battery voltage in millivolts (mV)
battery_voltage_mV = hub.battery.voltage()
# Use the function with your voltage reading
percentage = await get_battery_percentage(float(battery_voltage_mV))
if DEBUG:
print(f"Battery voltage: {battery_voltage_mV} mV")
print(f"Battery level: {percentage:.3f}%")
print("FLL Robot System Ready!")
await hub.display.text(f"{percentage:.0f}")
break
elif pressed == None:
continue
await wait(10)
# Run the main function
run_task(main())

0
twist_scrimmage.py → competition_codes/twist_scrimmage/twist_scrimmage.py
View File

40
config.py
View File

@@ -1,40 +0,0 @@
# config.py - Robot configuration shared across all modules
from pybricks.hubs import PrimeHub
from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor
from pybricks.parameters import Port
# Initialize hub
hub = PrimeHub()
# Robot hardware configuration
ROBOT_CONFIG = {
# Drive motors
'left_motor': Motor(Port.A),
'right_motor': Motor(Port.B),
# Attachment motors
'attachment_motor': Motor(Port.C),
'lift_motor': Motor(Port.D),
# Sensors
#'color_left': ColorSensor(Port.E),
'color_back': ColorSensor(Port.F),
'ultrasonic': UltrasonicSensor(Port.E),
# Hub reference
'hub': hub
}
# Speed and distance constants
SPEEDS = {
'FAST': 400,
'NORMAL': 250,
'SLOW': 100,
'PRECISE': 50
}
DISTANCES = {
'TILE_SIZE': 300, # mm per field tile
'ROBOT_LENGTH': 180, # mm
'ROBOT_WIDTH': 140 # mm
}

25
missions/M8_5.py
View File

@@ -21,20 +21,25 @@ drive_base.use_gyro(True)
async def main():
right_arm.run_angle(1000,450)
left_arm.run_angle(500,-80)
left_arm.run_angle(500,-90)
await drive_base.straight(200)
await drive_base.turn(-40)
await drive_base.straight(325)
await left_arm.run_angle(500,80)
await left_arm.run_angle(500,90)
await drive_base.straight(-100)
await drive_base.straight(50)
await left_arm.run_angle(500,-170)
await left_arm.run_angle(500,-180)
await drive_base.straight(-270)
await drive_base.turn(40)
await drive_base.straight(135)
await drive_base.straight(-90)
left_arm.run_angle(500,180)
await drive_base.turn(-20)
await drive_base.turn(15)
await drive_base.straight(-173)
await drive_base.turn(45)
await drive_base.straight(120)
left_arm.run_angle(1000,-670)
await right_arm.run_angle(5000,-450, Stop.HOLD)
@@ -45,7 +50,7 @@ async def main():
right_arm.run_angle(5000,450, Stop.HOLD)
await drive_base.turn(-35)
await drive_base.straight(300)
await drive_base.straight(297)
await drive_base.turn(63)
await drive_base.straight(170)
@@ -53,10 +58,8 @@ async def main():
await drive_base.straight(87)
await drive_base.turn(-15)
await drive_base.straight(-120)
await drive_base.straight(-90)
await drive_base.turn(-100)
await drive_base.straight(300)
await drive_base.turn(-45)
await drive_base.straight(500)
await drive_base.arc(-500,None,600)
run_task(main())

38
missions/New_MapReveal/New_MapReveal_Mineshaft.py Normal file
View File

@@ -0,0 +1,38 @@
from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor, ForceSensor
from pybricks.parameters import Button, Color, Direction, Port, Side, Stop
from pybricks.tools import run_task, multitask
from pybricks.tools import wait, StopWatch
from pybricks.robotics import DriveBase
from pybricks.hubs import PrimeHub
# Initialize hub and devices
hub = PrimeHub()
left_motor = Motor(Port.A, Direction.COUNTERCLOCKWISE)
right_motor = Motor(Port.B)
left_arm = Motor(Port.C)
right_arm = Motor(Port.D)
lazer_ranger = UltrasonicSensor(Port.E)
color_sensor = ColorSensor(Port.F)
# DriveBase configuration
WHEEL_DIAMETER = 68.8 # mm (adjust for your wheels)
AXLE_TRACK = 180 # mm (distance between wheels)
drive_base = DriveBase(left_motor, right_motor, WHEEL_DIAMETER, AXLE_TRACK)
drive_base.settings(600, 500, 300, 200)
drive_base.use_gyro(True)
WALL_DISTANCE = 200 # mm
async def main():
await drive_base.straight(700)
await drive_base.turn(-20)
await drive_base.straight(110)
await drive_base.straight(-220)
await drive_base.turn(63)
await drive_base.straight(130)
await right_arm.run_angle(1000, -1200)
await drive_base.straight(84)
await right_arm.run_angle(300, 1200)
await drive_base.straight(-875)
run_task(main())

1
final/1main.py → old_combined/1main.py
View File

@@ -1,4 +1,3 @@
from pybricks.hubs import PrimeHub
from pybricks.pupdevices import Motor, ColorSensor
from pybricks.parameters import Port, Stop, Color, Direction

1
final/2main.py → old_combined/2main.py
View File

@@ -1,4 +1,3 @@
from pybricks.hubs import PrimeHub
from pybricks.pupdevices import Motor, ColorSensor
from pybricks.parameters import Port, Stop, Color, Direction

0
final/3main.py → old_combined/3main.py
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0
final/4main.py → old_combined/4main.py
View File

0
final/main5.py → old_combined/main5.py
View File

303
test_10_17_2025.py
View File

@@ -1,303 +0,0 @@
# Stuff from 10/15/2025
# Atharv trying with no avail to add more colors to the color sensor logic 😭😭😭😭😭😭😭
from pybricks.hubs import PrimeHub
from pybricks.pupdevices import Motor, ColorSensor
from pybricks.parameters import Port, Stop, Color, Direction
from pybricks.robotics import DriveBase
from pybricks.tools import wait, StopWatch, multitask, run_task
hub = PrimeHub()
left_motor = Motor(Port.A, Direction.COUNTERCLOCKWISE)
right_motor = Motor(Port.B)
left_arm = Motor(Port.C)#, Direction.COUNTERCLOCKWISE)
right_arm = Motor(Port.D)
drive_base = DriveBase(left_motor, right_motor, wheel_diameter=68.8, axle_track=180)
drive_base.settings(550,700,100,100)
drive_base.use_gyro(True)
color_sensor = ColorSensor(Port.F)
Color.ORANGE = Color(28, 61, 61)
Color.BLUE = Color(230,100,100)
Color.YELLOW = Color(37, 85, 95)
Color.PURPLE = Color(326, 60, 87)
color_sensor.detectable_colors([Color.ORANGE, Color.BLUE, Color.GREEN, Color.WHITE, Color.RED, Color.YELLOW, Color.NONE, Color.PURPLE])
hub.speaker.volume(50) # Set the volume of the speaker
color_sensor.detectable_colors()
# Celebration sound types
class CelebrationSound:
VICTORY_FANFARE = 0
LEVEL_UP = 1
SUCCESS_CHIME = 2
TA_DA = 3
POWER_UP = 4
RICKROLL_INSPIRED = 5
async def play_victory_fanfare():
"""Classic victory fanfare"""
notes = [
(262, 200), # C4
(262, 200), # C4
(262, 200), # C4
(349, 600), # F4
]
for freq, duration in notes:
await hub.speaker.beep(freq, duration)
await wait(50)
async def play_level_up():
"""Upward scale for level completion"""
notesold = [
(262, 100), # C4
(294, 100), # D4
(330, 100), # E4
(349, 100), # F4
(392, 100), # G4
(440, 100), # A4
(494, 100), # B4
(523, 300), # C5
]
notes = [
(277, 100),
(330, 100),
(277, 100),
(554, 100),
(277, 100),
(413, 100),
(330, 100),
(277, 100),
(413, 100),
(277, 100),
(554, 100),
(413, 100),
(277, 100),
(413, 100),
(554, 100),
(413, 100)
]
for freq, duration in notes:
await hub.speaker.beep(freq, duration)
#await wait(20)
async def play_success_chime():
"""Simple success notification"""
notes = [
(523, 150), # C5
(659, 150), # E5
(784, 300), # G5
]
for freq, duration in notes:
await hub.speaker.beep(freq, duration)
await wait(50)
async def play_ta_da():
"""Classic "ta-da!" sound"""
notes = [
(392, 200), # G4
(523, 400), # C5
]
for freq, duration in notes:
await hub.speaker.beep(freq, duration)
await wait(100)
async def play_power_up():
"""Rising power-up sound"""
for freq in range(200, 800, 50):
await hub.speaker.beep(freq, 50)
await wait(10)
await hub.speaker.beep(1000, 200)
async def play_rickroll_inspired():
"""Fun 80s-style dance beat inspired sound"""
# Upbeat bouncy rhythm
pattern = [
(392, 200), (440, 200), (494, 200), (523, 200),
(440, 200), (392, 200), (349, 200), (392, 300),
(440, 200), (392, 200), (349, 200), (330, 400),
]
for freq, duration in pattern:
await hub.speaker.beep(freq, duration)
await wait(50)
async def celebrate_mission_complete(sound_type=CelebrationSound.SUCCESS_CHIME):
"""
Main celebration function to call after completing a mission.
Plays a sound and shows light animation.
Args:
sound_type: CelebrationSound enum value (default: SUCCESS_CHIME)
"""
# Light show
hub.light.on(Color.GREEN)
# Play the selected celebration sound
if sound_type == CelebrationSound.VICTORY_FANFARE:
await play_victory_fanfare()
elif sound_type == CelebrationSound.LEVEL_UP:
await play_level_up()
elif sound_type == CelebrationSound.SUCCESS_CHIME:
await play_success_chime()
elif sound_type == CelebrationSound.TA_DA:
await play_ta_da()
elif sound_type == CelebrationSound.POWER_UP:
await play_power_up()
elif sound_type == CelebrationSound.RICKROLL_INSPIRED:
await play_rickroll_inspired()
else:
await play_success_chime() # Default fallback
# Blink the light
for _ in range(3):
hub.light.off()
await wait(100)
hub.light.on(Color.GREEN)
await wait(100)
hub.light.off()
async def Run1():
left_arm.run_angle(1000, -300)
right_arm.run_angle(1000,500)
await drive_base.straight(320)
await right_arm.run_angle(5000,-500, Stop.HOLD)
await right_arm.run_angle(5000,500, Stop.HOLD)
await right_arm.run_angle(5000,-500, Stop.HOLD)
await right_arm.run_angle(5000,500, Stop.HOLD)
await right_arm.run_angle(5000,-500, Stop.HOLD)
await drive_base.turn(-20)
await drive_base.straight(277)
await drive_base.turn(20)
await drive_base.straight(65)
await drive_base.turn(-30)
right_arm.run_angle(50,500)
await drive_base.turn(45)
await drive_base.straight(-145)
await drive_base.turn(-60)
await drive_base.straight(90)
await left_arm.run_angle(1000, 450)
await drive_base.straight(-145)
await left_arm.run_angle(1000,-450)
await drive_base.straight(10)
await drive_base.turn(35)
await drive_base.straight(-700)
async def Run2():
await drive_base.straight(200)
await drive_base.turn(-20)
await drive_base.straight(525)
await drive_base.turn(60)
await drive_base.straight(50)
await right_arm.run_angle(2000,1000)
await drive_base.straight(-50)
await drive_base.turn(45)
await drive_base.straight(50)
await right_arm.run_angle(350,-1000)
await drive_base.straight(-100)
await drive_base.turn(-100)
await drive_base.straight(-750)
async def Run3():
await drive_base.straight(920)
await drive_base.turn(-90)
await drive_base.straight(60)
drive_base.turn(-10)
await left_arm.run_angle(10000,-4000)
await drive_base.straight(-110)
await drive_base.turn(90)
await drive_base.straight(2000)
async def Run4():
await drive_base.straight(519)
await drive_base.straight(519)
await arm_motor_left.run_angle(-10000, 300)
await arm_motor_left.run_angle(10000, 600)
await drive_base.straight(160)
await drive_base.turn(-30)
await drive_base.straight(50)
await arm_motor.run_angle(3000, 3000)
await drive_base.straight(-150)
await drive_base.turn(135)
await drive_base.straight(50)
await arm_motor.run_angle(10000, -3000)
await drive_base.straight(-100)
await drive_base.turn(-54)
await arm_motor.run_angle(10000, -3000)
await drive_base.straight(250)
await drive_base.turn(-5)
await arm_motor.run_angle(10000, 7000)
await drive_base.straight(-50)
await drive_base.turn(68)
await arm_motor.run_angle(10000, -6000)
await drive_base.straight(200)
await arm_motor.run_angle(10000, 4000)
await drive_base.turn(-40)
await arm_motor.run_angle(10000, 7000)
async def Run5():
await drive_base.straight(420)
await right_arm.run_angle(300,-100)
await drive_base.straight(-100)
await right_arm.run_angle(300, 100)
await drive_base.straight(-350)
async def Run6():
left_arm.run_angle(500,200)
right_arm.run_angle(500,200)
await drive_base.straight(70)
await drive_base.turn(-55)
await drive_base.straight(900)
await drive_base.turn(92.5)
await drive_base.straight(75)
await drive_base.straight(21)
await right_arm.run_angle(500,-250)
await right_arm.run_angle(500,250)
await drive_base.turn(55)
await left_arm.run_angle(300,-400)
await drive_base.turn(46.5)
await drive_base.turn(-40)
await drive_base.straight(900)
async def main():
while True:
#await celebrate_mission_complete(CelebrationSound.LEVEL_UP)
color_reflected_percent = await color_sensor.reflection()
print(color_reflected_percent)
color_detected = await color_sensor.color()
print(f'Detected color: {color_detected.h}, {color_detected.s}, {color_detected.v}')
if color_reflected_percent > 1:
if color_detected == Color.GREEN:
print('Running Mission 1')
await Run1()
#await celebrate_mission_complete(CelebrationSound.VICTORY_FANFARE)
elif color_detected == Color.WHITE:
print('Running Mission 2')
await Run2()
#await celebrate_mission_complete(CelebrationSound.RICKROLL_INSPIRED)
elif color_detected == Color.YELLOW:
print('Running Mission 3')
await Run3()
#await celebrate_mission_complete(CelebrationSound.SUCCESS_CHIME )
elif color_detected == Color.BLUE:
print('Running Mission 4')
await Run4()
#await celebrate_mission_complete(CelebrationSound.POWER_UP)
elif color_detected == Color.ORANGE:
print('Running Mission 5')
await Run5()
#await celebrate_mission_complete(CelebrationSound.LEVEL_UP)
elif color_detected == Color.PURPLE:
print('Running Mission 6 (this is ayaan\'s code)')
await Run6()
#await celebrate_mission_complete(CelebrationSound.LEVEL_UP)
else:
hub.light.off()
left_motor.stop()
right_motor.stop()
await wait(1000) #prevent loop from iterating fast
# Main execution loop
run_task(main())

29
utils/FINAL_STARTER_BLANK_CODE.py Normal file
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from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor, ForceSensor
from pybricks.parameters import Button, Color, Direction, Port, Side, Stop
from pybricks.tools import run_task, multitask
from pybricks.tools import wait, StopWatch
from pybricks.robotics import DriveBase
from pybricks.hubs import PrimeHub
# Initialize hub and devices
hub = PrimeHub()
left_motor = Motor(Port.A, Direction.COUNTERCLOCKWISE)
right_motor = Motor(Port.B)
left_arm = Motor(Port.C)
right_arm = Motor(Port.D)
lazer_ranger = UltrasonicSensor(Port.E)
color_sensor = ColorSensor(Port.F)
# DriveBase configuration
WHEEL_DIAMETER = 68.8 # mm
AXLE_TRACK = 180 # mm
drive_base = DriveBase(left_motor, right_motor, WHEEL_DIAMETER, AXLE_TRACK)
drive_base.settings(600, 500, 300, 200)
drive_base.use_gyro(True)
WALL_DISTANCE = 200 # mm
async def main():
# Your code goes here
run_task(main())

41
utils/color_sensor_navi.py
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from pybricks.hubs import PrimeHub
from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor, ForceSensor
from pybricks.parameters import Button, Color, Direction, Port, Side, Stop
from pybricks.robotics import DriveBase
from pybricks.tools import wait, StopWatch
hub = PrimeHub()
# Robot hardware configurationROBOT_CONFIG = { # Drive motors 'left_motor': Motor(Port.A), 'right_motor': Motor(Port.B), # Attachment motors 'attachment_motor': Motor(Port.C), 'lift_motor': Motor(Port.D), # Sensors 'color_left': ColorSensor(Port.E), 'color_right': ColorSensor(Port.F), 'ultrasonic': UltrasonicSensor(Port.S1), # Hub reference 'hub': hub}# Speed and distance constantsSPEEDS = { 'FAST': 400, 'NORMAL': 250, 'SLOW': 100, 'PRECISE': 50}DISTANCES = { 'TILE_SIZE': 300, # mm per field tile 'ROBOT_LENGTH': 180, # mm 'ROBOT_WIDTH': 140 # mm}
def mission_run_1():
print('Running missions in Run 1')
def mission_run_2():
print('Running missions in Run 2')
def mission_run_3():
print('Running missions in Run 3')
# In main.py - sensor-based navigation
def main(self):
"""Use color sensor to select runs"""
print("Place colored object in front of sensor:")
print("RED=Run1, GREEN=Run2, BLUE=Run3, YELLOW=Test")
while True:
color = ROBOT_CONFIG['color_left'].color()
if color == Color.RED:
mission_run_1()
break
elif color == Color.GREEN:
mission_run_2()
break
elif color == Color.BLUE:
mission_run_3()
break
elif color == Color.YELLOW:
self.test_mode()
break
wait(1000)
main()

13
utils/constants.py
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#Speed and distance constants
SPEEDS = {
'FAST': 400,
'NORMAL': 250,
'SLOW': 100,
'PRECISE': 50
}
DISTANCES = {
'TILE_SIZE': 300, # mm per field tile
'ROBOT_LENGTH': 180, # mm
'ROBOT_WIDTH': 140 # mm
}

36
utils/starter_drivebase_code.py
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from pybricks.hubs import PrimeHub
from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor, ForceSensor
from pybricks.parameters import Button, Color, Direction, Port, Side, Stop
from pybricks.robotics import DriveBase
from pybricks.tools import wait, StopWatch
hub = PrimeHub()
# Initialize both motors. In this example, the motor on the
# left must turn counterclockwise to make the robot go forward.
left_motor = Motor(Port.A, Direction.COUNTERCLOCKWISE)
right_motor = Motor(Port.B)
arm_motor = Motor(Port.E, Direction.CLOCKWISE)
arm_motor.run_angle(299,90, Stop.HOLD)
# Initialize the drive base. In this example, the wheel diameter is 56mm.
# The distance between the two wheel-ground contact points is 112mm.
drive_base = DriveBase(left_motor, right_motor, wheel_diameter=54, axle_track=112)
print('The default settings are: ' + str(drive_base.settings()))
drive_base.settings(100,1000,166,750)
# Optionally, uncomment the line below to use the gyro for improved accuracy.
drive_base.use_gyro(True)
# Drive forward by 500mm (half a meter).
drive_base.straight(500)
# Turn around clockwise by 180 degrees.
drive_base.turn(180)
# Drive forward again to get back to the start.
drive_base.straight(500)
# Turn around counterclockwise.
drive_base.turn(-180)
arm_motor.run_angle(299,-90, Stop.HOLD)

69
utils/tests/colorsensortest.py
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from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor, ForceSensor
from pybricks.parameters import Button, Color, Direction, Port, Side, Stop
from pybricks.tools import run_task, multitask
from pybricks.tools import wait, StopWatch
from pybricks.robotics import DriveBase
from pybricks.hubs import PrimeHub
# Initialize hub and devices
hub = PrimeHub()
color_sensor = ColorSensor(Port.F)
# Color Settings
# https://docs.pybricks.com/en/latest/parameters/color.html
print("Default Detected Colors:", color_sensor.detectable_colors())
# Custom color Hue, Saturation, Brightness value for Lego bricks
Color.MAGENTA = Color(315,100,60)
Color.BLUE = Color(240,100,100)
Color.CYAN = Color(180,100,100)
Color.RED = Color(350, 100, 100)
LEGO_BRICKS_COLOR = [
Color.BLUE,
Color.GREEN,
Color.WHITE,
Color.RED,
Color.YELLOW,
Color.MAGENTA,
Color.NONE
]
magenta_counter = 0
stable_color = None
real_color = None
#Update Detectable colors
color_sensor.detectable_colors(LEGO_BRICKS_COLOR)
print(f'Yellow:{Color.YELLOW} : {Color.YELLOW.h}, {Color.YELLOW.s}, {Color.YELLOW.v}')
print("Updated Detected Colors:", color_sensor.detectable_colors())
async def main():
while True:
global magenta_counter, stable_color, real_color
color_reflected_percent = await color_sensor.reflection()
print("Reflection: ", color_reflected_percent)
if color_reflected_percent > 15:
color_detected = await color_sensor.color()
if color_detected == Color.MAGENTA:
magenta_counter += 1
else:
magenta_counter = 0
stable_color = color_detected
# Only accept magenta if it's been stable for a while - usually triggers before other colors so we gotta do this :|
if magenta_counter > 10:
stable_color = Color.MAGENTA
if stable_color != Color.MAGENTA:
stable_color = await color_sensor.color()
real_color = stable_color
#if(color_detected != Color.NONE):
# return
print("Magenta counter: ", magenta_counter)
if real_color is not None:
print(f'Detected color: {real_color} : {real_color.h}, {real_color.s}, {real_color.v}')
else:
print("No valid color detected yet.")
await wait(50)
run_task(main())