ekf2: new yaw derivation

Instead of euler angles, compute measurement jacobian using a small
global perturbation around the vertical axis

src/modules/ekf2/EKF/python/ekf_derivation/derivation.py

@@ -390,6 +390,24 @@ def compute_mag_z_innov_var_and_h(
 
     return (innov_var, H.T)
 
+def compute_yaw_innov_var_and_h(
+        state: VState,
+        P: MTangent,
+        R: sf.Scalar
+) -> (sf.Scalar, VTangent):
+
+    state = vstate_to_state(state)
+    q = sf.Quaternion.from_storage(state["quat_nominal"].to_storage())
+    r = sf.Quaternion.symbolic('r')
+    delta_q = q * r.conj() # create a quaternion error of the measurement at the origin
+    delta_meas_pred = 2 * delta_q.z # Use small angle approximation to obtain a simpler jacobian
+
+    H = sf.V1(delta_meas_pred).jacobian(state)
+    H = H.subs({r.w: q.w, r.x: q.x, r.y: q.y, r.z: q.z}) # assume innovation is small
+    innov_var = (H * P * H.T + R)[0,0]
+
+    return (innov_var, H.T)
+
 def compute_yaw_321_innov_var_and_h(
         state: VState,
         P: MTangent,
@@ -678,6 +696,7 @@ if not args.disable_wind:
     generate_px4_function(compute_sideslip_innov_and_innov_var, output_names=["innov", "innov_var"])
     generate_px4_function(compute_wind_init_and_cov_from_airspeed, output_names=["wind", "P_wind"])
 
+generate_px4_function(compute_yaw_innov_var_and_h, output_names=["innov_var", "H"])
 generate_px4_function(compute_yaw_312_innov_var_and_h, output_names=["innov_var", "H"])
 generate_px4_function(compute_yaw_312_innov_var_and_h_alternate, output_names=["innov_var", "H"])
 generate_px4_function(compute_yaw_321_innov_var_and_h, output_names=["innov_var", "H"])

src/modules/ekf2/EKF/python/ekf_derivation/generated/compute_yaw_innov_var_and_h.h

@@ -0,0 +1,65 @@
+// -----------------------------------------------------------------------------
+// This file was autogenerated by symforce from template:
+//     function/FUNCTION.h.jinja
+// Do NOT modify by hand.
+// -----------------------------------------------------------------------------
+
+#pragma once
+
+#include <matrix/math.hpp>
+
+namespace sym {
+
+/**
+ * This function was autogenerated from a symbolic function. Do not modify by hand.
+ *
+ * Symbolic function: compute_yaw_innov_var_and_h
+ *
+ * Args:
+ *     state: Matrix24_1
+ *     P: Matrix23_23
+ *     R: Scalar
+ *
+ * Outputs:
+ *     innov_var: Scalar
+ *     H: Matrix23_1
+ */
+template <typename Scalar>
+void ComputeYawInnovVarAndH(const matrix::Matrix<Scalar, 24, 1>& state,
+                            const matrix::Matrix<Scalar, 23, 23>& P, const Scalar R,
+                            Scalar* const innov_var = nullptr,
+                            matrix::Matrix<Scalar, 23, 1>* const H = nullptr) {
+  // Total ops: 36
+
+  // Input arrays
+
+  // Intermediate terms (5)
+  const Scalar _tmp0 = 2 * state(2, 0);
+  const Scalar _tmp1 = 2 * state(1, 0);
+  const Scalar _tmp2 = -_tmp0 * state(0, 0) + _tmp1 * state(3, 0);
+  const Scalar _tmp3 = _tmp0 * state(3, 0) + _tmp1 * state(0, 0);
+  const Scalar _tmp4 = std::pow(state(0, 0), Scalar(2)) - std::pow(state(1, 0), Scalar(2)) -
+                       std::pow(state(2, 0), Scalar(2)) + std::pow(state(3, 0), Scalar(2));
+
+  // Output terms (2)
+  if (innov_var != nullptr) {
+    Scalar& _innov_var = (*innov_var);
+
+    _innov_var = R + _tmp2 * (P(0, 0) * _tmp2 + P(1, 0) * _tmp3 + P(2, 0) * _tmp4) +
+                 _tmp3 * (P(0, 1) * _tmp2 + P(1, 1) * _tmp3 + P(2, 1) * _tmp4) +
+                 _tmp4 * (P(0, 2) * _tmp2 + P(1, 2) * _tmp3 + P(2, 2) * _tmp4);
+  }
+
+  if (H != nullptr) {
+    matrix::Matrix<Scalar, 23, 1>& _h = (*H);
+
+    _h.setZero();
+
+    _h(0, 0) = _tmp2;
+    _h(1, 0) = _tmp3;
+    _h(2, 0) = _tmp4;
+  }
+}  // NOLINT(readability/fn_size)
+
+// NOLINTNEXTLINE(readability/fn_size)
+}  // namespace sym

src/modules/ekf2/EKF/yaw_fusion.cpp

@@ -35,6 +35,7 @@
 
 #include <ekf_derivation/generated/compute_yaw_321_innov_var_and_h.h>
 #include <ekf_derivation/generated/compute_yaw_312_innov_var_and_h.h>
+#include <ekf_derivation/generated/compute_yaw_innov_var_and_h.h>
 
 #include <mathlib/mathlib.h>
 
@@ -42,7 +43,7 @@
 bool Ekf::fuseYaw(estimator_aid_source1d_s &aid_src_status)
 {
 	VectorState H_YAW;
-	computeYawInnovVarAndH(aid_src_status.observation_variance, aid_src_status.innovation_variance, H_YAW);
+	sym::ComputeYawInnovVarAndH(_state.vector(), P, aid_src_status.observation_variance, &aid_src_status.innovation_variance, &H_YAW);
 
 	return fuseYaw(aid_src_status, H_YAW);
 }
@@ -135,10 +136,5 @@ bool Ekf::fuseYaw(estimator_aid_source1d_s &aid_src_status, const VectorState &H
 
 void Ekf::computeYawInnovVarAndH(float variance, float &innovation_variance, VectorState &H_YAW) const
 {
-	if (shouldUse321RotationSequence(_R_to_earth)) {
-		sym::ComputeYaw321InnovVarAndH(_state.vector(), P, variance, FLT_EPSILON, &innovation_variance, &H_YAW);
-
-	} else {
-		sym::ComputeYaw312InnovVarAndH(_state.vector(), P, variance, FLT_EPSILON, &innovation_variance, &H_YAW);
-	}
+	sym::ComputeYawInnovVarAndH(_state.vector(), P, variance, &innovation_variance, &H_YAW);
 }

src/modules/ekf2/test/test_EKF_yaw_fusion_generated.cpp

@@ -39,10 +39,11 @@
 #include "../EKF/python/ekf_derivation/generated/compute_yaw_321_innov_var_and_h_alternate.h"
 #include "../EKF/python/ekf_derivation/generated/compute_yaw_312_innov_var_and_h.h"
 #include "../EKF/python/ekf_derivation/generated/compute_yaw_312_innov_var_and_h_alternate.h"
+#include "../EKF/python/ekf_derivation/generated/compute_yaw_innov_var_and_h.h"
 
 using namespace matrix;
 
-TEST(YawFusionGenerated, singularityYawEquivalence)
+TEST(YawFusionGenerated, yawSingularity)
 {
 	// GIVEN: an attitude that should give a singularity when transforming the
 	// rotation matrix to Euler yaw
@@ -57,18 +58,18 @@ TEST(YawFusionGenerated, singularityYawEquivalence)
 	float innov_var_a;
 	float innov_var_b;
 
-	// WHEN: computing the innovation variance and H using two different
-	// alternate forms (one is singular at pi/2 and the other one at 0)
+	// WHEN: computing the innovation variance and H using two different methods
 	sym::ComputeYaw321InnovVarAndH(state.vector(), P, R, FLT_EPSILON, &innov_var_a, &H_a);
-	sym::ComputeYaw321InnovVarAndHAlternate(state.vector(), P, R, FLT_EPSILON, &innov_var_b, &H_b);
+	sym::ComputeYawInnovVarAndH(state.vector(), P, R, &innov_var_b, &H_b);
 
-	// THEN: Even at the singularity point, the result is still correct, thanks to epsilon
+	// THEN: Even at the singularity point, the result is still correct
 	EXPECT_TRUE(isEqual(H_a, H_b));
+
 	EXPECT_NEAR(innov_var_a, innov_var_b, 1e-5f);
 	EXPECT_TRUE(innov_var_a < 50.f && innov_var_a > R) << "innov_var = " << innov_var_a;
 }
 
-TEST(YawFusionGenerated, gimbalLock321vs312)
+TEST(YawFusionGenerated, gimbalLock321vs312vsTangent)
 {
 	// GIVEN: an attitude at gimbal lock position
 	StateSample state{};
@@ -79,18 +80,31 @@ TEST(YawFusionGenerated, gimbalLock321vs312)
 
 	VectorState H_321;
 	VectorState H_312;
+	VectorState H_tangent;
 	float innov_var_321;
 	float innov_var_312;
+	float innov_var_tangent;
 	sym::ComputeYaw321InnovVarAndH(state.vector(), P, R, FLT_EPSILON, &innov_var_321, &H_321);
 
 	sym::ComputeYaw312InnovVarAndH(state.vector(), P, R, FLT_EPSILON, &innov_var_312, &H_312);
+	sym::ComputeYawInnovVarAndH(state.vector(), P, R, &innov_var_tangent, &H_tangent);
 
-	// THEN: both computation are not equivalent, 321 is undefined but 312 is valid
+	// THEN: both computation are not equivalent, 321 is undefined but 312 and "tangent" are valid
 	EXPECT_FALSE(isEqual(H_321, H_312));
+	EXPECT_TRUE(isEqual(H_312, H_tangent));
 	EXPECT_GT(fabsf(innov_var_321 - innov_var_312), 1e6f);
+	EXPECT_NEAR(innov_var_312, innov_var_tangent, 1e-6f);
 	EXPECT_TRUE(innov_var_312 < 50.f && innov_var_312 > R) << "innov_var = " << innov_var_312;
 }
 
+Vector3f getRotVarNed(const Quatf &q, const SquareMatrixState &P)
+{
+	constexpr auto S = State::quat_nominal;
+	matrix::SquareMatrix3f rot_cov_body = P.slice<S.dof, S.dof>(S.idx, S.idx);
+	auto R_to_earth = Dcmf(q);
+	return matrix::SquareMatrix<float, State::quat_nominal.dof>(R_to_earth * rot_cov_body * R_to_earth.T()).diag();
+}
+
 TEST(YawFusionGenerated, positiveVarianceAllOrientations)
 {
 	const float R = sq(radians(10.f));
@@ -99,19 +113,14 @@ TEST(YawFusionGenerated, positiveVarianceAllOrientations)
 	VectorState H;
 	float innov_var;
 
-	// GIVEN: all orientations (90 deg steps)
-	for (float yaw = 0.f; yaw < 2.f * M_PI_F; yaw += M_PI_F / 2.f) {
-		for (float pitch = 0.f; pitch < 2.f * M_PI_F; pitch += M_PI_F / 2.f) {
-			for (float roll = 0.f; roll < 2.f * M_PI_F; roll += M_PI_F / 2.f) {
+	// GIVEN: all orientations
+	for (float yaw = 0.f; yaw < 2.f * M_PI_F; yaw += M_PI_F / 4.f) {
+		for (float pitch = 0.f; pitch < 2.f * M_PI_F; pitch += M_PI_F / 4.f) {
+			for (float roll = 0.f; roll < 2.f * M_PI_F; roll += M_PI_F / 4.f) {
 				StateSample state{};
 				state.quat_nominal = Eulerf(roll, pitch, yaw);
 
-				if (shouldUse321RotationSequence(Dcmf(state.quat_nominal))) {
-					sym::ComputeYaw321InnovVarAndH(state.vector(), P, R, FLT_EPSILON, &innov_var, &H);
-
-				} else {
-					sym::ComputeYaw312InnovVarAndH(state.vector(), P, R, FLT_EPSILON, &innov_var, &H);
-				}
+				sym::ComputeYawInnovVarAndH(state.vector(), P, R, &innov_var, &H);
 
 				// THEN: the innovation variance must be positive and finite
 				EXPECT_TRUE(innov_var < 100.f && innov_var > R)
@@ -119,6 +128,16 @@ TEST(YawFusionGenerated, positiveVarianceAllOrientations)
 						<< " pitch = " << degrees(pitch)
 						<< " roll = " << degrees(roll)
 						<< " innov_var = " << innov_var;
+
+				// AND: it should be the same as the "true" innovation variance obtained by summing
+				// the Z rotation variance in NED and the measurement variance
+				const float innov_var_true = getRotVarNed(state.quat_nominal, P)(2) + R;
+				EXPECT_NEAR(innov_var, innov_var_true, 1e-5f)
+						<< "yaw = " << degrees(yaw)
+						<< " pitch = " << degrees(pitch)
+						<< " roll = " << degrees(roll)
+						<< " innov_var = " << innov_var
+						<< " innov_var_true = " << innov_var_true;
 			}
 		}
 	}