Mercurial > public > ostc4
view Discovery/Src/motion.c @ 599:5a8f9126e4cb
Bugfix T3 skip deactivated views:
I previous version the OSTC hangs if only conditional views (like decoplan which is only displayed in case of deco time) are switched. Rootcause was that the select function could never switch to another view because no visible view was available. To avoid this use case a fallback option has been added. In case no other view is available, the current view will be kept. In case no view at all (even no conditional view) is available then a switch to the "None" view will be done independend if it is enabled or not.
T3_Profile: Added functionalty to show max depth and divetime of a profile provided by the replay block.
author | Ideenmodellierer |
---|---|
date | Mon, 04 Jan 2021 21:48:31 +0100 |
parents | fd0b60dee6f3 |
children | 916998f90e39 |
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/* * 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" #include "base.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 30.0 /* 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 SECTOR_MAX_CNT 5 /* max number of views used for sector control */ #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; static uint8_t sectorMap[SECTOR_MAX_CNT]; 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; uint8_t index = motionDeltaHistoryIdx; SDeltaHistory result = {0,0,0}; stepback++; /* motionDeltaHistoryIdx is pointing to future entry => step back one to get the latest */ loop = stepback; 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 > SECTOR_MAX_CNT) { sectorDetection.count = SECTOR_MAX_CNT; /* 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); } uint8_t GetCVForSector(uint8_t selSector) { if(selSector < sectorDetection.count) { return sectorMap[selSector]; } else { return 0; } } void MapCVToSector() { uint8_t centerView = 0; memset(sectorMap, 0, sizeof(sectorMap)); switch(sectorDetection.count) { case 1: centerView = 0; break; case 2: centerView = 0; break; case 3: centerView = 1; break; case 4: centerView = 1; break; case 5: centerView = 2; break; default: centerView = sectorDetection.count / 2 - 1; break; } if(settingsGetPointer()->design == 3) /* Big font view ? */ { t3_set_customview_to_primary(); sectorMap[centerView] = t3_change_customview(ACTION_END); } else { t7_set_customview_to_primary(); sectorMap[centerView] = t7_change_customview(ACTION_END); } centerView++; while(sectorMap[centerView] == 0) { if(settingsGetPointer()->design == 3) /* Big font view ? */ { sectorMap[centerView] = t3_change_customview(ACTION_BUTTON_ENTER); } else { sectorMap[centerView] = t7_change_customview(ACTION_BUTTON_ENTER); } centerView++; if(centerView == sectorDetection.count) { centerView = 0; } } } 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); MapCVToSector(); 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) { uint8_t newTargetSector; newTargetSector = GetSectorForPitch(stateRealGetPointer()->lifeData.compass_pitch); if(settingsGetPointer()->design == 3) /* Big font view ? */ { t3_select_customview(GetCVForSector(newTargetSector)); } else { t7_select_customview(GetCVForSector(newTargetSector)); } return DETECT_NOTHING; } /* 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) { static int8_t lastStart = 0; uint8_t exit = 0; int8_t step = 0; uint8_t duration = 0; SDeltaHistory test; if(lastStart < 0) { detectionState = DETECT_NOTHING; lastStart = 0; } else { detectionState = DETECT_START; } step = lastStart; do { test = GetDeltaHistory(step); duration++; switch (detectionState) { case DETECT_NOTHING: if(test.pitch > MOTION_DELTA_STABLE) { exit = 1; lastStart = -2; } else { detectionState = DETECT_START; lastStart = -1; } break; case DETECT_START: if(test.pitch == MOTION_DELTA_RAISE) { detectionState = DETECT_POS_MOVE; lastStart = step; } else if(test.pitch == MOTION_DELTA_FALL) { detectionState = DETECT_NEG_MOVE; lastStart = step; } else { lastStart = -1; } duration = 0; break; case DETECT_NEG_MOVE: if((test.pitch <= MOTION_DELTA_JITTER) || (test.pitch == MOTION_DELTA_RAISE)) { detectionState++; } break; case DETECT_POS_MOVE: if((test.pitch <= MOTION_DELTA_JITTER) || (test.pitch == MOTION_DELTA_FALL)) { 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 > 4) /* avoid detection triggered by short moves */ { detectionState++; } exit = 1; lastStart = -2; } break; default: detectionState = DETECT_NOTHING; exit = 1; break; } step--; } while((step >= 0) && (!exit)); if((lastStart < MOTION_DELTA_HISTORY_SIZE)) { lastStart++; /* prepare value for next iteration (history index will be increased) */ } else { lastStart = -1; } 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; }