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compare: Arcmyx:60384d4367648b48fd861f96102786a6497ade59
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Arcmyx:1.0.0

8 Commits
dev ... 60384d4367

Author SHA1 Message Date
Atharv Nagavarapu
60384d4367 Merge pull request 'dev' (#11) from dev into main 
Reviewed-on: Arcmyx/pynamics-pybricks-utils#11
 2025-12-11 14:29:29 +00:00
Atharv Nagavarapu
a91e79a02a Merge pull request 'dev' (#10) from dev into main 
Reviewed-on: Arcmyx/pynamics-pybricks-utils#10
 2025-12-11 14:27:04 +00:00
Atharv Nagavarapu
ffd89e5698 Update README.md 2025-12-09 00:12:35 +00:00
Atharv Nagavarapu
17db936432 Merge pull request 'dev' (#9) from dev into main 
Reviewed-on: Arcmyx/pynamics-pybricks-utils#9
 2025-12-09 00:10:54 +00:00
Atharv Nagavarapu
d3a740e705 Merge pull request 'dev' (#7) from dev into main 
Reviewed-on: Arcmyx/pybricks-utils#7
 2025-12-08 17:04:25 +00:00
Atharv Nagavarapu
960fd598c9 Merge pull request 'dev' (#5) from dev into main 
Reviewed-on: Arcmyx/pybricks-utils#5
 2025-12-08 14:21:45 +00:00
Atharv Nagavarapu
f3460290e5 Merge pull request 'Update utils/BatteryDiagnostics.py' (#3) from dev into main 
Reviewed-on: Arcmyx/pybricks-utils#3
 2025-12-07 21:49:05 +00:00
Atharv Nagavarapu
345da15b22 Merge pull request 'dev' (#2) from dev into main 
Reviewed-on: Arcmyx/pybricks-utils#2
 2025-12-07 21:31:02 +00:00
11 changed files with 76 additions and 462 deletions
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3
README.md
View File

@@ -10,10 +10,9 @@ How to use this:
Included utilities:
- Diagnostics - a program that allows you to diagnose issues and test parts of your robot, such as battery, motor, and color sensor. Open each program in the ```diagnostics``` folder in Pybricks, (you can select all of them at once) connect your robot, switch to the ```FullDiagnostics.py``` file and press run.
- Diagnostics - a program that allows you to diagnose issues and test parts of your robot, such as battery, motor, and color sensor. Open each program in the ```diagnostics``` folder in Pybricks, connect your robot, switch to the ```FullDiagnostics.py``` file and press run.
- Color Sensor Tests (UPCOMING) - a program that identifies what color the sensor is detecting. If you'd like, you can use our color ranges in your own programs.
Please set your window size to 90% on small screens for best results with the ASCII art.
This code is licensed under the Creative Commons Attribution 4.0 International License (CC BY 4.0).
Without the confusing legal speak, this means that you are free to:

28
diagnostics/battery_diagnostics.py → diagnostics/BatteryDiagnostics.py
View File

@@ -1,18 +1,24 @@
from pybricks.tools import wait
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
import umath
# Initialize hub and devices
hub = PrimeHub()
class BatteryDiagnostics:
def __init__(self, hub):
def __init__(self):
self.voltage = 0
self.current = 0
self.hub = hub
def printVoltage(self):
self.voltage = self.hub.battery.voltage()
self.voltage = hub.battery.voltage()
if self.voltage > 7800:
print(f"Battery voltage is sufficient: {self.voltage}")
elif self.voltage < 7800 :
print(f"Charging needed: {self.voltage}")
def printCurrent(self):
self.current = self.hub.battery.current()
self.current = hub.battery.current()
print("Battery current:", self.current)
def printAll(self):
timeelapsed = 0
@@ -33,17 +39,17 @@ class BatteryDiagnostics:
print("Voltage deviation:", self.stdev(voltageList))
print("Current deviation:", self.stdev(currentList))
def stdev(self, vals):
DATA = vals
if len(DATA) < 2:
data = vals
if len(data) < 2:
return 0
# Calculate the mean
MEAN = sum(DATA) / len(DATA)
mean = sum(data) / len(data)
# Calculate the variance (sum of squared differences from the mean, divided by n-1 for sample standard deviation)
VARIANCE = sum([(x - MEAN) ** 2 for x in DATA]) / float(len(DATA) - 1)
variance = sum([(x - mean) ** 2 for x in data]) / float(len(data) - 1)
# Calculate the standard deviation (square root of the variance)
STD_DEV_MANUAL = umath.sqrt(VARIANCE)
std_dev_manual = umath.sqrt(variance)
return (STD_DEV_MANUAL)
return (std_dev_manual)

51
diagnostics/full_diagnostics.py → diagnostics/FullDiagnostics.py
View File

@@ -3,19 +3,13 @@ from pybricks.pupdevices import Motor, ColorSensor, UltrasonicSensor, ForceSenso
from pybricks.parameters import Button, Color, Direction, Port, Side, Stop
from pybricks.robotics import DriveBase
from pybricks.tools import wait, StopWatch
HUB = PrimeHub()
from battery_diagnostics import BatteryDiagnostics
from motor_diagnostics import MotorDiagnostics
from color_sensor_diagnostics import ColorSensorDiagnostics
from drive_base_diagnostics import DriveBaseDiagnostics
from hub_diagnostics import HubDiagnostics
battery = BatteryDiagnostics(HUB)
motor = MotorDiagnostics(HUB, Motor)
colorsensor = ColorSensorDiagnostics(HUB, ColorSensor)
drivebase = DriveBaseDiagnostics(HUB, Motor, DriveBase)
hubdiagnostics = HubDiagnostics(HUB)
CLEARCONFIRM = input("Clear the console before proceeding? Y/N (default: yes): ")
if(CLEARCONFIRM == "Y" or CLEARCONFIRM == "y" or CLEARCONFIRM == "yes" or CLEARCONFIRM == ""):
hub = PrimeHub()
from BatteryDiagnostics import BatteryDiagnostics
from MotorDiagnostics import MotorDiagnostics
battery = BatteryDiagnostics()
motor = MotorDiagnostics()
clearConfirmation = input("Do you want to clear the console before proceeding? Y/N (default: yes): ")
if(clearConfirmation == "Y" or clearConfirmation == "y" or clearConfirmation == "yes" or clearConfirmation == ""):
print("Clearing console... \n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n")
print("""
@@ -27,25 +21,22 @@ print("""
The free and open source diagnostics tool for LEGO® Education SPIKE Prime robots, designed for FIRST Lego League.
The free and open source diagnostics tool for the LEGO® Education SPIKE Prime robots, designed for FIRST Lego League.
Developed by Team 65266, Lego Dynamics.
"""
)
while True:
print("\nWhich diagnostic do you want to perform?")
print("Enter 'b' for battery diagnostics")
print("Enter 'm' for motor diagnostics")
print("Enter 'cs' for color sensor diagnostics")
print("Enter 'db' for drive base diagnostics")
print("Enter 'h' for hub diagnostics")
print("Enter 'q' to quit")
print("\nWhat diagnostic do you want to perform?")
print("Enter 'b' for Battery diagnostics")
print("Enter 'm' for Motor diagnostics")
print("Enter 'q' to Quit")
choice = input("Your choice: ").strip().lower()
if choice == "b":
print("-----------------------BATTERY DIAGNOSTICS-----------------------")
print("This test will check the battery voltage and current. It will measure these over a period of 3 seconds and provide average and deviation values. Your voltage should be above 7800 mV for optimal performance.")
print("This test will check the battery voltage and current. It will measure the voltage and current over a period of 3 seconds and provide average values and deviation values. Your voltage should be above 7800 mV for optimal performance.")
input("Press Enter to begin the battery diagnostics.")
battery.printAll()
print("Battery diagnostics completed.")
@@ -53,21 +44,11 @@ while True:
elif choice == "m":
print("------------------------MOTOR DIAGNOSTICS------------------------")
motor.fullTest()
print("[Motor Diagnostics] Motor diagnostics completed.")
print("Motor diagnostics completed.")
elif choice == "q":
print("Diagnostics completed successfully. Exiting program.")
print("Diagnostics completed successfully. Exiting with code 0. Good luck in the robot game!")
break
elif choice == "cs":
print("---------------------COLOR SENSOR DIAGNOSTICS---------------------")
colorsensor.printAll()
print("[Color Sensor Diagnostics] Color sensor diagnostics completed.")
elif choice == "db":
print("----------------------DRIVE BASE DIAGNOSTICS----------------------")
drivebase.printAll()
print("[Drivebase Diagnostics] Drivebase diagnostics completed.")
elif choice == "h":
print("--------------------------HUB DIAGNOSTICS--------------------------")
hubdiagnostics.printAll(False)
else:
print("Invalid choice. Please enter 'b', 'm', or 'q'.")

73
diagnostics/motor_diagnostics.py → diagnostics/MotorDiagnostics.py
View File

@@ -1,8 +1,13 @@
from pybricks.parameters import Direction, Port, Stop
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
import umath
hub = PrimeHub()
class MotorDiagnostics:
def __init__(self, hub, motorclass):
def __init__(self):
self.testmotor = None
self.port_map = {
"A": Port.A,
@@ -12,42 +17,46 @@ class MotorDiagnostics:
"E": Port.E,
"F": Port.F,
}
self.motorclass = motorclass
def stdev(self, vals):
DATA = vals
if len(DATA) < 2:
data = vals
if len(data) < 2:
return 0
# Calculate the mean
MEAN = sum(DATA) / len(DATA)
mean = sum(data) / len(data)
# Calculate the variance (sum of squared differences from the mean, divided by n-1 for sample standard deviation)
VARIANCE = sum([(x - MEAN) ** 2 for x in DATA]) / float(len(DATA) - 1)
variance = sum([(x - mean) ** 2 for x in data]) / float(len(data) - 1)
# Calculate the standard deviation (square root of the variance)
STD_DEV_MANUAL = umath.sqrt(VARIANCE)
std_dev_manual = umath.sqrt(variance)
return (STD_DEV_MANUAL)
return (std_dev_manual)
def health_score(self, desired, avg_speed, stdev_speed, avg_load):
# Speed accuracy: penalize % error
ACCURACY = max(0, 100 - abs(avg_speed - desired) / desired * 100)
accuracy = max(0, 100 - abs(avg_speed - desired) / desired * 100)
# Stability: penalize deviation relative to desired
STABILITY = max(0, 100 - (stdev_speed / desired) * 100)
stability = max(0, 100 - (stdev_speed / desired) * 100)
# Normalize load: map 10 to 20 as baseline (around 0%), 200 as max (around 100%)
BASELINE = 10 # midpoint of idle range
MAX_OBSERVED = 200 # heavy load/stall
NORMALIZED_LOAD = max(0, avg_load - BASELINE)
LOAD_PCT = min(100, (NORMALIZED_LOAD / (MAX_OBSERVED - BASELINE)) * 100)
baseline = 15 # midpoint of idle range
max_observed = 200 # heavy load/stall
normalized_load = max(0, avg_load - baseline)
load_pct = min(100, (normalized_load / (max_observed - baseline)) * 100)
LOAD_SCORE = max(0, 100 - LOAD_PCT)
load_score = max(0, 100 - load_pct)
# Final score: average of the three
return (ACCURACY + STABILITY + LOAD_SCORE) / 3
return (accuracy + stability + load_score) / 3
# Final score: average of the three
return (accuracy + stability + load_score) / 3
def initializeMotor(self):
VALID_PORTS = {"A", "B", "C", "D", "E", "F"}
valid_ports = {"A", "B", "C", "D", "E", "F"}
while True:
motorinput = input(
"This test will run your motor at 3 speeds: 180, 540, and 1000 degrees per second.\n"
@@ -55,13 +64,11 @@ class MotorDiagnostics:
"If you want to test the wheel's load, note that this will affect the load measurements.\n"
"Enter the port for the motor you would like to test (A, B, C, D, E, or F): "
).strip().upper()
if motorinput not in VALID_PORTS:
print("That is not a valid port. Please enter A-F.")
continue
try:
# Only create a new Motor if we don't already have one
if self.testmotor is None:
self.testmotor = self.motorclass(self.port_map[motorinput])
self.testmotor = Motor(self.port_map[motorinput])
print(f"Motor initialized on port {motorinput}.")
else:
print(f"Reusing existing motor on port {motorinput}.")
@@ -82,16 +89,16 @@ class MotorDiagnostics:
motorspeeds = []
motorloads = []
TARGET_ANGLE = speed * 3
target_angle = speed * 3
print("\n", speed, "DEGREES PER SECOND TEST")
self.testmotor.run_angle(speed, TARGET_ANGLE, Stop.HOLD, False)
self.testmotor.run_angle(speed, target_angle, Stop.HOLD, False)
stopwatchmotor = StopWatch()
while stopwatchmotor.time() < 3000:
wait(20)
motorspeeds.append(self.testmotor.speed())
motorloads.append(self.testmotor.load())
MAX_SPEED, MAX_ACCEL, MAX_TORQUE = self.testmotor.control.limits()
max_speed, max_accel, max_torque = self.testmotor.control.limits()
print("Desired motor speed: ", str(speed))
@@ -110,25 +117,25 @@ class MotorDiagnostics:
else:
print("No load samples collected.")
avgload = 0
SCORE = self.health_score(speed, avg, self.stdev(motorspeeds), avgload)
print("Health score for this test:", str(SCORE) + "%")
return SCORE
score = self.health_score(speed, avg, self.stdev(motorspeeds), avgload)
print("Health score for this test:", str(score) + "%")
return score
def fullTest(self):
self.initializeMotor()
print("Load measurements are in mNm. Speed measurements are in degrees per second.")
MAX_SPEED, MAX_ACCEL, MAX_TORQUE = self.testmotor.control.limits()
print("Maximum motor speed:", MAX_SPEED)
max_speed, max_accel, max_torque = self.testmotor.control.limits()
print("Maximum motor speed:", max_speed)
test180 = self.testSpeed(180)
test540 = self.testSpeed(540)
test1000 = self.testSpeed(1000)
print("\n FINAL MOTOR STATISTICS")
final = (test180 + test540 + test1000) / 3
print("Final motor health score:", str(final) + "%")
if final < 65:
if final < 80:
print("Your motor is in need of attention. Make sure to clean it regularly and charge the Prime Hub.")
elif final < 85:
elif final < 90:
print("Your motor is in OK condition. Make sure to clean it regularly and charge the Prime Hub.")
elif final < 95:
elif final < 97:
print("Your motor is in great condition!")
else:
print("Your motor is in AMAZING condition!!!")

48
diagnostics/color_sensor_diagnostics.py
View File

@@ -1,48 +0,0 @@
from pybricks.parameters import Color, Port, Stop
from pybricks.tools import wait, StopWatch
class ColorSensorDiagnostics:
def __init__(self, hub, colorsensorclass):
self.colorsensor = None
self.PORT_MAP = {
"A": Port.A,
"B": Port.B,
"C": Port.C,
"D": Port.D,
"E": Port.E,
"F": Port.F,
}
self.colorsensorclass = colorsensorclass
def initializeColorSensor(self):
VALID_PORTS = {"A", "B", "C", "D", "E", "F"}
while True:
colorinput = input(
"This will test your color sensor.\n"
"Enter the port for the color sensor you would like to test (A, B, C, D, E, or F): "
).strip().upper()
if colorinput not in VALID_PORTS:
print("Invalid port. Please enter A-F.")
continue
try:
if self.colorsensor is None:
self.colorsensor = self.colorsensorclass(self.PORT_MAP[colorinput])
print(f"Color Sensor initialized on port {colorinput}.")
else:
print(f"Reusing existing color sensor on port {colorinput}.")
break
except OSError as e:
if e.errno == 16: # EBUSY
print(f"Port {colorinput} is already in use. Reusing existing color sensor.")
break
else:
print(f"Error initializing color sensor on port {colorinput}: {e}")
print("Make sure a color sensor is actually connected to this port.")
self.colorsensor = None
self.colorsensor.detectable_colors([Color.RED, Color.YELLOW, Color.GREEN, Color.BLUE, Color.WHITE, Color.NONE])
def printAll(self):
self.initializeColorSensor()
stopwatch = StopWatch()
while stopwatch.time() < 5000:
print("HSV output:", self.colorsensor.hsv())
print("Detected color:", self.colorsensor.color())

165
diagnostics/drive_base_diagnostics.py
View File

@@ -1,165 +0,0 @@
from pybricks.parameters import Direction, Port, Side, Stop
from pybricks.robotics import DriveBase
from pybricks.tools import wait, StopWatch
from usys import stdin
from uselect import poll
class DriveBaseDiagnostics:
def __init__(self, hub, motorclass, dbclass):
self.hub = hub
self.motorclass = motorclass
self.dbclass = dbclass
self.drive_base = None
self.PORT_MAP = {
"A": Port.A,
"B": Port.B,
"C": Port.C,
"D": Port.D,
"E": Port.E,
"F": Port.F,
}
def initializeDriveBase(self):
print("DriveBase setup:")
print("1 = Load from savefile (paste JSON)")
print("2 = Use defaults")
print("3 = Enter values manually")
choice = input("Choose an option: ")
# Default values
WHEEL_DIAMETER = 68.8
AXLE_TRACK = 180
DRIVE_SETTINGS = (600, 2000, 300, 2000)
# Motor ports (None until set)
leftmotorport = Port.A
rightmotorport = Port.B
# -----------------------------
# OPTION 1: LOAD SAVEFILE
# -----------------------------
if choice == "1":
print("Paste JSON:")
raw = input("> ")
# --- wheel ---
if "\"wheel\"" in raw:
part = raw.split("\"wheel\"")[1]
part = part.split(":")[1]
part = part.split(",")[0]
WHEEL_DIAMETER = float(part)
# --- axle ---
if "\"axle\"" in raw:
part = raw.split("\"axle\"")[1]
part = part.split(":")[1]
part = part.split(",")[0]
AXLE_TRACK = float(part)
# --- settings ---
if "\"settings\"" in raw:
part = raw.split("\"settings\"")[1]
part = part.split("[")[1]
part = part.split("]")[0]
nums = part.split(",")
DRIVE_SETTINGS = (int(nums[0]), int(nums[1]), int(nums[2]), int(nums[3]))
# --- left motor port ---
if "\"left_port\"" in raw:
part = raw.split("\"left_port\"")[1]
part = part.split("\"")[1] # first quoted value
leftmotorport = part
# --- right motor port ---
if "\"right_port\"" in raw:
part = raw.split("\"right_port\"")[1]
part = part.split("\"")[1]
rightmotorport = part
print("Loaded config.")
# -----------------------------
# OPTION 3: MANUAL ENTRY
# -----------------------------
elif choice == "3":
WHEEL_DIAMETER = float(input("Wheel diameter: "))
AXLE_TRACK = float(input("Axle track: "))
print("Enter drive settings:")
s1 = int(input("Straight speed: "))
s2 = int(input("Straight accel: "))
s3 = int(input("Turn rate: "))
s4 = int(input("Turn accel: "))
DRIVE_SETTINGS = (s1, s2, s3, s4)
# Ask for motor ports HERE (manual only)
leftmotorport = input("Left motor port: ")
rightmotorport = input("Right motor port: ")
# -----------------------------
# OPTION 2: DEFAULTS
# -----------------------------
else:
pass
# -----------------------------
# CREATE MOTORS
# -----------------------------
left_motor = self.motorclass(leftmotorport, Direction.COUNTERCLOCKWISE)
right_motor = self.motorclass(rightmotorport, Direction.CLOCKWISE)
# -----------------------------
# CREATE DRIVEBASE
# -----------------------------
self.drive_base = self.dbclass(left_motor, right_motor, WHEEL_DIAMETER, AXLE_TRACK)
self.drive_base.settings(*DRIVE_SETTINGS)
self.drive_base.use_gyro(True)
print("DriveBase initialized.")
return DRIVE_SETTINGS
def printAll(self):
self.driveRobot()
def driveRobot(self):
drivesettings = self.initializeDriveBase()
print(drivesettings)
keyboard = poll()
keyboard.register(stdin)
last_key_time = StopWatch()
last_key_time.reset()
while True:
key = None
# Check for keypress immediately
if keyboard.poll(0):
key = stdin.read(1).upper()
last_key_time.reset()
# Process key
if key:
if key == "W":
self.drive_base.drive(drivesettings[0], 0)
elif key == "A":
self.drive_base.drive(drivesettings[0], -180)
elif key == "S":
self.drive_base.drive(-drivesettings[0], 0)
elif key == "D":
self.drive_base.drive(drivesettings[0], 180)
elif key == "X":
break
# Auto-stop if no key for 120 ms
if last_key_time.time() > 120:
self.drive_base.stop()
# Tiny manual delay to avoid 100% CPU
# (much faster than wait())
for _ in range(200):
pass

41
diagnostics/hub_diagnostics.py
View File

@@ -1,41 +0,0 @@
from pybricks.tools import wait, StopWatch
from pybricks import version
import other_functions as debug
from micropython_diagnostics import MicroPythonDiagnostics
from pybricks.parameters import Port
class HubDiagnostics:
def __init__(self, hub):
self.hub = hub
self.port_map = {
"A": Port.A,
"B": Port.B,
"C": Port.C,
"D": Port.D,
"E": Port.E,
"F": Port.F,
}
def testLightSources(self, verbose):
v = verbose
self.hub.display.off()
for x in range(5):
for y in range(5):
debug.log(f"[Hub Diagnostics - Light Sources] Turning on pixel at position {x}, {y}...", v)
self.hub.display.pixel(x, y, brightness=100)
wait(100)
debug.log(f"[Hub Diagnostics - Light Sources] Turning off pixel at position {x}, {y}...", v)
self.hub.display.pixel(x, y, brightness=0)
def printAll(self, verbose=True):
v = verbose
debug.log("[Hub Diagnostics] Starting hub diagnostics...", v)
while True:
choice = input("[Hub Diagnostics] Which hub diagnostic would you like to run?\n[Hub Diagnostics] Enter 'l' for light source test\n[Hub Diagnostics] Enter 'm' for MicroPython diagnostics\n[Hub Diagnostics] Enter 'q' to quit\n[Hub Diagnostics] Your choice: ").strip().lower()
if choice == "l":
debug.log("[Hub Diagnostics] Running light source test...", v)
self.testLightSources(v)
if choice == "m":
debug.log("[Hub Diagnostics] Running MicroPython diagnostics...", v)
MicroPythonDiagnostics.printAll()
if choice == "q":
print("[Hub Diagnostics] Hub diagnostics completed.")
return

42
diagnostics/micropython_diagnostics.py
View File

@@ -1,42 +0,0 @@
import usys
import micropython
from pybricks import version
class MicroPythonDiagnostics:
def __init__(self, hub):
pass
def printVersionDiagnostics():
print("[Hub Diagnostics - MicroPython - Version] Hub version information:", version)
print("[Hub Diagnostics - MicroPython - Version] MicroPython version:", usys.version)
print("[Hub Diagnostics - MicroPython - Version] Pybricks version information:", usys.version_info)
print("[Hub Diagnostics - MicroPython - Version] MicroPython information:", usys.implementation)
def performMemoryDiagnostics():
print("[Hub Diagnostics - MicroPython - Memory] Memory information (retrieved from the MicroPython environment):")
micropython.mem_info(1)
print("[Hub Diagnostics - MicroPython - Memory] Testing heap lock and unlock.")
print("[Hub Diagnostics - MicroPython - Memory] Allocating memory while heap is unlocked:")
try:
x = 5000
print("[Hub Diagnostics - MicroPython - Memory] [SUCCESS] There was no MemoryError raised. The value of the new variable x is", x)
except MemoryError:
print("[Hub Diagnostics - MicroPython - Memory] [FAIL] Allocation failed. Your memory may be faulty.")
print("[Hub Diagnostics - MicroPython - Memory] Locking the heap:")
micropython.heap_lock()
print("[Hub Diagnostics - MicroPython - Memory] Heap was locked. Attempting to allocate memory (this should fail):")
try:
y = 10000
print("[Hub Diagnostics - MicroPython - Memory] [FAIL] There was no MemoryError raised. Heap lock failed.")
except MemoryError:
print("[Hub Diagnostics - MicroPython - Memory] [SUCCESS] Allocation failed. Test successful. The heap was successfully locked.")
# Attempt to add gc to this for memory diagnostics, in addition test machine.soft_reset() and add that first to reset the heap.
print("[Hub Diagnostics - MicroPython - Memory] Unlocking the heap:")
micropython.heap_unlock()
print("[Hub Diagnostics - MicroPython - Memory] Heap was unlocked. Attempting to allocate memory (this should succeed):")
try:
z = 17000
print("[Hub Diagnostics - MicroPython - Memory] [SUCCESS] There was no MemoryError raised. The value of the new variable y is", x)
except MemoryError:
print("[Hub Diagnostics - MicroPython - Memory] [FAIL] Allocation failed. The heap failed to unlock.")
def printAll():
printVersionDiagnostics()
performMemoryDiagnostics()

3
diagnostics/other_functions.py
View File

@@ -1,3 +0,0 @@
def log(string, verbose):
if(verbose):
print("[LOG (verbose)]", string)

62
templates/color_sensor_start_logic.py
View File

@@ -1,62 +0,0 @@
from pybricks.pupdevices import ColorSensor
from pybricks.parameters import Color, Port
from pybricks.tools import run_task
from pybricks.tools import wait
from pybricks.hubs import PrimeHub
hub = PrimeHub()
color_sensor = ColorSensor(Port.F) # Change the port to your color sensor's port
# 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 - your brick should approach from the top for accuracy
return "Green"
elif 195 < h < 198: # light blue
return "Light_Blue"
elif 210 < h < 225: # blue - your brick should approach from the top 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 == "Green":
print('Running Task 1')
# Run a function with await Function() here
elif color == "Red":
print('Running Task 2')
# Run a function with await Function() here
elif color == "Yellow":
print('Running Task 3')
# Run a function with await Function() here
elif color == "Blue":
print('Running Task 4')
# Run a function with await Function() here
elif color == "Orange":
print('Running Task 5')
# Run a function with await Function() here
elif color == "Purple":
print('Running Task 6')
# Run a function with await Function() here
elif color == "Light_Blue":
print("Running Task 7")
# Run a function with await Function() here
else:
print(f"Unknown color detected (Hue: {h}, Sat: {s}, Val: {v})")
#pass
await wait(10)
# Run the main function
run_task(main())

18
templates/xbox_controller.py
View File

@@ -1,18 +0,0 @@
from pybricks.pupdevices import Motor
from pybricks.parameters import Button, Direction, Port, Side, Stop
from pybricks.tools import run_task, multitask
from pybricks.tools import wait, StopWatch
from pybricks.robotics import DriveBase
from pybricks.iodevices import XboxController
from pybricks.hubs import PrimeHub
hub = PrimeHub()
testmotor = Motor(Port.C)
async def main():
while True:
if(Button.UP in buttons.pressed()):
testmotor.run(500)
else:
testmotor.stop()
await wait(10)
# Run the main function
run_task(main())