Mercurial > public > ostc4
view Discovery/Src/motion.c @ 575:86c4baa6ba29
Change style of viewport calibration menu:
Viewport is now independend from heading value => removed compass value and replaced it by a bar indicator for visualization of the deviation between calibrated and current view
author | Ideenmodellierer |
---|---|
date | Sun, 29 Nov 2020 22:53:33 +0100 |
parents | 01ee21dd311f |
children | beb4d47542f1 |
line wrap: on
line source
/* * motion.c * * Created on: 20.05.2019 * Author: Thorsten Sonntag */ #include <stdint.h> #include <string.h> #include <stdlib.h> #include <math.h> #include "motion.h" #include "data_central.h" #include "t7.h" #include "t3.h" #include "settings.h" #define STABLE_STATE_COUNT 2 /* number of count to declare a state as stable (at the moment based on 100ms) */ #define STABLE_STATE_TIMEOUT 5 /* Detection shall be aborted if a movement state is stable for more than 500ms */ #define SECTOR_WINDOW 40.0 /* Pitch window which is used for custom view projection */ #define SECTOR_WINDOW_MAX 120.0 /* Pitch window which will be greater than the divers field of view */ #define SECTOR_HYSTERY 2 /* Additional offset to avoid fast changing displays */ #define SECTOR_BORDER 400.0 /* Define a value which is out of limit to avoid not wanted key events */ #define SECTOR_FILTER 10 /* Define speed for calculated angle to follow real value */ #define SECTOR_MAX 24 /* maximum number of sectors */ #define SECTOR_SCROLL 7 /* number of sectors used for scroll detection */ #define MOTION_DELTA_STABLE 0 #define MOTION_DELTA_JITTER 1 #define MOTION_DELTA_RAISE 2 #define MOTION_DELTA_FALL 3 #define MOTION_DELTA_JITTER_LEVEL 3.0 /* lower values are considered as stable */ #define MOTION_DELTA_RAISE_LEVEL 6.0 /* Movement causing a significant change detected */ #define MOTION_DELTA_FALL_LEVEL -6.0 /* Movement causing a significant change detected */ #define MOTION_DELTA_HISTORY_SIZE 20 /* Number of history data sets */ detectionState_t detectionState = DETECT_NOTHING; SSector sectorDetection; static uint8_t motionDeltaHistory[3][MOTION_DELTA_HISTORY_SIZE]; /* Change history of roll, pitch and yaw */ static uint8_t motionDeltaHistoryIdx; /* Current index of history data */ static uint8_t focusCnt = 0; static uint8_t inFocus = 0; void resetMotionDeltaHistory() { motionDeltaHistoryIdx = 0; memset(motionDeltaHistory, 0, sizeof(motionDeltaHistory)); } void evaluateMotionDelta(float roll, float pitch, float yaw) { static float lastValue[3] = {0.0,0.0,0.0}; uint8_t nextIndex = motionDeltaHistoryIdx + 1; uint8_t axis; float curValue; if(nextIndex == MOTION_DELTA_HISTORY_SIZE) { nextIndex = 0; } for(axis=0; axis < 3; axis++) { switch(axis) { case MOTION_HISTORY_ROLL: curValue = roll; break; case MOTION_HISTORY_PITCH: curValue = pitch; break; default: case MOTION_HISTORY_YAW: if((yaw < 90) && (lastValue[MOTION_HISTORY_YAW] > 270.0)) /* transition 360 => 0 */ { lastValue[MOTION_HISTORY_YAW] -= 360; } else if((yaw > 270) && (lastValue[MOTION_HISTORY_YAW] < 90.0)) /* transition 0 => 360 */ { lastValue[MOTION_HISTORY_YAW] += 360; } curValue = yaw; break; } if(curValue - lastValue[axis] > MOTION_DELTA_RAISE_LEVEL) { motionDeltaHistory[axis][nextIndex] = MOTION_DELTA_RAISE; } if(fabsf(curValue - lastValue[axis]) < MOTION_DELTA_RAISE_LEVEL) { motionDeltaHistory[axis][nextIndex] = MOTION_DELTA_JITTER; } if(fabsf(curValue - lastValue[axis]) < MOTION_DELTA_JITTER_LEVEL) { motionDeltaHistory[axis][nextIndex] = MOTION_DELTA_STABLE; } if(curValue - lastValue[axis] < MOTION_DELTA_FALL_LEVEL) { motionDeltaHistory[axis][nextIndex] = MOTION_DELTA_FALL; } lastValue[axis] = curValue; } motionDeltaHistoryIdx = nextIndex; } SDeltaHistory GetDeltaHistory(uint8_t stepback) { uint8_t loop = stepback; uint8_t index = motionDeltaHistoryIdx; SDeltaHistory result = {0,0,0}; if(stepback < MOTION_DELTA_HISTORY_SIZE) { while(loop != 0) /* find requested entry */ { loop--; index--; if(index == 0) { index = MOTION_DELTA_HISTORY_SIZE - 1; } } result.roll = motionDeltaHistory[MOTION_HISTORY_ROLL][index]; result.pitch = motionDeltaHistory[MOTION_HISTORY_PITCH][index]; result.yaw = motionDeltaHistory[MOTION_HISTORY_YAW][index]; } return result; } uint8_t GetSectorForPitch(float pitch) { static uint8_t lastsector = 0; float newPitch; uint8_t sector = 0; newPitch = pitch + sectorDetection.offset + sectorDetection.center; /* do not use negative values and consider offset to center position */ if (newPitch < 0.0) /* clip value */ { newPitch = 0.0; } if (newPitch > sectorDetection.window) /* clip value */ { newPitch = sectorDetection.window; } /* switch to other sector? */ if((newPitch > sectorDetection.upperborder) || (newPitch <= sectorDetection.lowerborder)) { sector = (uint16_t) newPitch / sectorDetection.size; sectorDetection.lowerborder = sector * sectorDetection.size - SECTOR_HYSTERY; sectorDetection.upperborder = (sector + 1) * sectorDetection.size + SECTOR_HYSTERY; lastsector = sector; } return lastsector; } void DefinePitchSectors(float centerPitch,uint8_t numOfSectors) { if(numOfSectors == CUSTOMER_DEFINED_VIEWS) { if(settingsGetPointer()->design == 3) /* Big font view ? */ { sectorDetection.count = t3_GetEnabled_customviews(); } else { sectorDetection.count = t7_GetEnabled_customviews(); } if(sectorDetection.count > 7) { sectorDetection.count = 7; /* more views are hard to manually control */ } } else if(numOfSectors != CUSTOMER_KEEP_LAST_SECTORS) { sectorDetection.count = numOfSectors; } if(sectorDetection.count == SECTOR_MAX) { sectorDetection.window = SECTOR_WINDOW_MAX; } else { sectorDetection.window = SECTOR_WINDOW; } sectorDetection.offset = (centerPitch - (sectorDetection.window / 2)) * -1.0; sectorDetection.size = sectorDetection.window / sectorDetection.count; sectorDetection.center = 0; /* reset border values */ sectorDetection.lowerborder = SECTOR_BORDER; sectorDetection.upperborder = SECTOR_BORDER * -1.0; /* get the current sector */ sectorDetection.current = GetSectorForPitch(stateRealGetPointer()->lifeData.compass_pitch); sectorDetection.target = sectorDetection.current; /* do a small adjustment to center pitch to make sure the actual pitch is in the center of the current sector */ sectorDetection.center = (sectorDetection.upperborder) - ((sectorDetection.size + 2 *SECTOR_HYSTERY) / 2.0) - (centerPitch + sectorDetection.offset); } void InitMotionDetection(void) { sectorDetection.target = 0; sectorDetection.current = 0; sectorDetection.size = 0; sectorDetection.count = 0; switch(settingsGetPointer()->MotionDetection) { case MOTION_DETECT_SECTOR: DefinePitchSectors(settingsGetPointer()->viewPitch,CUSTOMER_DEFINED_VIEWS); break; case MOTION_DETECT_MOVE: DefinePitchSectors(settingsGetPointer()->viewPitch,SECTOR_MAX); break; case MOTION_DETECT_SCROLL: DefinePitchSectors(settingsGetPointer()->viewPitch,SECTOR_SCROLL); break; default: break; } resetMotionDeltaHistory(); } /* Map the current pitch value to a sector and create button event in case the sector is left */ detectionState_t detectSectorButtonEvent(float curPitch) { static uint8_t lastTargetSector = 0; uint8_t newTargetSector; uint8_t PitchEvent = DETECT_NOTHING; /* only change sector if reading is stable */ newTargetSector = GetSectorForPitch(stateRealGetPointer()->lifeData.compass_pitch); if(lastTargetSector == newTargetSector) { sectorDetection.target = newTargetSector; } lastTargetSector = newTargetSector; if(sectorDetection.target != sectorDetection.current) { if(sectorDetection.target > sectorDetection.current) { sectorDetection.current++; PitchEvent = DETECT_POS_PITCH; } else { sectorDetection.current--; PitchEvent = DETECT_NEG_PITCH; } } return PitchEvent; } /* Check if pitch is not in center position and trigger a button action if needed */ detectionState_t detectScrollButtonEvent(float curPitch) { static uint8_t delayscroll = 0; /* slow down the number of scroll events */ uint8_t PitchEvent = DETECT_NOTHING; uint8_t newSector; if(delayscroll == 0) { newSector = GetSectorForPitch(stateRealGetPointer()->lifeData.compass_pitch); /* for scroll detection the motion window is split into 6 sectors => set event accoring to the sector number*/ switch(newSector) { case 0: PitchEvent = DETECT_POS_PITCH; break; case 6: PitchEvent = DETECT_NEG_PITCH; break; default: break; } if(PitchEvent != DETECT_NOTHING) { delayscroll = 7; } } else { delayscroll--; } return PitchEvent; } /* Detect if user is generating an pitch including return to starting position */ /* This is done by feeding the past movements value per value into a state machine */ detectionState_t detectPitch(float currentPitch) { uint8_t exit = 0; uint8_t step = 0; uint8_t duration = 0; SDeltaHistory test; detectionState = DETECT_NOTHING; while((step != MOTION_DELTA_HISTORY_SIZE) && (!exit)) /* start backward evalution of pitch changes*/ { test = GetDeltaHistory(step); step++; duration++; switch (detectionState) { case DETECT_NOTHING: if(test.pitch > MOTION_DELTA_STABLE) { exit = 1; } else { detectionState = DETECT_START; } break; case DETECT_START: if(test.pitch == MOTION_DELTA_RAISE) { detectionState = DETECT_POS_MOVE; } if(test.pitch == MOTION_DELTA_FALL) { detectionState = DETECT_NEG_MOVE; } duration = 0; break; case DETECT_NEG_MOVE: case DETECT_POS_MOVE: if(test.pitch <= MOTION_DELTA_JITTER) { detectionState++; } break; case DETECT_MAXIMA: if(test.pitch == MOTION_DELTA_FALL) { detectionState = DETECT_FALLBACK; } break; case DETECT_MINIMA: if(test.pitch == MOTION_DELTA_RAISE) { detectionState = DETECT_RISEBACK; } break; case DETECT_RISEBACK: case DETECT_FALLBACK: if(test.pitch == MOTION_DELTA_STABLE) { if(duration > 5) /* avoid detection triggered by short moves */ { detectionState++; exit = 1; } else { detectionState = DETECT_NOTHING; } } break; default: detectionState = DETECT_NOTHING; exit = 1; break; } } if((detectionState != DETECT_POS_PITCH) && (detectionState != DETECT_NEG_PITCH)) /* nothing found */ { detectionState = DETECT_NOTHING; } else /* dont detect the same event twice */ { resetMotionDeltaHistory(); } return detectionState; } void anglesToCoord(float roll, float pitch, float yaw, SCoord *pCoord) { pCoord->x = ((cosf(yaw) * cosf(pitch)) * pCoord->x + (cosf(yaw)*sinf(pitch)*sinf(roll) - (sinf(yaw)* cosf(roll))) * pCoord->y + (cosf(yaw)*sinf(pitch)*cosf(roll) + sinf(yaw)*sinf(roll)) * pCoord->z); pCoord->y = ((sinf(yaw) * cosf(pitch)) * pCoord->x + (sinf(yaw)*sinf(pitch)*sinf(roll) + cosf(yaw) * cosf(roll)) * pCoord->y + ( sinf(yaw) * sinf(pitch) * cosf(roll) - cosf(yaw) * sinf(roll))* pCoord->z); pCoord->z = ((-1*sinf(pitch)) * pCoord->x + (cosf(pitch) *sinf(roll)) * pCoord->y + (cosf(pitch) * cosf(roll))* pCoord->z); } SCoord CoordAdd(SCoord cA, SCoord cB) { SCoord result; result.x = cA.x + cB.x; result.y = cA.y + cB.y; result.z = cA.z + cB.z; return result; } SCoord CoordSub(SCoord cA, SCoord cB) { SCoord result; result.x = cA.x - cB.x; result.y = cA.y - cB.y; result.z = cA.z - cB.z; return result; } SCoord CoordCross(SCoord cA, SCoord cB) { SCoord result; result.x = (cA.y * cB.z) - (cA.z * cB.y); result.y = (cA.z * cB.x) - (cA.x * cB.z); result.z = (cA.x * cB.y) - (cA.y * cB.x); return result; } SCoord CoordMulF(SCoord op, float factor) { SCoord result; result.x = (op.x * factor); result.y = (op.y * factor); result.z = (op.z * factor); return result; } SCoord CoordDivF(SCoord op, float factor) { SCoord result; result.x = (op.x / factor); result.y = (op.y / factor); result.z = (op.z / factor); return result; } float CoordDot(SCoord cA, SCoord cB) { float result; result = cA.x * cB.x + cA.y * cB.y + cB.z*cA.z; return result; } void calibrateViewport(float roll, float pitch, float yaw) { SSettings* pSettings = settingsGetPointer(); pSettings->viewPitch = pitch; pSettings->viewRoll = roll; pSettings->viewYaw = yaw; } float checkViewport(float roll, float pitch, float yaw) { static float freezeRoll = 0; static float freezeYaw = 0; uint8_t retval = 0; float angleYaw; float anglePitch; float angleRoll; float distance = 0; float _a, _b; SCoord u,v,n; float r; SCoord refVec; SCoord axis_1; SCoord axis_2; SCoord curVec; SCoord resultVec; SDeltaHistory test; SSettings* pSettings = settingsGetPointer(); /* calculate base vector taking calibration delta into account yaw (heading) */ float compYaw = yaw + pSettings->viewYaw; compYaw = 360.0 - yaw; /* turn to 0° */ compYaw += pSettings->viewYaw; /* consider calib yaw value */ compYaw += yaw; if (compYaw < 0.0) { compYaw = 360.0 + compYaw; } if (compYaw > 360.0) { compYaw = compYaw - 360.0; } if (compYaw > 360.0) { compYaw = compYaw - 360.0; } angleYaw = pSettings->viewYaw * M_PI / 180.0; anglePitch = pSettings->viewPitch * M_PI / 180.0; angleRoll = pSettings->viewRoll * M_PI / 180.0; refVec.x = 0; refVec.y = 0; refVec.z = 1.0; anglesToCoord(angleRoll,anglePitch,angleYaw, &refVec); anglePitch = pitch * M_PI / 180.0; angleRoll = roll * M_PI / 180.0; angleYaw = yaw * M_PI / 180.0; /* assume x = 0 and y = 1 => find matching vector so axis_1 is 90° to axis_2 */ axis_1.x = 0; if(refVec.y >=0) { axis_2.y = 1; /* => Spawn y == refVec y */ } else axis_1.y = -1; axis_1.z = -1.0 * refVec.y / refVec.z; axis_2 = CoordCross(refVec, axis_1); /* Cross is 90° to refVec and Spawn as well => Plane Spawn / cross */ /* check if detection plane is correct */ u = CoordSub(axis_1,refVec); v = CoordSub(axis_2,refVec); n = CoordCross(u,v); if((fabsf(n.x) <= 0.0001) && (fabsf(n.y) <= 0.0001) && (fabsf(n.z) <= 0.0001)) { retval = 2; } else { angleYaw = compYaw * M_PI / 180.0; anglePitch = pitch * M_PI / 180.0; angleRoll = roll * M_PI / 180.0; curVec.x = 0; curVec.y = 0; curVec.z = 1.0; anglesToCoord(angleRoll,anglePitch,angleYaw, &curVec); _a = CoordDot(curVec,n); _b = CoordDot(refVec,n); if(_b>=(-0.0001)&&_b<=0.0001) /* Check if view port is parallel (no matchpoint) */ { retval = 3; } else { r=_a/_b; if(r<0.00||r>1.40) /* are we looking into wrong direction? */ { retval = 4; } } distance = retval * 1.0; /* just for debugging */ if(retval == 0) { /* start calculating the matchpoint */ curVec = CoordMulF(curVec,r); resultVec = CoordSub(refVec,curVec); /* calculate the distance between reference and actual vector */ resultVec.x = resultVec.x * resultVec.x; resultVec.y = resultVec.y * resultVec.y; resultVec.z = resultVec.z * resultVec.z; if((resultVec.x == 0) && (resultVec.y == 0) && (resultVec.z == 0)) { distance = 0.0; } else { distance = sqrtf((resultVec.x + resultVec.y + resultVec.z)); } } } if(distance < 0.5) /* handle focus counter to avoid fast in/out focus changes */ { if(focusCnt < 10) { if((focusCnt == 9) && (inFocus == 0)) /* we will get into focus */ { resetMotionDeltaHistory(); } focusCnt++; } if((focusCnt == 10) && (inFocus == 0)) { inFocus = 1; freezeRoll = roll; freezeYaw = yaw; } } else { if(focusCnt >= 5) /* Reset focus faster then setting focus */ { if(pSettings->MotionDetection != MOTION_DETECT_MOVE) /* only apply extended focus for methods using absolute pitch values */ { test = GetDeltaHistory(0); if((test.yaw == MOTION_DELTA_STABLE) && (test.roll == MOTION_DELTA_STABLE)) { if((fabsf(freezeRoll - roll) < MOTION_DELTA_JITTER_LEVEL) && (fabsf(freezeYaw - yaw) < MOTION_DELTA_JITTER_LEVEL)) { focusCnt++; } } else { if(freezeRoll != 0.0) { focusCnt = 1; } } } focusCnt--; } else { focusCnt = 0; inFocus = 0; freezeRoll = 0; freezeYaw = 0; } } return distance; } uint8_t viewInFocus(void) { return inFocus; } void resetFocusState(void) { inFocus = 0; }