BMP280 Code cleanup
[openXsensor.git] / openXsensor / oXs_ms5611.cpp
blob98de92b98c3a5ef83f7899d9ebf1815e42d53bb2
1 #include "oXs_ms5611.h"
3 #if defined(SENSOR_IS_MS5611)
5 #ifdef DEBUG
6 //#define DEBUGI2CMS5611
7 //#define DEBUG_VARIO_DATA
8 //#define DEBUGVARIOI2C
9 //#define DEBUGVARIO
10 //#define DEBUG_VARIO_TIME
11 #endif
13 //extern unsigned long micros( void ) ;
14 //extern unsigned long millis( void ) ;
15 //extern void delay(unsigned long ms) ;
17 uint16_t i2cPressureError ;
18 uint16_t i2cTemperatureError ;
19 uint16_t i2cReadCount ;
23 //long result ;
26 #ifdef DEBUG
27 OXS_MS5611::OXS_MS5611(uint8_t addr, HardwareSerial &print)
28 #else
29 OXS_MS5611::OXS_MS5611(uint8_t addr)
30 #endif
32 // constructor
33 _addr=addr;
34 varioData.SensorState = 0 ;
35 #ifdef DEBUG
36 printer = &print; //operate on the address of print
37 // printer->begin(115200);
38 // printer->print("Vario Sensor:MS5611 I2C Addr=");
39 // printer->println(addr,HEX);
40 #endif
44 // **************** Setup the MS5611 sensor *********************
45 void OXS_MS5611::setup() {
46 varioData.absoluteAlt.available = false ;
47 varioData.relativeAlt.available = false ;
48 varioData.climbRate.available = false ;
49 varioData.sensitivity.available = false ;
50 varioData.vSpeed10SecAvailable = false ;
51 // varioData.newClimbRateAvailable = false;
52 // varioData.sensitivityPpm = 0 ;
53 // varioData.idxPrevAlt = 0 ;
54 // D1 = 0;
55 // D2 = 0;
56 // D2Prev = 0;
57 // D2Apply = 0 ;
58 // dT = 0 ;
59 // TEMP = 0 ;
60 // rawAltitude = 0 ;
62 // altitude = 0 ;
63 // altitudeLowPass = 0 ;
64 // altitudeHighPass = 0 ;
65 sensitivityMin = SENSITIVITY_MIN ; // set the min smoothing to the default value
66 varioData.delaySmooth = 20000 ; // delay between 2 altitude calculation = 20msec = 20000 usec
67 nextAltMillis = 5000 ; // in msec; save when Altitude has to be calculated; altitude is available only after some delay in order to get a stable value (less temperature drift)
68 // nextAverageAltMillis = nextAltMillis ; // in msec ; save when AverageAltitude has to be calculated
69 // nextAverageAltMillis = nextAltMillis ;
70 // static long lastResultPressure = 0 ; // used to replace a new pressure by an oldone if collected pressure is wrong (at some time we got wring values)
71 // static long lastResultTemp = 0 ; // idem for temperature
73 // climbRate2AltFloat = 0 ;
74 // climbRateFloat = 0 ;
76 #ifdef ALT_TEMP_COMPENSATION
77 alt_temp_compensation = ALT_TEMP_COMPENSATION ;
78 #endif
81 #ifdef DEBUGVARIO
82 printer->print(F("Vario Sensor:MS5611 I2C Addr="));
83 printer->println(_addr,HEX);
84 printer->print(F(" milli="));
85 printer->println(millis());
87 #endif
88 I2c.begin() ;
89 I2c.timeOut(80); //initialise the time out in order to avoid infinite loop
90 #ifdef DEBUGI2CMS5611
91 printer->println(F("begin I2C scan"));
92 I2c.scan() ;
93 printer->print(F("last I2C scan adr: "));
94 printer->println( I2c.scanAdr , HEX );
95 #endif
96 errorI2C = I2c.write( _addr,0x1e) ;
97 errorCalibration = false ;
98 if (errorI2C > 0 ) {
99 #ifdef DEBUGVARIO
100 printer->print(F("error code in setup I2CWrite: "));
101 printer->println( errorI2C );
102 #endif
103 errorCalibration = true ;
104 } else {
105 delay(100);
106 for (byte i = 1; i <=6; i++) {
107 errorI2C = I2c.read( _addr, 0xa0 + i*2, 2 ) ; //read 2 bytes from the device after sending the command A0 + xx depending on the register to be read
108 if ( errorI2C > 0 ) {
109 #ifdef DEBUGVARIO
110 printer->print(F("error code in setup I2CRead: "));
111 printer->println( errorI2C );
112 #endif
113 errorCalibration = true ;
114 } else {
115 high = I2c.receive() ;
116 low = I2c.receive() ;
117 _calibrationData[i] = high<<8 | low;
119 #ifdef DEBUGVARIO
120 printer->print(F("calibration data #"));
121 printer->print(i);
122 printer->print(F(" = "));
123 printer->print( _calibrationData[i] );
124 printer->print(F(" error= "));
125 printer->println( errorI2C );
126 #endif
127 } // End for
128 } // End if else
130 #ifdef DEBUGVARIO
131 printer->println(F("setup vario done."));
132 #endif
134 // resetValues(); // not used anymore (min, max, ...)
135 } //end of setup
138 //********************************************************************************************
139 //*** read the sensor ***
140 //********************************************************************************************
141 #define WAIT_I2C_TIME 9000 // normally we have to wait 9000 usec
143 bool OXS_MS5611::readSensor() { // read sensor performs a read from sensor if the delay since previous conversion command is enlapsed, else calculates once if data are available.
144 #ifdef DEBUGVARIOI2C
145 printer->print(F("sensorState= "));
146 printer->println(varioData.SensorState);
147 #endif
148 #ifdef DEBUG_VARIO_TIME
149 unsigned long varioEnter = micros() ;
150 #endif
151 bool newVSpeedCalculated = false ;
152 if ( ( micros() - varioData.lastCommandMicros )> WAIT_I2C_TIME ) { // wait 9 msec at least before asking for reading the pressure
153 long result = 0 ;
154 if( ! I2c.read( _addr, 0, 3 )) { ; //read 3 bytes from the device after sending a command "00";
155 result = I2c.receive() ;
156 result <<= 8 ;
157 result |= I2c.receive() ;
158 result <<= 8 ;
159 result |= I2c.receive() ;
160 } // result remain 0 if I2C is wrong
161 if (varioData.SensorState==0) { // ========================= We got the temperature
162 D2=result;
163 varioData.SensorState++ ;
164 I2c.write( _addr,0x48) ; // ask a conversion of Pressure
165 } else { // ========================= We got the Pressure
166 D1=result;
167 pressureMicros = micros(); // pressureMicros is the timestamp to calculate climbrate between 2 pressuresD2=result;
168 varioData.SensorState = 2 ;
169 I2c.write( _addr,0x58) ; // ask a conversion of Temperature
171 varioData.lastCommandMicros = micros() ; // save time of last command
172 } else {
173 if ( varioData.SensorState == 2 ) { // 2 means that previous call to read sensor got a Pressure
174 varioData.SensorState = 0 ; // reset state to 0 to allow reading the temperature
175 if ( (D1 > 0) && (D2 > 0) &&( millis() > 1000) ) { // we have all data and we can calculate
176 calculateVario() ;
177 newVSpeedCalculated = true ;
179 } // end ( varioData.SensorState == 2 )
181 #ifdef DEBUG_VARIO_TIME
182 varioEnter = micros() - varioEnter ;
183 if ( varioEnter > 10 ) {
184 Serial.print("Vario ") ; Serial.println(varioEnter) ; // when I2C works at 400 khz, it takes about 520 usec to read the temperature or the pressure and 450 usec to perform the calculation
186 #endif
187 return newVSpeedCalculated ; // return true if a new Vspeed is available
188 } // end read sensor
190 void OXS_MS5611::calculateVario() {
191 if (D2Prev == 0) D2Prev = D2 ;
192 D2Apply = (D2 + D2Prev ) >> 1 ;
193 D2Prev = D2 ;
194 dT = D2Apply - ((long)_calibrationData[5] << 8);
195 // TEMP = (2000 + (((int64_t)dT * (int64_t)_calibrationData[6]) >> 23)) / (float) 1.0 ;
196 varioData.temperature = (2000 + (((int64_t)dT * (int64_t)_calibrationData[6]) >> 23)) ;
197 // varioData.temperature= TEMP;
198 // OFF = (((int64_t)_calibrationData[2]) << 16) + ( (_calibrationData[4] * dT) >> 7);
199 OFF = (((int64_t)_calibrationData[2]) << 16) + ( ( (_calibrationData[4] - alt_temp_compensation ) * dT) >> 7);
200 SENS = (((int64_t)_calibrationData[1]) << 15) + ((_calibrationData[3] * dT) >> 8);
201 varioData.rawPressure= (((((((int64_t) D1) * (int64_t) SENS) >> 21) - OFF) * 10000 ) >> 15) ; // 1013.25 mb gives 1013250000 is a factor to keep higher precision (=1/100 cm).
203 // altitude = 44330 * (1.0 - pow(pressure /sealevelPressure,0.1903));
204 // other alternative (faster) = 1013.25 = 0 m , 954.61 = 500m , etc...
205 // Pressure Alt (m) Ratio
206 // 101325 0 0.08526603
207 // 95461 500 0.089525515
208 // 89876 1000 0.094732853
209 // 84598 1500 0.098039216
210 // 79498 2000 0.103906899
211 // 74686 2500 0.109313511
212 // 70112 3000 0.115101289
213 // 65768 3500 0.121270919
214 // 61645 4000 0.127811861
215 // 57733 4500 0.134843581
216 // 54025 5000
217 if ( varioData.rawPressure > 954610000) {
218 varioData.rawAltitude = ( 1013250000 - varioData.rawPressure ) * 0.08526603 ; // = 500 / (101325 - 95461) // returned value 1234567 means 123,4567 m (temp is fixed to 15 degree celcius)
219 } else if ( varioData.rawPressure > 898760000) {
220 varioData.rawAltitude = 5000000 + ( 954610000 - varioData.rawPressure ) * 0.089525515 ;
221 } else if ( varioData.rawPressure > 845980000) {
222 varioData.rawAltitude = 10000000 + ( 898760000 - varioData.rawPressure ) * 0.094732853 ;
223 } else if ( varioData.rawPressure > 794980000) {
224 varioData.rawAltitude = 15000000 + ( 845980000 - varioData.rawPressure ) * 0.098039216 ;
225 } else if ( varioData.rawPressure > 746860000) {
226 varioData.rawAltitude = 20000000 + ( 794980000 - varioData.rawPressure ) * 0.103906899 ;
227 } else if ( varioData.rawPressure > 701120000) {
228 varioData.rawAltitude = 25000000 + ( 746860000 - varioData.rawPressure ) * 0.109313511 ;
229 } else if ( varioData.rawPressure > 657680000) {
230 varioData.rawAltitude = 30000000 + ( 701120000 - varioData.rawPressure ) * 0.115101289 ;
231 } else if ( varioData.rawPressure > 616450000) {
232 varioData.rawAltitude = 35000000 + ( 657680000 - varioData.rawPressure ) * 0.121270919 ;
233 } else if ( varioData.rawPressure > 577330000) {
234 varioData.rawAltitude = 40000000 + ( 616450000 - varioData.rawPressure ) * 0.127811861 ;
235 } else { varioData.rawAltitude = 45000000 + ( 577330000 - varioData.rawPressure ) * 0.134843581 ;
238 // here the classical way to calculate Vspeed with high and low pass filter
239 if (altitude == 0) {
240 altitudeLowPass = altitudeHighPass = altitude = varioData.rawAltitude ;
242 altitude += 0.04 * (varioData.rawAltitude - altitude) ;
243 // varioData.altitudeAt20MsecAvailable = true ; // inform openxsens.ino that calculation of dTE can be performed
245 altitudeLowPass += 0.085 * ( varioData.rawAltitude - altitudeLowPass) ;
246 altitudeHighPass += 0.1 * ( varioData.rawAltitude - altitudeHighPass) ;
247 climbRate2AltFloat = ((altitudeHighPass - altitudeLowPass ) * 5666.685 ) / 20000 ;
249 abs_deltaClimbRate = abs(climbRate2AltFloat - varioData.climbRateFloat) ;
250 if ( varioData.sensitivityPpm > 0) sensitivityMin = varioData.sensitivityPpm ;
251 if ( (abs_deltaClimbRate <= SENSITIVITY_MIN_AT) || (sensitivityMin >= SENSITIVITY_MAX) ) {
252 varioData.sensitivity.value = sensitivityMin ;
253 } else if (abs_deltaClimbRate >= SENSITIVITY_MAX_AT) {
254 varioData.sensitivity.value = SENSITIVITY_MAX ;
255 } else {
256 varioData.sensitivity.value = sensitivityMin + ( SENSITIVITY_MAX - sensitivityMin ) * (abs_deltaClimbRate - SENSITIVITY_MIN_AT) / (SENSITIVITY_MAX_AT - SENSITIVITY_MIN_AT) ;
258 varioData.climbRateFloat += varioData.sensitivity.value * (climbRate2AltFloat - varioData.climbRateFloat) * 0.001 ; // sensitivity is an integer and must be divided by 1000
260 if ( abs((int32_t) varioData.climbRateFloat - varioData.climbRate.value) > VARIOHYSTERESIS ) {
261 //varioData.climbRate = (int32_t) varioData.climbRateFloat ;
262 varioData.climbRate.value = (int32_t) varioData.climbRateFloat ;
264 //varioData.climbRateAvailable=true; // allows SPORT protocol to transmit the value
265 varioData.climbRate.available=true; // allows SPORT protocol to transmit the value
266 // varioData.switchClimbRateAvailable = true ; // inform readsensors() that a switchable vspeed is available
267 // varioData.averageClimbRateAvailable = true ; // inform readsensors() that a vspeed is available to calculate the average
268 // AltitudeAvailable is set to true only once every 100 msec in order to give priority to climb rate on SPORT
269 altMillis = millis() ;
270 if (altMillis > nextAltMillis){
271 nextAltMillis = altMillis + 100 ;
272 varioData.absoluteAlt.value = altitude / 100 ; // altitude is in m *10000 and AbsoluteAlt must be in m * 100 (= cm)
273 varioData.absoluteAlt.available=true ; // Altitude is considered as available only after several loop in order to reduce number of transmission on Sport.
274 varioData.sensitivity.available = true ;
275 if (varioData.altOffset == 0) varioData.altOffset = varioData.absoluteAlt.value ;
276 varioData.relativeAlt.value = varioData.absoluteAlt.value - varioData.altOffset ;
277 varioData.relativeAlt.available = true ;
278 if ( varioData.relativeAlt.value > varioData.relativeAltMax ) varioData.relativeAltMax = varioData.relativeAlt.value ;
279 varioData.relativeAltMaxAvailable = true ;
281 // if ( altMillis > nextAverageAltMillis ){ // calculation of the difference of altitude (in m) between the 10 last sec
282 // nextAverageAltMillis = altMillis + 500 ; // calculate only once every 500 msec
283 // varioData.vSpeed10Sec = (varioData.absoluteAlt - varioData.prevAlt[varioData.idxPrevAlt]) /100 ;
284 // varioData.prevAlt[varioData.idxPrevAlt] = varioData.absoluteAlt ;
285 // varioData.idxPrevAlt++ ;
286 // if ( varioData.idxPrevAlt >= 20 ) varioData.idxPrevAlt = 0 ;
287 // if ( altMillis > 15000) { // make the data avalaible only after 15 sec)
288 // varioData.vSpeed10SecAvailable = true ;
289 // }
290 // }
292 } // end If (altMillis > nextAltMillis)
293 #ifdef DEBUG_VARIO_DATA
294 static bool firstPrintAlt = true ;
295 if (firstPrintAlt == true) {
296 firstPrintAlt = false ;
297 // printer->println(F( "T,Ra,Sm,A,NC,DS,AHP,ALP,CR2, Temp" )) ;
298 Serial.println(F( "T,Ra,Alt,vpsd, Alt2, rawVspd, vspd2 , smoothAlt, smoothVspd" )) ;
300 Serial.print( varioData.temperature ) ; printer->print(",");
301 Serial.print( (float) varioData.rawAltitude ) ; Serial.print(","); // alt is displayed in CM with 2 decimal
302 // printer->print( expoSmooth ) ; printer->print(" ,");
303 Serial.print( (float) altitude ) ; Serial.print(" ,");
304 Serial.print( varioData.climbRate.value ) ; Serial.print(" ,");
305 // printer->print( delaySmooth ) ; printer->print(" ,");
306 // printer->print( altitudeHighPass ) ; printer->print(" ,");
307 // printer->print( altitudeLowPass ) ; printer->print(" ,");
308 // printer->print( climbRate2AltFloat ) ; printer->print(" ,");
309 // printer->print( varioData.temperature ) ;
310 // printer->print( smoothAltitude ) ; printer->print(" ,");
311 // printer->print( rawRateVSpeed ) ; printer->print(" ,");
312 // printer->print( smoothRateVSpeed ) ; printer->print(" ,");
313 // printer->print( expoSmooth5611_alt_auto * 1000 ) ; printer->print(" ,");
314 // printer->print( expoSmooth5611_vSpeed_auto * 1000 ) ; printer->print(" ,");
315 Serial.println( ) ;
317 #endif
320 pressureMicrosPrev2 = pressureMicrosPrev1 ;
322 } // End of calculateVario
324 #endif // en of #if defined(SENSOR_IS_MS5611)
327 void OXS_MS5611::readSensor() {
328 long result = 0;
329 #ifdef DEBUGVARIOI2C
330 printer->print(F("sensorState= "));
331 printer->println(varioData.SensorState);
332 #endif
333 if (varioData.SensorState==1) { // ========================= Read the pressure
334 extended2Micros = micros() >> 1 ;
335 if (extended2Micros < varioData.lastCommand2Micros) extended2Micros = extended2Micros | 0x80000000 ;
336 if ( extended2Micros > (varioData.lastCommand2Micros + ( WAIT_I2C_TIME / 2 ) ) ) { // wait 9 msec at least before asking for reading the pressure
337 // long result = 0;
338 if( ! I2c.read( _addr, 0, 3 )) { ; //read 3 bytes from the device after sending a command "00"; keep previous value in case of error
339 result = I2c.receive() ;
340 result <<= 8 ;
341 result |= I2c.receive() ;
342 result <<= 8 ;
343 result |= I2c.receive() ;
344 D1=result;
345 } else {
346 D1 = 0 ; // D1 value are not processed to calculate Alt.
347 i2cPressureError++ ; // for debugging, count the number of read errors on pressure
349 i2cReadCount++ ; // for debugging I2C count the number of Pressure and Temperature reads
350 I2c.write( _addr,0x58) ; // ask a conversion of Temperature
351 varioData.lastCommand2Micros = (micros() >>1 );
352 varioData.SensorState = 2;
353 } // end of delay of 9 ms
354 } // end of SensorState == 1
355 else if (varioData.SensorState==2){ // =========================
356 extended2Micros = micros() >> 1 ;
357 if (extended2Micros < varioData.lastCommand2Micros) extended2Micros = extended2Micros | 0x80000000 ;
358 if ( extended2Micros > ( varioData.lastCommand2Micros + (WAIT_I2C_TIME / 2) )) { // wait 9000 usec to get Temp with high precision
359 if ( ! I2c.read( _addr, 0, 3 )) { ; //read 3 bytes from the device; keep previous value in case of error
360 result = I2c.receive() ;
361 result <<= 8 ;
362 result |= I2c.receive() ;
363 result <<= 8 ;
364 result |= I2c.receive() ;
365 D2=result;
366 } else {
367 i2cTemperatureError++ ; // for debugging, count the number of read errors on temperature
369 varioData.SensorState=0; //
370 } // End of process if temperature can be read
372 } // End of process if SensorState was 1 or 2
373 if (varioData.SensorState==0) { // ========================== new Pressure and (new or old) Temp are known so Request Pressure immediately and calculate altitude
374 I2c.write( _addr,0x48) ;// ask a conversion of Pressure
375 pressureMicrosPrev1 = pressureMicros ;
376 pressureMicros = micros(); // pressureMicros is the timestamp to calculate climbrate between 2 pressures
377 varioData.lastCommand2Micros = pressureMicros >> 1 ;
378 varioData.SensorState=1;
379 if ((D1 > 0) & (millis() > 1000) ) { // If D1 has been read in a previous loop and if sensor is started since more than 1 sec, then calculate pressure etc...
380 if (D2Prev == 0) D2Prev = D2 ;
381 D2Apply = (D2 + D2Prev ) / 2 ;
382 D2Prev = D2 ;
383 dT = D2Apply - ((long)_calibrationData[5] << 8);
384 // TEMP = (2000 + (((int64_t)dT * (int64_t)_calibrationData[6]) >> 23)) / (float) 1.0 ;
385 varioData.temperature = (2000 + (((int64_t)dT * (int64_t)_calibrationData[6]) >> 23)) ;
386 // varioData.temperature= TEMP;
387 // OFF = (((int64_t)_calibrationData[2]) << 16) + ( (_calibrationData[4] * dT) >> 7);
388 OFF = (((int64_t)_calibrationData[2]) << 16) + ( ( (_calibrationData[4] - alt_temp_compensation ) * dT) >> 7);
389 SENS = (((int64_t)_calibrationData[1]) << 15) + ((_calibrationData[3] * dT) >> 8);
390 varioData.rawPressure= (((((((int64_t) D1) * (int64_t) SENS) >> 21) - OFF) * 10000 ) >> 15) ; // 1013.25 mb gives 1013250000 is a factor to keep higher precision (=1/100 cm).
392 // altitude = 44330 * (1.0 - pow(pressure /sealevelPressure,0.1903));
393 // other alternative (faster) = 1013.25 = 0 m , 954.61 = 500m , etc...
394 // Pressure Alt (m) Ratio
395 // 101325 0 0.08526603
396 // 95461 500 0.089525515
397 // 89876 1000 0.094732853
398 // 84598 1500 0.098039216
399 // 79498 2000 0.103906899
400 // 74686 2500 0.109313511
401 // 70112 3000 0.115101289
402 // 65768 3500 0.121270919
403 // 61645 4000 0.127811861
404 // 57733 4500 0.134843581
405 // 54025 5000
407 if ( varioData.rawPressure > 954610000) {
408 varioData.rawAltitude = ( 1013250000 - varioData.rawPressure ) * 0.08526603 ; // = 500 / (101325 - 95461) // returned value 1234567 means 123,4567 m (temp is fixed to 15 degree celcius)
409 } else if ( varioData.rawPressure > 898760000) {
410 varioData.rawAltitude = 5000000 + ( 954610000 - varioData.rawPressure ) * 0.089525515 ;
411 } else if ( varioData.rawPressure > 845980000) {
412 varioData.rawAltitude = 10000000 + ( 898760000 - varioData.rawPressure ) * 0.094732853 ;
413 } else if ( varioData.rawPressure > 794980000) {
414 varioData.rawAltitude = 15000000 + ( 845980000 - varioData.rawPressure ) * 0.098039216 ;
415 } else if ( varioData.rawPressure > 746860000) {
416 varioData.rawAltitude = 20000000 + ( 794980000 - varioData.rawPressure ) * 0.103906899 ;
417 } else if ( varioData.rawPressure > 701120000) {
418 varioData.rawAltitude = 25000000 + ( 746860000 - varioData.rawPressure ) * 0.109313511 ;
419 } else if ( varioData.rawPressure > 657680000) {
420 varioData.rawAltitude = 30000000 + ( 701120000 - varioData.rawPressure ) * 0.115101289 ;
421 } else if ( varioData.rawPressure > 616450000) {
422 varioData.rawAltitude = 35000000 + ( 657680000 - varioData.rawPressure ) * 0.121270919 ;
423 } else if ( varioData.rawPressure > 577330000) {
424 varioData.rawAltitude = 40000000 + ( 616450000 - varioData.rawPressure ) * 0.127811861 ;
425 } else { varioData.rawAltitude = 45000000 + ( 577330000 - varioData.rawPressure ) * 0.134843581 ;
428 // here the classical way to calculate Vspeed with high and low pass filter
429 if (altitude == 0) {
430 altitudeLowPass = altitudeHighPass = altitude = varioData.rawAltitude ;
431 pressureMicrosPrev2 = pressureMicrosPrev1 - 20000 ;
433 altitude += 0.04 * (varioData.rawAltitude - altitude) ;
434 varioData.altitudeAt20MsecAvailable = true ; // inform openxsens.ino that calculation of dTE can be performed
436 altitudeLowPass += 0.085 * ( varioData.rawAltitude - altitudeLowPass) ;
437 altitudeHighPass += 0.1 * ( varioData.rawAltitude - altitudeHighPass) ;
438 if (pressureMicrosPrev1 > pressureMicrosPrev2 ) varioData.delaySmooth += 0.1 * ( pressureMicrosPrev1 - pressureMicrosPrev2 - varioData.delaySmooth ) ; //delay between 2 measures only if there is no overflow of pressureMicos
439 climbRate2AltFloat = ((altitudeHighPass - altitudeLowPass ) * 5666.685 ) / varioData.delaySmooth;
441 abs_deltaClimbRate = abs(climbRate2AltFloat - varioData.climbRateFloat) ;
442 if ( varioData.sensitivityPpm > 0) sensitivityMin = varioData.sensitivityPpm ;
443 if ( (abs_deltaClimbRate <= SENSITIVITY_MIN_AT) || (sensitivityMin >= SENSITIVITY_MAX) ) {
444 varioData.sensitivity = sensitivityMin ;
445 } else if (abs_deltaClimbRate >= SENSITIVITY_MAX_AT) {
446 varioData.sensitivity = SENSITIVITY_MAX ;
447 } else {
448 varioData.sensitivity = sensitivityMin + ( SENSITIVITY_MAX - sensitivityMin ) * (abs_deltaClimbRate - SENSITIVITY_MIN_AT) / (SENSITIVITY_MAX_AT - SENSITIVITY_MIN_AT) ;
450 varioData.climbRateFloat += varioData.sensitivity * (climbRate2AltFloat - varioData.climbRateFloat) * 0.001 ; // sensitivity is an integer and must be divided by 1000
452 if ( abs((int32_t) varioData.climbRateFloat - varioData.climbRate) > VARIOHYSTERESIS ) {
453 varioData.climbRate = (int32_t) varioData.climbRateFloat ;
455 varioData.climbRateAvailable=true; // allows SPORT protocol to transmit the value
456 varioData.switchClimbRateAvailable = true ; // inform readsensors() that a switchable vspeed is available
457 varioData.averageClimbRateAvailable = true ; // inform readsensors() that a vspeed is available to calculate the average
458 // AltitudeAvailable is set to true only once every 100 msec in order to give priority to climb rate on SPORT
459 altMillis = millis() ;
460 if (altMillis > nextAltMillis){
461 nextAltMillis = altMillis + 100 ;
462 varioData.absoluteAlt = altitude / 100 ; // altitude is in m *10000 and AbsoluteAlt must be in m * 100
463 varioData.absoluteAltAvailable=true ; // Altitude is considered as available only after several loop in order to reduce number of transmission on Sport.
464 varioData.sensitivityAvailable = true ;
465 if (varioData.altOffset == 0) varioData.altOffset = varioData.absoluteAlt ;
466 varioData.relativeAlt = varioData.absoluteAlt - varioData.altOffset ;
467 varioData.relativeAltAvailable = true ;
468 if ( varioData.relativeAlt > varioData.relativeAltMax ) varioData.relativeAltMax = varioData.relativeAlt ;
469 varioData.relativeAltMaxAvailable = true ;
471 // if ( altMillis > nextAverageAltMillis ){ // calculation of the difference of altitude (in m) between the 10 last sec
472 // nextAverageAltMillis = altMillis + 500 ; // calculate only once every 500 msec
473 // varioData.vSpeed10Sec = (varioData.absoluteAlt - varioData.prevAlt[varioData.idxPrevAlt]) /100 ;
474 // varioData.prevAlt[varioData.idxPrevAlt] = varioData.absoluteAlt ;
475 // varioData.idxPrevAlt++ ;
476 // if ( varioData.idxPrevAlt >= 20 ) varioData.idxPrevAlt = 0 ;
477 // if ( altMillis > 15000) { // make the data avalaible only after 15 sec)
478 // varioData.vSpeed10SecAvailable = true ;
479 // }
480 // }
482 } // end If (altMillis > nextAltMillis)
483 #ifdef DEBUGDATA
484 static bool firstPrintAlt = true ;
485 if (firstPrintAlt == true) {
486 firstPrintAlt = false ;
487 // printer->println(F( "T,Ra,Sm,A,NC,DS,AHP,ALP,CR2, Temp" )) ;
488 printer->println(F( "T,Ra,Alt,vpsd, Alt2, rawVspd, vspd2 , smoothAlt, smoothVspd" )) ;
490 printer->print( pressureMicrosPrev1 ) ; printer->print(",");
491 printer->print( (float) varioData.rawAltitude ) ; printer->print(","); // alt is displayed in CM with 2 decimal
492 // printer->print( expoSmooth ) ; printer->print(" ,");
493 printer->print( (float) altitude ) ; printer->print(" ,");
494 printer->print( varioData.climbRate ) ; printer->print(" ,");
495 // printer->print( delaySmooth ) ; printer->print(" ,");
496 // printer->print( altitudeHighPass ) ; printer->print(" ,");
497 // printer->print( altitudeLowPass ) ; printer->print(" ,");
498 // printer->print( climbRate2AltFloat ) ; printer->print(" ,");
499 // printer->print( varioData.temperature ) ;
500 // printer->print( smoothAltitude ) ; printer->print(" ,");
501 // printer->print( rawRateVSpeed ) ; printer->print(" ,");
502 // printer->print( smoothRateVSpeed ) ; printer->print(" ,");
503 // printer->print( expoSmooth5611_alt_auto * 1000 ) ; printer->print(" ,");
504 // printer->print( expoSmooth5611_vSpeed_auto * 1000 ) ; printer->print(" ,");
505 printer->println( ) ;
507 #endif
510 pressureMicrosPrev2 = pressureMicrosPrev1 ;
511 } // end of D1 > 0 & time > 3 sec
512 } // End of process if SensorState was 0
513 } // End of readSensor