/** * Loop reading sensors, attempt to summarize at 50Hz **/ func ReadSensors(sensorChannel chan SensorData) { var ( count int now int64 // Current time in nanoseconds lastTime int64 // Last 100Hz time in nanoseconds hz int64 // Hz in nanoseconds magCount int // Read the Magnetometer every 5th summarize mx, my, mz float32 // Magnetometer data err error gyroscope *sensors.L3GD20 accelerometer *sensors.LSM303ACCEL magnetometer *sensors.LSM303MAG ) fmt.Printf("Allocating sensors...\n") gyroscope, accelerometer, magnetometer, err = setup() if err != nil { close(sensorChannel) return } fmt.Printf("Reading sensors...\n") hz = int64(time.Second/50) - 200000 // minus overhead to send sensor data lastTime = time.Now().UnixNano() mx, my, mz, err = magnetometer.ReadXYZ() if err != nil { fmt.Printf("readSensors: failed to read magnetometer, err=%v\n", err) } for { count++ gyroscope.Measure() now = time.Now().UnixNano() if (now - lastTime) >= hz { sendSensorData(sensorChannel, now, gyroscope, accelerometer, mx, my, mz, count) lastTime = now count = 0 magCount++ } accelerometer.Measure() now = time.Now().UnixNano() if (now - lastTime) >= hz { sendSensorData(sensorChannel, now, gyroscope, accelerometer, mx, my, mz, count) lastTime = now count = 0 magCount++ } if magCount == 5 { magCount = 0 mx, my, mz, err = magnetometer.ReadXYZ() if err != nil { fmt.Printf("readSensors: failed to read magnetometer, err=%v\n", err) } } } }
/** * This test program reads data from the three sensors * gyroscope, accelerometer, and magnetometer, runs it * through the filter, and prints the computed * Yaw, Pitch, and Roll every 100 iterations. * Each iteration takes approximately 3 milliseconds * on a RaspberryPi model B. **/ func main() { const ( d2r = math.Pi / 180.0 // Used to convert degrees to radians r2d = 180.0 / math.Pi // Used to convert radians to degrees ) var ( gyroscope *sensors.L3GD20 = nil accelerometer *sensors.LSM303ACCEL = nil magnetometer *sensors.LSM303MAG = nil imu *imus.ImuMayhony = nil err error dbgPrint bool gx, gy, gz float32 // Gyroscope rate in degrees ax, ay, az float32 // Accelerometer data mx, my, mz float32 // Magnetometer data yaw, pitch, roll float32 // IMU results in radians ) gyroscope, err = sensors.NewL3GD20() if err != nil { fmt.Printf("Error: getting device L3GD20, err=%v\n", err) return } accelerometer, err = sensors.NewLSM303ACCEL() if err != nil { fmt.Printf("Error: getting device LSM303ACCEL, err=%v\n", err) return } magnetometer, err = sensors.NewLSM303MAG() if err != nil { fmt.Printf("Error: getting device LSM303MAG, err=%v\n", err) return } imu = imus.NewImuMayhony() maxIterations := 10000 for { startTime := time.Now().UnixNano() for i := 0; i < maxIterations; i++ { dbgPrint = (i % 100) == 0 now := time.Now().UnixNano() gx, gy, gz, err = gyroscope.ReadXYZ() if err == nil { ax, ay, az, err = accelerometer.ReadXYZ() if err == nil { mx, my, mz, err = magnetometer.ReadXYZ() if err == nil { yaw, pitch, roll = imu.Update(now, gx*d2r, gy*d2r, gz*d2r, ax, ay, az, mx, my, mz) if dbgPrint { fmt.Printf(" YPR(%10.5f, %10.5f, %10.5f)\n", yaw*r2d, pitch*r2d, roll*r2d) } } else { fmt.Printf("Error: reading magnetometer, err=%v\n", err) } } else { fmt.Printf("Error: reading accelerometer, err=%v\n", err) } } else { fmt.Printf("Error: reading gyroscope, err=%v\n", err) } } finishTime := time.Now().UnixNano() delta := finishTime - startTime fmt.Printf("%4.2f milliseconds per iteration\n", (float64(delta)/float64(maxIterations))/1000000.0) } }