Difference between revisions of "Whirlybird/IMU"
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== BNO080 == | == BNO080 == | ||
Sample obtained from Circuit Launch community surplus racks. | Sample obtained from Circuit Launch community surplus racks. |
Latest revision as of 20:56, 9 October 2024
Main project page Whirlybird
BNO080
Sample obtained from Circuit Launch community surplus racks.
https://learn.sparkfun.com/tutorials/qwiic-vr-imu-bno080-hookup-guide/all
compass.py
# BNO08x Micropython I2C Library & Test # derived from Adafruit CircuitPython & Dobodu # https://github.com/dobodu/BOSCH-BNO085-I2C-micropython-library/blob/main/lib/bno08x_i2c.py # Updates to integrate with whilrlybird DF'n by DEFAULT from machine import I2C, Pin import time from time import sleep_ms import math from bno08x_i2c import * import neopixel NEO_COUNT = 32 NEO_DELAY = 50 np = neopixel.NeoPixel(Pin(44), NEO_COUNT, bpp=4) I2C1_SDA = Pin(5) I2C1_SCL = Pin(4) def rgbw(p): np[p] = (0, 0, 0, 1) np.write() sleep_ms(NEO_DELAY) def ring(): for i in range(24,32): rgbw(i) np.fill((0,0,0,0)) np.write() for i in range(23,-1, -1): rgbw(i) np.fill((0,0,0,0)) np.write() ring() i2c1 = I2C(1, scl=I2C1_SCL, sda=I2C1_SDA, freq=100000, timeout=200000 ) #print("I2C Device found at address : ",i2c1.scan(),"\n") bno = BNO08X_I2C(i2c1, debug=False) print("BNO08x I2C connection : Done\n") bno.enable_feature(BNO_REPORT_ACCELEROMETER) bno.enable_feature(BNO_REPORT_GYROSCOPE) #bno.enable_feature(BNO_REPORT_GEOMAGNETIC_ROTATION_VECTOR) #bno.enable_feature(BNO_REPORT_MAGNETOMETER) bno.enable_feature(BNO_REPORT_ROTATION_VECTOR) #bno.enable_feature(BNO_REPORT_ACTIVITY_CLASSIFIER) #bno.enable_feature(BNO_REPORT_STABILITY_CLASSIFIER) print("BNO08x sensors enabling : Done\n") def tilt(): #26/30 left/right, 28/31 down/up x,y,z = bno.acceleration np.fill((0,0,0,0)) if x < -1: np[26] = (int(x*-3),0,0,0) elif x > 1: np[30] = (int(x*3),0,0,0) if y < -1: np[31] = (0,int(y*-3),0,0) elif y > 1: np[28] = (0,0,int(y*3),0) #print("X: %0.6f\tY: %0.6f\tZ: %0.6f" % (x,y,z)) def turn(): x,y,z = bno.euler r = z + 180 - 13 if r < 0: r += 360 #print(z,r) np[int(r/15)] = (0,0,0,5) np.write() def classifier(): print(bno.stability_classification, bno.activity_classification["most_likely"]) def loop(): while True: tilt() turn() #classifier() sleep_ms(50) loop() #cpt = 0 #while True: # time.sleep(0.5) # cpt += 1 # geo_x, geo_y, geo_z, geo_w = bno.geomagnetic_quaternion # mag_x, mag_y, mag_z = bno.magnetic # pylint:disable=no-member # heading = math.atan2(mag_x, mag_y) * 180 / math.pi # print("%0.f Geo\tX: %0.6f\tY: %0.6f\tZ: %0.6f\tW: %0.6f\tMag X: %0.6f\tY: %0.6f\tZ: %0.6f\tuT %d" % (heading, geo_x, geo_y, geo_z, geo_w, mag_x, mag_y, mag_z, cpt)) #if cpt == 10 : # bno.tare # print("cpt", cpt) # accel_x, accel_y, accel_z = bno.acceleration # pylint:disable=no-member # print("Acceleration\tX: %0.6f\tY: %0.6f\tZ: %0.6f\tm/s²" % (accel_x, accel_y, accel_z)) # gyro_x, gyro_y, gyro_z = bno.gyro # pylint:disable=no-member # print("Gyroscope\tX: %0.6f\tY: %0.6f\tZ: %0.6f\trads/s" % (gyro_x, gyro_y, gyro_z)) # quat_i, quat_j, quat_k, quat_real = bno.quaternion # pylint:disable=no-member # print("Rot Vect Quat\tI: %0.6f\tJ: %0.6f\tK: %0.6f\tReal: %0.6f" % (quat_i, quat_j, quat_k, quat_real)) # R, T, P = bno.euler # print("Euler Angle\tX: %0.1f\tY: %0.1f\tZ: %0.1f" % (R, T, P)) # print("")