/*
* Copyright (C) 2016 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
// adapted from frameworks/native/services/sensorservice/Fusion.cpp
#include <algos/fusion.h>
#include <errno.h>
#include <nanohub_math.h>
#include <stdio.h>
#include <seos.h>
#ifdef DEBUG_CH
// change to 0 to disable fusion debugging output
#define DEBUG_FUSION 0
#endif
#define ACC 1
#define MAG 2
#define GYRO 4
#define DEFAULT_GYRO_VAR 1e-7f
#define DEFAULT_GYRO_BIAS_VAR 1e-12f
#define DEFAULT_ACC_STDEV 5e-2f
#define DEFAULT_MAG_STDEV 5e-1f
#define GEOMAG_GYRO_VAR 2e-4f
#define GEOMAG_GYRO_BIAS_VAR 1e-4f
#define GEOMAG_ACC_STDEV 0.02f
#define GEOMAG_MAG_STDEV 0.02f
#define SYMMETRY_TOLERANCE 1e-10f
#define FAKE_MAG_INTERVAL 1.0f //sec
#define NOMINAL_GRAVITY 9.81f
#define FREE_FALL_THRESHOLD (0.1f * NOMINAL_GRAVITY)
#define FREE_FALL_THRESHOLD_SQ (FREE_FALL_THRESHOLD * FREE_FALL_THRESHOLD)
#define MAX_VALID_MAGNETIC_FIELD 75.0f
#define MAX_VALID_MAGNETIC_FIELD_SQ (MAX_VALID_MAGNETIC_FIELD * MAX_VALID_MAGNETIC_FIELD)
#define MIN_VALID_MAGNETIC_FIELD 20.0f //norminal mag field strength is 25uT in some area
#define MIN_VALID_MAGNETIC_FIELD_SQ (MIN_VALID_MAGNETIC_FIELD * MIN_VALID_MAGNETIC_FIELD)
#define MIN_VALID_CROSS_PRODUCT_MAG 1.0e-3
#define MIN_VALID_CROSS_PRODUCT_MAG_SQ (MIN_VALID_CROSS_PRODUCT_MAG * MIN_VALID_CROSS_PRODUCT_MAG)
#define DELTA_TIME_MARGIN 1.0e-9f
#define TRUST_DURATION_MANUAL_MAG_CAL 5.f //unit: seconds
void initFusion(struct Fusion *fusion, uint32_t flags) {
fusion->flags = flags;
if (flags & FUSION_USE_GYRO) {
// normal fusion mode
fusion->param.gyro_var = DEFAULT_GYRO_VAR;
fusion->param.gyro_bias_var = DEFAULT_GYRO_BIAS_VAR;
fusion->param.acc_stdev = DEFAULT_ACC_STDEV;
fusion->param.mag_stdev = DEFAULT_MAG_STDEV;
} else {
// geo mag mode
fusion->param.gyro_var = GEOMAG_GYRO_VAR;
fusion->param.gyro_bias_var = GEOMAG_GYRO_BIAS_VAR;
fusion->param.acc_stdev = GEOMAG_ACC_STDEV;
fusion->param.mag_stdev = GEOMAG_MAG_STDEV;
}
if (flags & FUSION_REINITIALIZE)
{
initVec3(&fusion->Ba, 0.0f, 0.0f, 1.0f);
initVec3(&fusion->Bm, 0.0f, 1.0f, 0.0f);
initVec4(&fusion->x0, 0.0f, 0.0f, 0.0f, 0.0f);
initVec3(&fusion->x1, 0.0f, 0.0f, 0.0f);
fusion->mInitState = 0;
fusion->mPredictDt = 0.0f;
fusion->mCount[0] = fusion->mCount[1] = fusion->mCount[2] = 0;
initVec3(&fusion->mData[0], 0.0f, 0.0f, 0.0f);
initVec3(&fusion->mData[1], 0.0f, 0.0f, 0.0f);
initVec3(&fusion->mData[2], 0.0f, 0.0f, 0.0f);
} else {
// mask off disabled sensor bit
fusion->mInitState &= (ACC
| ((fusion->flags & FUSION_USE_MAG) ? MAG : 0)
| ((fusion->flags & FUSION_USE_GYRO) ? GYRO : 0));
}
fusionSetMagTrust(fusion, NORMAL);
fusion->lastMagInvalid = false;
}
int fusionHasEstimate(const struct Fusion *fusion) {
// waive sensor init depends on the mode
return fusion->mInitState == (ACC
| ((fusion->flags & FUSION_USE_MAG) ? MAG : 0)
| ((fusion->flags & FUSION_USE_GYRO) ? GYRO : 0));
}
static void updateDt(struct Fusion *fusion, float dT) {
if (fabsf(fusion->mPredictDt - dT) > DELTA_TIME_MARGIN) {
float dT2 = dT * dT;
float dT3 = dT2 * dT;
float q00 = fusion->param.gyro_var * dT +
0.33333f * fusion->param.gyro_bias_var * dT3;
float q11 = fusion->param.gyro_bias_var * dT;
float q10 = 0.5f * fusion->param.gyro_bias_var * dT2;
float q01 = q10;
initDiagonalMatrix(&fusion->GQGt[0][0], q00);
initDiagonalMatrix(&fusion->GQGt[0][1], -q10);
initDiagonalMatrix(&fusion->GQGt[1][0], -q01);
initDiagonalMatrix(&fusion->GQGt[1][1], q11);
fusion->mPredictDt = dT;
}
}
static int fusion_init_complete(struct Fusion *fusion, int what, const struct Vec3 *d, float dT) {
if (fusionHasEstimate(fusion)) {
return 1;
}
switch (what) {
case ACC:
{
if (!(fusion->flags & FUSION_USE_GYRO)) {
updateDt(fusion, dT);
}
struct Vec3 unityD = *d;
vec3Normalize(&unityD);
vec3Add(&fusion->mData[0], &unityD);
++fusion->mCount[0];
if (fusion->mCount[0] == 8) {
fusion->mInitState |= ACC;
}
break;
}
case MAG:
{
struct Vec3 unityD = *d;
vec3Normalize(&unityD);
vec3Add(&fusion->mData[1], &unityD);
++fusion->mCount[1];
fusion->mInitState |= MAG;
break;
}
case GYRO:
{
updateDt(fusion, dT);
struct Vec3 scaledD = *d;
vec3ScalarMul(&scaledD, dT);
vec3Add(&fusion->mData[2], &scaledD);
++fusion->mCount[2];
fusion->mInitState |= GYRO;
break;
}
default:
// assert(!"should not be here");
break;
}
if (fusionHasEstimate(fusion)) {
vec3ScalarMul(&fusion->mData[0], 1.0f / fusion->mCount[0]);
if (fusion->flags & FUSION_USE_MAG) {
vec3ScalarMul(&fusion->mData[1], 1.0f / fusion->mCount[1]);
} else {
fusion->fake_mag_decimation = 0.f;
}
struct Vec3 up = fusion->mData[0];
struct Vec3 east;
if (fusion->flags & FUSION_USE_MAG) {
vec3Cross(&east, &fusion->mData[1], &up);
vec3Normalize(&east);
} else {
findOrthogonalVector(up.x, up.y, up.z, &east.x, &east.y, &east.z);
}
struct Vec3 north;
vec3Cross(&north, &up, &east);
struct Mat33 R;
initMatrixColumns(&R, &east, &north, &up);
//Quat q;
//initQuat(&q, &R);
initQuat(&fusion->x0, &R);
initVec3(&fusion->x1, 0.0f, 0.0f, 0.0f);
initZeroMatrix(&fusion->P[0][0]);
initZeroMatrix(&fusion->P[0][1]);
initZeroMatrix(&fusion->P[1][0]);
initZeroMatrix(&fusion->P[1][1]);
fusionSetMagTrust(fusion, INITIALIZATION);
}
return 0;
}
static void matrixCross(struct Mat33 *out, struct Vec3 *p, float diag) {
out->elem[0][0] = diag;
out->elem[1][1] = diag;
out->elem[2][2] = diag;
out->elem[1][0] = p->z;
out->elem[0][1] = -p->z;
out->elem[2][0] = -p->y;
out->elem[0][2] = p->y;
out->elem[2][1] = p->x;
out->elem[1][2] = -p->x;
}
static void fusionCheckState(struct Fusion *fusion) {
if (!mat33IsPositiveSemidefinite(&fusion->P[0][0], SYMMETRY_TOLERANCE)
|| !mat33IsPositiveSemidefinite(
&fusion->P[1][1], SYMMETRY_TOLERANCE)) {
initZeroMatrix(&fusion->P[0][0]);
initZeroMatrix(&fusion->P[0][1]);
initZeroMatrix(&fusion->P[1][0]);
initZeroMatrix(&fusion->P[1][1]);
}
}
#define kEps 1.0E-4f
UNROLLED
static void fusionPredict(struct Fusion *fusion, const struct Vec3 *w) {
const float dT = fusion->mPredictDt;
Quat q = fusion->x0;
struct Vec3 b = fusion->x1;
struct Vec3 we = *w;
vec3Sub(&we, &b);
struct Mat33 I33;
initDiagonalMatrix(&I33, 1.0f);
struct Mat33 I33dT;
initDiagonalMatrix(&I33dT, dT);
struct Mat33 wx;
matrixCross(&wx, &we, 0.0f);
struct Mat33 wx2;
mat33Multiply(&wx2, &wx, &wx);
float norm_we = vec3Norm(&we);
if (fabsf(norm_we) < kEps) {
return;
}
float lwedT = norm_we * dT;
float hlwedT = 0.5f * lwedT;
float ilwe = 1.0f / norm_we;
float k0 = (1.0f - cosf(lwedT)) * (ilwe * ilwe);
float k1 = sinf(lwedT);
float k2 = cosf(hlwedT);
struct Vec3 psi = we;
vec3ScalarMul(&psi, sinf(hlwedT) * ilwe);
struct Vec3 negPsi = psi;
vec3ScalarMul(&negPsi, -1.0f);
struct Mat33 O33;
matrixCross(&O33, &negPsi, k2);
struct Mat44 O;
uint32_t i;
for (i = 0; i < 3; ++i) {
uint32_t j;
for (j = 0; j < 3; ++j) {
O.elem[i][j] = O33.elem[i][j];
}
}
O.elem[3][0] = -psi.x;
O.elem[3][1] = -psi.y;
O.elem[3][2] = -psi.z;
O.elem[3][3] = k2;
O.elem[0][3] = psi.x;
O.elem[1][3] = psi.y;
O.elem[2][3] = psi.z;
struct Mat33 tmp = wx;
mat33ScalarMul(&tmp, k1 * ilwe);
fusion->Phi0[0] = I33;
mat33Sub(&fusion->Phi0[0], &tmp);
tmp = wx2;
mat33ScalarMul(&tmp, k0);
mat33Add(&fusion->Phi0[0], &tmp);
tmp = wx;
mat33ScalarMul(&tmp, k0);
fusion->Phi0[1] = tmp;
mat33Sub(&fusion->Phi0[1], &I33dT);
tmp = wx2;
mat33ScalarMul(&tmp, ilwe * ilwe * ilwe * (lwedT - k1));
mat33Sub(&fusion->Phi0[1], &tmp);
mat44Apply(&fusion->x0, &O, &q);
if (fusion->x0.w < 0.0f) {
fusion->x0.x = -fusion->x0.x;
fusion->x0.y = -fusion->x0.y;
fusion->x0.z = -fusion->x0.z;
fusion->x0.w = -fusion->x0.w;
}
// Pnew = Phi * P
struct Mat33 Pnew[2][2];
mat33Multiply(&Pnew[0][0], &fusion->Phi0[0], &fusion->P[0][0]);
mat33Multiply(&tmp, &fusion->Phi0[1], &fusion->P[1][0]);
mat33Add(&Pnew[0][0], &tmp);
mat33Multiply(&Pnew[0][1], &fusion->Phi0[0], &fusion->P[0][1]);
mat33Multiply(&tmp, &fusion->Phi0[1], &fusion->P[1][1]);
mat33Add(&Pnew[0][1], &tmp);
Pnew[1][0] = fusion->P[1][0];
Pnew[1][1] = fusion->P[1][1];
// P = Pnew * Phi^T
mat33MultiplyTransposed2(&fusion->P[0][0], &Pnew[0][0], &fusion->Phi0[0]);
mat33MultiplyTransposed2(&tmp, &Pnew[0][1], &fusion->Phi0[1]);
mat33Add(&fusion->P[0][0], &tmp);
fusion->P[0][1] = Pnew[0][1];
mat33MultiplyTransposed2(&fusion->P[1][0], &Pnew[1][0], &fusion->Phi0[0]);
mat33MultiplyTransposed2(&tmp, &Pnew[1][1], &fusion->Phi0[1]);
mat33Add(&fusion->P[1][0], &tmp);
fusion->P[1][1] = Pnew[1][1];
mat33Add(&fusion->P[0][0], &fusion->GQGt[0][0]);
mat33Add(&fusion->P[0][1], &fusion->GQGt[0][1]);
mat33Add(&fusion->P[1][0], &fusion->GQGt[1][0]);
mat33Add(&fusion->P[1][1], &fusion->GQGt[1][1]);
fusionCheckState(fusion);
}
void fusionHandleGyro(struct Fusion *fusion, const struct Vec3 *w, float dT) {
if (!fusion_init_complete(fusion, GYRO, w, dT)) {
return;
}
updateDt(fusion, dT);
fusionPredict(fusion, w);
}
UNROLLED
static void scaleCovariance(struct Mat33 *out, const struct Mat33 *A, const struct Mat33 *P) {
uint32_t r;
for (r = 0; r < 3; ++r) {
uint32_t j;
for (j = r; j < 3; ++j) {
float apat = 0.0f;
uint32_t c;
for (c = 0; c < 3; ++c) {
float v = A->elem[c][r] * P->elem[c][c] * 0.5f;
uint32_t k;
for (k = c + 1; k < 3; ++k) {
v += A->elem[k][r] * P->elem[c][k];
}
apat += 2.0f * v * A->elem[c][j];
}
out->elem[r][j] = apat;
out->elem[j][r] = apat;
}
}
}
static void getF(struct Vec4 F[3], const struct Vec4 *q) {
F[0].x = q->w; F[1].x = -q->z; F[2].x = q->y;
F[0].y = q->z; F[1].y = q->w; F[2].y = -q->x;
F[0].z = -q->y; F[1].z = q->x; F[2].z = q->w;
F[0].w = -q->x; F[1].w = -q->y; F[2].w = -q->z;
}
static void fusionUpdate(
struct Fusion *fusion, const struct Vec3 *z, const struct Vec3 *Bi, float sigma) {
struct Mat33 A;
quatToMatrix(&A, &fusion->x0);
struct Vec3 Bb;
mat33Apply(&Bb, &A, Bi);
struct Mat33 L;
matrixCross(&L, &Bb, 0.0f);
struct Mat33 R;
initDiagonalMatrix(&R, sigma * sigma);
struct Mat33 S;
scaleCovariance(&S, &L, &fusion->P[0][0]);
mat33Add(&S, &R);
struct Mat33 Si;
mat33Invert(&Si, &S);
struct Mat33 LtSi;
mat33MultiplyTransposed(&LtSi, &L, &Si);
struct Mat33 K[2];
mat33Multiply(&K[0], &fusion->P[0][0], &LtSi);
mat33MultiplyTransposed(&K[1], &fusion->P[0][1], &LtSi);
struct Mat33 K0L;
mat33Multiply(&K0L, &K[0], &L);
struct Mat33 K1L;
mat33Multiply(&K1L, &K[1], &L);
struct Mat33 tmp;
mat33Multiply(&tmp, &K0L, &fusion->P[0][0]);
mat33Sub(&fusion->P[0][0], &tmp);
mat33Multiply(&tmp, &K1L, &fusion->P[0][1]);
mat33Sub(&fusion->P[1][1], &tmp);
mat33Multiply(&tmp, &K0L, &fusion->P[0][1]);
mat33Sub(&fusion->P[0][1], &tmp);
mat33Transpose(&fusion->P[1][0], &fusion->P[0][1]);
struct Vec3 e = *z;
vec3Sub(&e, &Bb);
struct Vec3 dq;
mat33Apply(&dq, &K[0], &e);
struct Vec4 F[3];
getF(F, &fusion->x0);
// 4x3 * 3x1 => 4x1
struct Vec4 q;
q.x = fusion->x0.x + 0.5f * (F[0].x * dq.x + F[1].x * dq.y + F[2].x * dq.z);
q.y = fusion->x0.y + 0.5f * (F[0].y * dq.x + F[1].y * dq.y + F[2].y * dq.z);
q.z = fusion->x0.z + 0.5f * (F[0].z * dq.x + F[1].z * dq.y + F[2].z * dq.z);
q.w = fusion->x0.w + 0.5f * (F[0].w * dq.x + F[1].w * dq.y + F[2].w * dq.z);
fusion->x0 = q;
quatNormalize(&fusion->x0);
if (fusion->flags & FUSION_USE_MAG) {
// accumulate gyro bias (causes self spin) only if not
// game rotation vector
struct Vec3 db;
mat33Apply(&db, &K[1], &e);
vec3Add(&fusion->x1, &db);
}
fusionCheckState(fusion);
}
#define ACC_TRUSTWORTHY(abs_norm_err) ((abs_norm_err) < 1.f)
#define ACC_COS_CONV_FACTOR 0.01f
#define ACC_COS_CONV_LIMIT 3.f
int fusionHandleAcc(struct Fusion *fusion, const struct Vec3 *a, float dT) {
if (!fusion_init_complete(fusion, ACC, a, dT)) {
return -EINVAL;
}
float norm2 = vec3NormSquared(a);
if (norm2 < FREE_FALL_THRESHOLD_SQ) {
return -EINVAL;
}
float l = sqrtf(norm2);
float l_inv = 1.0f / l;
if (!(fusion->flags & FUSION_USE_GYRO)) {
// geo mag mode
// drive the Kalman filter with zero mean dummy gyro vector
struct Vec3 w_dummy;
// avoid (fabsf(norm_we) < kEps) in fusionPredict()
initVec3(&w_dummy, fusion->x1.x + kEps, fusion->x1.y + kEps,
fusion->x1.z + kEps);
updateDt(fusion, dT);
fusionPredict(fusion, &w_dummy);
}
struct Mat33 R;
fusionGetRotationMatrix(fusion, &R);
if (!(fusion->flags & FUSION_USE_MAG) &&
(fusion->fake_mag_decimation += dT) > FAKE_MAG_INTERVAL) {
// game rotation mode, provide fake mag update to prevent
// P to diverge over time
struct Vec3 m;
mat33Apply(&m, &R, &fusion->Bm);
fusionUpdate(fusion, &m, &fusion->Bm,
fusion->param.mag_stdev);
fusion->fake_mag_decimation = 0.f;
}
struct Vec3 unityA = *a;
vec3ScalarMul(&unityA, l_inv);
float d = fabsf(l - NOMINAL_GRAVITY);
float p;
if (fusion->flags & FUSION_USE_GYRO) {
float fc = 0;
// Enable faster convergence
if (ACC_TRUSTWORTHY(d)) {
struct Vec3 aa;
mat33Apply(&aa, &R, &fusion->Ba);
float cos_err = vec3Dot(&aa, &unityA);
cos_err = cos_err < (1.f - ACC_COS_CONV_FACTOR) ?
(1.f - ACC_COS_CONV_FACTOR) : cos_err;
fc = (1.f - cos_err) *
(1.0f / ACC_COS_CONV_FACTOR * ACC_COS_CONV_LIMIT);
}
p = fusion->param.acc_stdev * expf(3 * d - fc);
} else {
// Adaptive acc weighting (trust acc less as it deviates from nominal g
// more), acc_stdev *= e(sqrt(| |acc| - g_nominal|))
//
// The weighting equation comes from heuristics.
p = fusion->param.acc_stdev * expf(sqrtf(d));
}
fusionUpdate(fusion, &unityA, &fusion->Ba, p);
return 0;
}
#define MAG_COS_CONV_FACTOR 0.02f
#define MAG_COS_CONV_LIMIT 3.5f
#define MAG_STDEV_REDUCTION 0.005f // lower stdev means more trust
int fusionHandleMag(struct Fusion *fusion, const struct Vec3 *m, float dT) {
if (!fusion_init_complete(fusion, MAG, m, 0.0f /* dT */)) {
return -EINVAL;
}
float magFieldSq = vec3NormSquared(m);
if (magFieldSq > MAX_VALID_MAGNETIC_FIELD_SQ
|| magFieldSq < MIN_VALID_MAGNETIC_FIELD_SQ) {
fusionSetMagTrust(fusion, NORMAL);
fusion->lastMagInvalid = true;
return -EINVAL;
}
struct Mat33 R;
fusionGetRotationMatrix(fusion, &R);
struct Vec3 up;
mat33Apply(&up, &R, &fusion->Ba);
struct Vec3 east;
vec3Cross(&east, m, &up);
if (vec3NormSquared(&east) < MIN_VALID_CROSS_PRODUCT_MAG_SQ) {
fusionSetMagTrust(fusion, NORMAL);
fusion->lastMagInvalid = true;
return -EINVAL;
}
if (fusion->lastMagInvalid) {
fusion->lastMagInvalid = false;
fusionSetMagTrust(fusion, BACK_TO_VALID);
}
struct Vec3 north;
vec3Cross(&north, &up, &east);
float invNorm = 1.0f / vec3Norm(&north);
vec3ScalarMul(&north, invNorm);
float p = fusion->param.mag_stdev;
if (fusion->flags & FUSION_USE_GYRO) {
struct Vec3 mm;
mat33Apply(&mm, &R, &fusion->Bm);
float cos_err = vec3Dot(&mm, &north);
if (fusion->trustedMagDuration > 0) {
// if the trust mag time period is not finished
if (cos_err < (1.f - MAG_COS_CONV_FACTOR/4)) {
// if the mag direction and the fusion north has not converged, lower the
// standard deviation of mag to speed up convergence.
p *= MAG_STDEV_REDUCTION;
fusion->trustedMagDuration -= dT;
} else {
// it has converged already, so no need to keep the trust period any longer
fusionSetMagTrust(fusion, NORMAL);
}
} else {
cos_err = cos_err < (1.f - MAG_COS_CONV_FACTOR) ?
(1.f - MAG_COS_CONV_FACTOR) : cos_err;
float fc;
fc = (1.f - cos_err) * (1.0f / MAG_COS_CONV_FACTOR * MAG_COS_CONV_LIMIT);
p *= expf(-fc);
}
}
fusionUpdate(fusion, &north, &fusion->Bm, p);
return 0;
}
void fusionSetMagTrust(struct Fusion *fusion, int mode) {
switch(mode) {
case NORMAL:
fusion->trustedMagDuration = 0; // disable
break;
case INITIALIZATION:
case BACK_TO_VALID:
fusion->trustedMagDuration = 0; // no special treatment for these two
break;
case MANUAL_MAG_CAL:
fusion->trustedMagDuration = TRUST_DURATION_MANUAL_MAG_CAL;
break;
default:
fusion->trustedMagDuration = 0; // by default it is disable
break;
}
}
void fusionGetAttitude(const struct Fusion *fusion, struct Vec4 *attitude) {
*attitude = fusion->x0;
}
void fusionGetBias(const struct Fusion *fusion, struct Vec3 *bias) {
*bias = fusion->x1;
}
void fusionGetRotationMatrix(const struct Fusion *fusion, struct Mat33 *R) {
quatToMatrix(R, &fusion->x0);
}