#include <ao_data.h>
#endif
+#if HAS_GYRO
+#include <ao_quaternion.h>
+#endif
+
/*
* Current sensor values
*/
#if HAS_ACCEL
__pdata accel_t ao_sample_accel;
#endif
+#if HAS_GYRO
+__pdata accel_t ao_sample_accel_along;
+__pdata accel_t ao_sample_accel_across;
+__pdata accel_t ao_sample_accel_through;
+__pdata gyro_t ao_sample_roll;
+__pdata gyro_t ao_sample_pitch;
+__pdata gyro_t ao_sample_yaw;
+__pdata angle_t ao_orient;
+#endif
__data uint8_t ao_sample_data;
__pdata int32_t ao_accel_scale; /* sensor to m/s² conversion */
#endif
+#if HAS_GYRO
+__pdata accel_t ao_ground_accel_along;
+__pdata accel_t ao_ground_accel_across;
+__pdata accel_t ao_ground_accel_through;
+__pdata gyro_t ao_ground_pitch;
+__pdata gyro_t ao_ground_yaw;
+__pdata gyro_t ao_ground_roll;
+#endif
+
static __pdata uint8_t ao_preflight; /* in preflight mode */
static __pdata uint16_t nsamples;
#if HAS_ACCEL
__pdata int32_t ao_sample_accel_sum;
#endif
+#if HAS_GYRO
+__pdata int32_t ao_sample_accel_along_sum;
+__pdata int32_t ao_sample_accel_across_sum;
+__pdata int32_t ao_sample_accel_through_sum;
+__pdata int32_t ao_sample_pitch_sum;
+__pdata int32_t ao_sample_yaw_sum;
+__pdata int32_t ao_sample_roll_sum;
+static struct ao_quaternion ao_rotation;
+static struct ao_quaternion ao_pad_orientation;
+#endif
+
+static void
+ao_sample_preflight_add(void)
+{
+#if HAS_ACCEL
+ ao_sample_accel_sum += ao_sample_accel;
+#endif
+ ao_sample_pres_sum += ao_sample_pres;
+#if HAS_GYRO
+ ao_sample_accel_along_sum += ao_sample_accel_along;
+ ao_sample_accel_across_sum += ao_sample_accel_across;
+ ao_sample_accel_through_sum += ao_sample_accel_through;
+ ao_sample_pitch_sum += ao_sample_pitch;
+ ao_sample_yaw_sum += ao_sample_yaw;
+ ao_sample_roll_sum += ao_sample_roll;
+#endif
+ ++nsamples;
+}
+
+static void
+ao_sample_preflight_set(void)
+{
+#if HAS_ACCEL
+ ao_ground_accel = ao_sample_accel_sum >> 9;
+ ao_sample_accel_sum = 0;
+#endif
+ ao_ground_pres = ao_sample_pres_sum >> 9;
+ ao_ground_height = pres_to_altitude(ao_ground_pres);
+ ao_sample_pres_sum = 0;
+#if HAS_GYRO
+ ao_ground_accel_along = ao_sample_accel_along_sum >> 9;
+ ao_ground_accel_across = ao_sample_accel_across_sum >> 9;
+ ao_ground_accel_through = ao_sample_accel_through_sum >> 9;
+ ao_ground_pitch = ao_sample_pitch_sum >> 9;
+ ao_ground_yaw = ao_sample_yaw_sum >> 9;
+ ao_ground_roll = ao_sample_roll_sum >> 9;
+ ao_sample_accel_along_sum = 0;
+ ao_sample_accel_across_sum = 0;
+ ao_sample_accel_through_sum = 0;
+ ao_sample_pitch_sum = 0;
+ ao_sample_yaw_sum = 0;
+ ao_sample_roll_sum = 0;
+ ao_orient = 0;
+
+ /* No rotation yet */
+ ao_quaternion_init_zero_rotation(&ao_rotation);
+
+ /* Take the pad IMU acceleration values and compute our current direction
+ */
+ ao_quaternion_init_vector(&ao_pad_orientation,
+ ao_ground_accel_across - ao_config.accel_zero_across,
+ ao_ground_accel_through - ao_config.accel_zero_through,
+ -ao_ground_accel_along - ao_config.accel_zero_along);
+
+ ao_quaternion_normalize(&ao_pad_orientation,
+ &ao_pad_orientation);
+
+#endif
+ nsamples = 0;
+}
+
+#if HAS_GYRO
+static void
+ao_sample_rotate(void)
+{
+#ifdef AO_FLIGHT_TEST
+ float dt = (ao_sample_tick - ao_sample_prev_tick) / 100.0;
+#else
+ static const float dt = 1/100.0;
+#endif
+ float x = ao_mpu6000_gyro(ao_sample_pitch - ao_ground_pitch) * dt;
+ float y = ao_mpu6000_gyro(ao_sample_yaw - ao_ground_yaw) * dt;
+ float z = ao_mpu6000_gyro(ao_sample_roll - ao_ground_roll) * dt;
+
+ float n_2, n;
+ float s, c;
+
+ struct ao_quaternion rot;
+ struct ao_quaternion point;
+
+ /* The amount of rotation is just the length of the vector. Now,
+ * here's the trick -- assume that the rotation amount is small. In this case,
+ * sin(x) ≃ x, so we can just make this the sin.
+ */
+
+ n_2 = x*x + y*y + z*z;
+ n = sqrtf(n_2);
+ s = n / 2;
+ if (s > 1)
+ s = 1;
+ c = sqrtf(1 - s*s);
+
+ /* Make unit vector */
+ if (n > 0) {
+ x /= n;
+ y /= n;
+ z /= n;
+ }
+
+ /* Now compute the unified rotation quaternion */
+
+ ao_quaternion_init_rotation(&rot,
+ x, y, z,
+ s, c);
+
+ /* Integrate with the previous rotation amount */
+ ao_quaternion_multiply(&ao_rotation, &ao_rotation, &rot);
+
+ /* And normalize to make sure it remains a unit vector */
+ ao_quaternion_normalize(&ao_rotation, &ao_rotation);
+
+ /* Compute pitch angle from vertical by taking the pad
+ * orientation vector and rotating it by the current total
+ * rotation value. That will be a unit vector pointing along
+ * the airframe axis. The Z value will be the cosine of the
+ * change in the angle from vertical since boost
+ */
+
+ ao_quaternion_rotate(&point, &ao_pad_orientation, &ao_rotation);
+
+ ao_orient = acosf(point.z) * (float) (180.0/M_PI);
+}
+#endif
static void
ao_sample_preflight(void)
* data and average them to find the resting values
*/
if (nsamples < 512) {
-#if HAS_ACCEL
- ao_sample_accel_sum += ao_sample_accel;
-#endif
- ao_sample_pres_sum += ao_sample_pres;
- ++nsamples;
+ ao_sample_preflight_add();
} else {
- ao_config_get();
#if HAS_ACCEL
- ao_ground_accel = ao_sample_accel_sum >> 9;
ao_accel_2g = ao_config.accel_minus_g - ao_config.accel_plus_g;
ao_accel_scale = to_fix32(GRAVITY * 2 * 16) / ao_accel_2g;
#endif
- ao_ground_pres = ao_sample_pres_sum >> 9;
- ao_ground_height = pres_to_altitude(ao_ground_pres);
+ ao_sample_preflight_set();
ao_preflight = FALSE;
}
}
+/*
+ * While in pad mode, constantly update the ground state by
+ * re-averaging the data. This tracks changes in orientation, which
+ * might be caused by adjustments to the rocket on the pad and
+ * pressure, which might be caused by changes in the weather.
+ */
+
+static void
+ao_sample_preflight_update(void)
+{
+ if (nsamples < 512)
+ ao_sample_preflight_add();
+ else if (nsamples < 1024)
+ ++nsamples;
+ else
+ ao_sample_preflight_set();
+}
+
+#if 0
+#if HAS_GYRO
+static int32_t p_filt;
+static int32_t y_filt;
+
+static gyro_t inline ao_gyro(void) {
+ gyro_t p = ao_sample_pitch - ao_ground_pitch;
+ gyro_t y = ao_sample_yaw - ao_ground_yaw;
+
+ p_filt = p_filt - (p_filt >> 6) + p;
+ y_filt = y_filt - (y_filt >> 6) + y;
+
+ p = p_filt >> 6;
+ y = y_filt >> 6;
+ return ao_sqrt(p*p + y*y);
+}
+#endif
+#endif
uint8_t
ao_sample(void)
{
- ao_config_get();
ao_wakeup(DATA_TO_XDATA(&ao_sample_data));
ao_sleep((void *) DATA_TO_XDATA(&ao_data_head));
while (ao_sample_data != ao_data_head) {
ao_data = (struct ao_data *) &ao_data_ring[ao_sample_data];
ao_sample_tick = ao_data->tick;
+#if HAS_BARO
ao_data_pres_cook(ao_data);
ao_sample_pres = ao_data_pres(ao_data);
ao_sample_alt = pres_to_altitude(ao_sample_pres);
ao_sample_height = ao_sample_alt - ao_ground_height;
+#endif
#if HAS_ACCEL
ao_sample_accel = ao_data_accel_cook(ao_data);
ao_sample_accel = ao_data_accel_invert(ao_sample_accel);
ao_data_set_accel(ao_data, ao_sample_accel);
#endif
+#if HAS_GYRO
+ ao_sample_accel_along = ao_data_along(ao_data);
+ ao_sample_accel_across = ao_data_across(ao_data);
+ ao_sample_accel_through = ao_data_through(ao_data);
+ ao_sample_pitch = ao_data_pitch(ao_data);
+ ao_sample_yaw = ao_data_yaw(ao_data);
+ ao_sample_roll = ao_data_roll(ao_data);
+#endif
if (ao_preflight)
ao_sample_preflight();
- else
+ else {
+ if (ao_flight_state < ao_flight_boost)
+ ao_sample_preflight_update();
ao_kalman();
+#if HAS_GYRO
+ ao_sample_rotate();
+#endif
+ }
+#ifdef AO_FLIGHT_TEST
+ ao_sample_prev_tick = ao_sample_tick;
+#endif
ao_sample_data = ao_data_ring_next(ao_sample_data);
}
return !ao_preflight;
void
ao_sample_init(void)
{
+ ao_config_get();
nsamples = 0;
ao_sample_pres_sum = 0;
ao_sample_pres = 0;
#if HAS_ACCEL
ao_sample_accel_sum = 0;
ao_sample_accel = 0;
+#endif
+#if HAS_GYRO
+ ao_sample_accel_along_sum = 0;
+ ao_sample_accel_across_sum = 0;
+ ao_sample_accel_through_sum = 0;
+ ao_sample_accel_along = 0;
+ ao_sample_accel_across = 0;
+ ao_sample_accel_through = 0;
+ ao_sample_pitch_sum = 0;
+ ao_sample_yaw_sum = 0;
+ ao_sample_roll_sum = 0;
+ ao_sample_pitch = 0;
+ ao_sample_yaw = 0;
+ ao_sample_roll = 0;
+ ao_orient = 0;
#endif
ao_sample_data = ao_data_head;
ao_preflight = TRUE;