Mercurial > public > ostc4
view Small_CPU/Src/externalInterface.c @ 797:acf6614dc396
Use mirror sensortype for visualization:
The visualization of O2 sensor data is still based on the three slots. To make the usage of these slots more transparent and easy "mirror" sensortypes have been introduced. These types may be used within the refresh to switch the source. E.g. if only one or two slots are used for O2 values the the third may be used for CO2 data. By using the mirror the datastream does no longer need to be manipulated (copying Co2data in variables named O2xyz).
author | Ideenmodellierer |
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date | Mon, 31 Jul 2023 20:10:27 +0200 |
parents | bb37d4f3e50e |
children | e9eba334b942 |
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/** ****************************************************************************** * @file externalInterface.c * @author heinrichs weikamp gmbh * @version V0.0.1 * @date 07-Nov-2020 * @brief Interface functionality to proceed external analog signal via i2c connection * @verbatim ============================================================================== ##### stm32f4xx_hal_i2c.c modification ##### ============================================================================== The LTC2942 requires an repeated start condition without stop condition for data reception. @endverbatim ****************************************************************************** * @attention * * <h2><center>© COPYRIGHT(c) 2014 heinrichs weikamp</center></h2> * ****************************************************************************** */ /* Includes ------------------------------------------------------------------*/ #include <math.h> #include <string.h> #include "data_central.h" #include "i2c.h" #include "externalInterface.h" #include "scheduler.h" #include "uart.h" #include "data_exchange.h" #include "pressure.h" #include "uartProtocol_O2.h" extern SGlobal global; extern UART_HandleTypeDef huart1; #define ADC_ANSWER_LENGTH (5u) /* 3424 will provide addr + 4 data bytes */ #define ADC_TIMEOUT (10u) /* conversion stuck for unknown reason => restart */ #define ADC_REF_VOLTAGE_MV (2048.0f) /* reference voltage of MPC3424*/ #define ADC_START_CONVERSION (0x80) #define ADC_GAIN_4 (0x02) #define ADC_GAIN_4_VALUE (4.0f) #define ADC_GAIN_8 (0x03) #define ADC_GAIN_8_VALUE (8.0f) #define ADC_RESOLUTION_16BIT (0x08) #define ADC_RESOLUTION_16BIT_VALUE (16u) #define ADC_RESOLUTION_18BIT (0x0C) #define ADC_RESOLUTION_18BIT_VALUE (18u) #define ANSWER_CONFBYTE_INDEX (4u) #define LOOKUP_CO2_CORR_TABLE_SCALE (1000u) #define LOOKUP_CO2_CORR_TABLE_MAX (30000u) #define REQUEST_INT_SENSOR_MS (1500) /* Minimum time interval for cyclic sensor data requests per sensor (UART mux) */ #define COMMAND_TX_DELAY (30u) /* The time the sensor needs to recover from a invalid command request */ #define TIMEOUT_SENSOR_ANSWER (300) /* Time till a request is repeated if no answer was received */ #define activeSensorId (activeUartChannel + EXT_INTERFACE_MUX_OFFSET) /* Used if UART channels are applied to Sensor map */ static uint8_t activeChannel = 0; /* channel which is in request */ static uint8_t recBuf[ADC_ANSWER_LENGTH]; static uint8_t timeoutCnt = 0; static uint8_t externalInterfacePresent = 0; float externalChannel_mV[MAX_ADC_CHANNEL]; static uint8_t externalV33_On = 0; static uint8_t externalADC_On = 0; static uint8_t externalUART_Protocol = 0; static uint16_t externalCO2Value; static uint16_t externalCO2SignalStrength; static uint16_t externalCO2Status = 0; static float externalCO2Scale = 0.0; static uint8_t lastSensorDataId = 0; static SSensorDataDiveO2 sensorDataDiveO2[EXT_INTERFACE_SENSOR_CNT]; static externalInterfaceAutoDetect_t externalAutoDetect = DETECTION_OFF; static externalInterfaceSensorType SensorMap[EXT_INTERFACE_SENSOR_CNT] ={ SENSOR_OPTIC, SENSOR_OPTIC, SENSOR_OPTIC, SENSOR_NONE, SENSOR_NONE}; static externalInterfaceSensorType tmpSensorMap[EXT_INTERFACE_SENSOR_CNT]; static externalInterfaceSensorType MasterSensorMap[EXT_INTERFACE_SENSOR_CNT]; static externalInterfaceSensorType foundSensorMap[EXT_INTERFACE_SENSOR_CNT]; static uint8_t Mux2ADCMap[MAX_ADC_CHANNEL]; static uint8_t externalInterface_SensorState[EXT_INTERFACE_SENSOR_CNT]; static float LookupCO2PressureCorrection[LOOKUP_CO2_CORR_TABLE_MAX / LOOKUP_CO2_CORR_TABLE_SCALE]; /* lookup table for pressure compensation values */ static uint16_t externalInterfaceMuxReqIntervall = 0; /* delay between switching from one MUX channel to the next */ static uint8_t activeUartChannel = 0; /* Index of the sensor port which is selected by the mux or 0 if no mux is connected */ void externalInterface_Init(void) { uint16_t index; uint16_t coeff; activeChannel = 0; timeoutCnt = 0; externalInterfacePresent = 0; if(externalInterface_StartConversion(activeChannel) == HAL_OK) { externalInterfacePresent = 1; global.deviceDataSendToMaster.hw_Info.extADC = 1; } global.deviceDataSendToMaster.hw_Info.checkADC = 1; memset(Mux2ADCMap,0xFF, sizeof(Mux2ADCMap)); /* Create a lookup table based on GSS application note AN001: PRESSURE COMPENSATION OF A CO2 SENSOR */ /* The main purpose of the sensor in the dive application is to be a warning indicator */ /* => no exact values necessary => a lookup table with 1000ppm scaling should be sufficient */ LookupCO2PressureCorrection [0] = -0.0014; for(index = 1; index < (LOOKUP_CO2_CORR_TABLE_MAX / LOOKUP_CO2_CORR_TABLE_SCALE); index++) { coeff = index * LOOKUP_CO2_CORR_TABLE_SCALE; LookupCO2PressureCorrection[index] = 2.811*pow(10,-38)*pow(coeff,6)- 9.817*pow(10,-32)*pow(coeff,5)+1.304*pow(10,-25)*pow(coeff,4)-8.216*pow(10,-20)*pow(coeff,3)+2.311*pow(10,-14)*pow(coeff,2) - 2.195*pow(10,-9)*coeff - 1.471*pow(10,-3); } externalInterface_InitDatastruct(); } void externalInterface_InitDatastruct(void) { uint8_t index = 0; /* init data values */ externalV33_On = 0; externalCO2Value = 0; externalCO2SignalStrength = 0; externalCO2Status = 0; externalAutoDetect = DETECTION_OFF; for(index = 0; index < MAX_ADC_CHANNEL; index++) { externalChannel_mV[index] = 0.0; } memset(externalInterface_SensorState,UART_O2_INIT,sizeof(externalInterface_SensorState)); } uint8_t externalInterface_StartConversion(uint8_t channel) { uint8_t retval = 0; uint8_t confByte = 0; if(channel < MAX_ADC_CHANNEL) { confByte = ADC_START_CONVERSION | ADC_RESOLUTION_16BIT | ADC_GAIN_8; confByte |= channel << 5; retval = I2C_Master_Transmit(DEVICE_EXTERNAL_ADC, &confByte, 1); } return retval; } /* Check if conversion is done and trigger measurement of next channel */ uint8_t externalInterface_ReadAndSwitch() { uint8_t retval = EXTERNAL_ADC_NO_DATA; uint8_t nextChannel; uint8_t* psensorMap = externalInterface_GetSensorMapPointer(0); if(externalADC_On) { if(I2C_Master_Receive(DEVICE_EXTERNAL_ADC, recBuf, ADC_ANSWER_LENGTH) == HAL_OK) { if((recBuf[ANSWER_CONFBYTE_INDEX] & ADC_START_CONVERSION) == 0) /* !ready set => received data contains new value */ { retval = activeChannel; /* return channel number providing new data */ nextChannel = activeChannel + 1; if(nextChannel == MAX_ADC_CHANNEL) { nextChannel = 0; } while((psensorMap[nextChannel] != SENSOR_ANALOG) && (nextChannel != activeChannel)) { if(nextChannel == MAX_ADC_CHANNEL) { nextChannel = 0; } else { nextChannel++; } } activeChannel = nextChannel; externalInterface_StartConversion(activeChannel); timeoutCnt = 0; } else { if(timeoutCnt++ >= ADC_TIMEOUT) { externalInterface_StartConversion(activeChannel); timeoutCnt = 0; } } } else /* take also i2c bus disturb into account */ { if(timeoutCnt++ >= ADC_TIMEOUT) { externalInterface_StartConversion(activeChannel); timeoutCnt = 0; } } } return retval; } float externalInterface_CalculateADCValue(uint8_t channel) { int32_t rawvalue = 0; float retValue = 0.0; if(channel < MAX_ADC_CHANNEL) { rawvalue = ((recBuf[0] << 16) | (recBuf[1] << 8) | (recBuf[2])); switch(recBuf[3] & 0x0C) /* confbyte => Resolution bits*/ { case ADC_RESOLUTION_16BIT: rawvalue = rawvalue >> 8; /* only 2 databytes received shift out confbyte*/ if(rawvalue & (0x1 << (ADC_RESOLUTION_16BIT_VALUE-1))) /* MSB set => negative number */ { rawvalue |= 0xFFFF0000; /* set MSB for int32 */ } else { rawvalue &= 0x0000FFFF; } externalChannel_mV[channel] = ADC_REF_VOLTAGE_MV * 2.0 / (float) pow(2,ADC_RESOLUTION_16BIT_VALUE); /* calculate bit resolution */ break; case ADC_RESOLUTION_18BIT: if(rawvalue & (0x1 << (ADC_RESOLUTION_18BIT_VALUE-1))) /* MSB set => negative number */ { rawvalue |= 0xFFFE0000; /* set MSB for int32 */ } externalChannel_mV[channel] = ADC_REF_VOLTAGE_MV * 2.0 / (float) pow(2,ADC_RESOLUTION_18BIT_VALUE); /* calculate bit resolution */ break; default: rawvalue = 0; break; } externalChannel_mV[channel] = externalChannel_mV[channel] * rawvalue / ADC_GAIN_8_VALUE; retValue = externalChannel_mV[channel]; } return retValue; } float getExternalInterfaceChannel(uint8_t channel) { float retval = 0; if(channel < MAX_ADC_CHANNEL) { retval = externalChannel_mV[channel]; } return retval; } uint8_t setExternalInterfaceChannel(uint8_t channel, float value) { uint8_t retval = 0; uint8_t localId = channel; uint8_t index = 0; if(localId >= MAX_ADC_CHANNEL) /* at the moment sensor visualization is focused on the three ADC channels => map Mux sensors */ { for(index = 0; index < MAX_ADC_CHANNEL; index++) { if(Mux2ADCMap[index] == localId) { localId = index; break; } } } if(localId < MAX_ADC_CHANNEL) { externalChannel_mV[localId] = value; retval = 1; } return retval; } void externalInterface_InitPower33(void) { GPIO_InitTypeDef GPIO_InitStructure; GPIO_InitStructure.Pin = GPIO_PIN_7; GPIO_InitStructure.Mode = GPIO_MODE_OUTPUT_PP; GPIO_InitStructure.Pull = GPIO_PULLUP; GPIO_InitStructure.Speed = GPIO_SPEED_LOW; HAL_GPIO_Init(GPIOC, &GPIO_InitStructure); HAL_GPIO_WritePin(GPIOC,GPIO_PIN_7,GPIO_PIN_SET); } uint8_t externalInterface_isEnabledPower33() { return externalV33_On; } uint8_t externalInterface_isEnabledADC() { return externalADC_On; } uint8_t externalInterface_GetUARTProtocol() { return externalUART_Protocol; } void externalInterface_SwitchPower33(uint8_t state) { if(state != externalV33_On) { if(state) { HAL_GPIO_WritePin(GPIOC,GPIO_PIN_7,GPIO_PIN_RESET); externalV33_On = 1; } else { if(externalAutoDetect == DETECTION_OFF) { HAL_GPIO_WritePin(GPIOC,GPIO_PIN_7,GPIO_PIN_SET); externalV33_On = 0; externalInterface_SetCO2Value(0); externalInterface_SetCO2SignalStrength(0); } } } } void externalInterface_SwitchADC(uint8_t state) { uint8_t loop = 0; if((state) && (externalInterfacePresent)) { if(externalADC_On == 0) { activeChannel = 0; externalInterface_StartConversion(activeChannel); externalADC_On = 1; } } else { if(externalAutoDetect == DETECTION_OFF) /* block deactivation requests if auto detection is active */ { externalADC_On = 0; for(loop = 0; loop < MAX_ADC_CHANNEL; loop++) { externalChannel_mV[loop] = 0; } } } } void externalInterface_SwitchUART(uint8_t protocol) { switch(protocol) { case 0: case (EXT_INTERFACE_UART_CO2 >> 8): case (EXT_INTERFACE_UART_O2 >> 8): case (EXT_INTERFACE_UART_SENTINEL >> 8): if((externalAutoDetect <= DETECTION_START) || ((protocol == EXT_INTERFACE_UART_O2 >> 8) && (externalAutoDetect == DETECTION_DIGO2_0)) || ((protocol == EXT_INTERFACE_UART_O2 >> 8) && (externalAutoDetect == DETECTION_DIGO2_1)) || ((protocol == EXT_INTERFACE_UART_O2 >> 8) && (externalAutoDetect == DETECTION_DIGO2_2)) || ((protocol == EXT_INTERFACE_UART_O2 >> 8) && (externalAutoDetect == DETECTION_DIGO2_3)) || ((protocol == EXT_INTERFACE_UART_O2 >> 8) && (externalAutoDetect == DETECTION_UARTMUX)) #ifdef ENABLE_CO2_SUPPORT || ((protocol == EXT_INTERFACE_UART_CO2 >> 8) && (externalAutoDetect == DETECTION_CO2)) #endif #ifdef ENABLE_SENTINEL_MODE || ((protocol == EXT_INTERFACE_UART_SENTINEL >> 8) && (externalAutoDetect == DETECTION_SENTINEL)) #endif ) { lastSensorDataId = 0; externalUART_Protocol = protocol; MX_USART1_UART_DeInit(); if( protocol != 0) { MX_USART1_UART_Init(); } } break; default: break; } } uint8_t externalInterface_GetActiveUartSensor() { return activeUartChannel; } void externalInterface_SetSensorState(uint8_t sensorIdx, uint8_t state) { if(sensorIdx < EXT_INTERFACE_SENSOR_CNT) { externalInterface_SensorState[sensorIdx] = state; } } uint8_t externalInterface_GetSensorState(uint8_t sensorIdx) { uint8_t ret = COMMON_SENSOR_STATE_INVALID; if(sensorIdx < EXT_INTERFACE_SENSOR_CNT) { ret = externalInterface_SensorState[sensorIdx]; } return ret; } /* The supported sensors from GSS have different scaling factors depending on their accuracy. The factor may be read out of the sensor */ void externalInterface_SetCO2Scale(float CO2Scale) { if((CO2Scale == 10) || (CO2Scale == 100)) { externalCO2Scale = CO2Scale; } } float externalInterface_GetCO2Scale() { return externalCO2Scale; } void externalInterface_SetCO2Value(uint16_t CO2_ppm) { float local_ppm = CO2_ppm * externalCO2Scale; #ifndef ENABLE_EXTERNAL_PRESSURE float local_corr = 0.0; if (local_ppm >= LOOKUP_CO2_CORR_TABLE_MAX) { local_corr = -0.0014; } else { local_corr = LookupCO2PressureCorrection[((uint16_t) (local_ppm / LOOKUP_CO2_CORR_TABLE_SCALE))]; } local_ppm = local_ppm / (1.0 + (local_corr * (get_surface_mbar() - get_pressure_mbar()))); #else /* The external pressure value is passed via ADC channel2 and calibration is done at firmware => just forward sensor data */ /* compensation is done at firmware side. This is for testing only. Take care the the same algorithm is taken as used for the lookup table */ #endif externalCO2Value = local_ppm / externalCO2Scale; } void externalInterface_SetCO2SignalStrength(uint16_t LED_qa) { externalCO2SignalStrength = LED_qa; } uint16_t externalInterface_GetCO2Value(void) { return externalCO2Value; } uint16_t externalInterface_GetCO2SignalStrength(void) { return externalCO2SignalStrength; } void externalInterface_SetCO2State(uint16_t state) { externalCO2Status = state; } uint16_t externalInterface_GetCO2State(void) { return externalCO2Status; } uint8_t externalInterface_GetSensorData(uint8_t sensorId, uint8_t* pDataStruct) { uint8_t index = 0; uint8_t localId = sensorId; if(localId == 0xFF) { localId = lastSensorDataId; } if((pDataStruct != NULL) && (localId <= EXT_INTERFACE_SENSOR_CNT)) { memcpy(pDataStruct, &sensorDataDiveO2[localId], sizeof(SSensorDataDiveO2)); } else { localId = 0xFF; } if(localId > MAX_ADC_CHANNEL) /* at the moment sensor visualization is focused on the three ADC channels => map Mux sensors */ { for(index = 0; index < MAX_ADC_CHANNEL; index++) { if(Mux2ADCMap[index] == localId) { localId = index; } } } return localId; } void externalInterface_SetSensorData(uint8_t sensorId, uint8_t* pDataStruct) { uint8_t index = 0; if(pDataStruct != NULL) { if((sensorId != 0xFF) && (sensorId < EXT_INTERFACE_SENSOR_CNT)) { memcpy(&sensorDataDiveO2[sensorId], pDataStruct, sizeof(SSensorDataDiveO2)); lastSensorDataId = sensorId; for(index = 0; index < MAX_MUX_CHANNEL; index++) { if(Mux2ADCMap[index] == sensorId) { memcpy(&sensorDataDiveO2[index], pDataStruct, sizeof(SSensorDataDiveO2)); lastSensorDataId = index; break; } } } else { memset(&sensorDataDiveO2,0,sizeof(sensorDataDiveO2)); lastSensorDataId = 0xFF; } } } void externalInface_SetSensorMap(uint8_t* pMap) { if(pMap != NULL) { memcpy(MasterSensorMap, pMap, EXT_INTERFACE_SENSOR_CNT); /* the map is not directly copied. Copy is done via cmd request */ } } uint8_t* externalInterface_GetSensorMapPointer(uint8_t finalMap) { uint8_t* pret; if((externalAutoDetect != DETECTION_OFF) && (!finalMap)) { pret = tmpSensorMap; } else { pret = SensorMap; } return pret; } void externalInterface_AutodetectSensor() { static uint8_t sensorIndex = 0; static uint8_t uartMuxChannel = 0; uint8_t index = 0; uint8_t index2 = 0; uint8_t cntSensor = 0; uint8_t cntUARTSensor = 0; uint8_t cmdString[10]; uint8_t cmdLength = 0; if(externalAutoDetect != DETECTION_OFF) { switch(externalAutoDetect) { case DETECTION_INIT: externalInterfaceMuxReqIntervall = 1100; sensorIndex = 0; uartMuxChannel = 0; tmpSensorMap[0] = SENSOR_OPTIC; tmpSensorMap[1] = SENSOR_OPTIC; tmpSensorMap[2] = SENSOR_OPTIC; tmpSensorMap[3] = SENSOR_NONE; tmpSensorMap[4] = SENSOR_NONE; memset(foundSensorMap, SENSOR_NONE, sizeof(foundSensorMap)); memset(externalInterface_SensorState,UART_O2_INIT,sizeof(externalInterface_SensorState)); memset(Mux2ADCMap,0, sizeof(Mux2ADCMap)); if(externalInterfacePresent) { externalInterface_SwitchPower33(0); externalInterface_SwitchUART(0); for(index = 0; index < MAX_ADC_CHANNEL; index++) { externalChannel_mV[index] = 0; } externalAutoDetect = DETECTION_START; } else { externalAutoDetect = DETECTION_DONE; /* without external interface O2 values may only be received via optical port => return default sensor map */ } break; case DETECTION_START: tmpSensorMap[0] = SENSOR_ANALOG; tmpSensorMap[1] = SENSOR_ANALOG; tmpSensorMap[2] = SENSOR_ANALOG; externalInterface_SwitchPower33(1); externalInterface_SwitchADC(1); externalAutoDetect = DETECTION_ANALOG1; break; case DETECTION_ANALOG1: externalAutoDetect = DETECTION_ANALOG2; /* do a second loop to make sure all adc channels could be processed */ break; case DETECTION_ANALOG2: for(index = 0; index < MAX_ADC_CHANNEL; index++) { if(externalChannel_mV[index] > MIN_ADC_VOLTAGE_MV) { tmpSensorMap[sensorIndex++] = SENSOR_ANALOG; foundSensorMap[index] = SENSOR_ANALOG; } else { tmpSensorMap[sensorIndex++] = SENSOR_NONE; } } externalAutoDetect = DETECTION_UARTMUX; externalInterface_SwitchUART(EXT_INTERFACE_UART_O2 >> 8); UART_MUX_SelectAddress(MAX_MUX_CHANNEL); uartO2_SetChannel(MAX_MUX_CHANNEL); activeUartChannel = MAX_MUX_CHANNEL; tmpSensorMap[EXT_INTERFACE_SENSOR_CNT-1] = SENSOR_MUX; break; case DETECTION_UARTMUX: if(uartO2_isSensorConnected()) { uartMuxChannel = 1; tmpSensorMap[EXT_INTERFACE_SENSOR_CNT-1] = SENSOR_MUX; foundSensorMap[EXT_INTERFACE_SENSOR_CNT-1] = SENSOR_MUX; } else { tmpSensorMap[EXT_INTERFACE_SENSOR_CNT-1] = SENSOR_NONE; } externalAutoDetect = DETECTION_DIGO2_0; externalInterface_SwitchUART(EXT_INTERFACE_UART_O2 >> 8); UART_MUX_SelectAddress(0); uartO2_SetChannel(0); activeUartChannel = 0; tmpSensorMap[EXT_INTERFACE_MUX_OFFSET] = SENSOR_DIGO2; externalInterface_SensorState[EXT_INTERFACE_MUX_OFFSET] = UART_O2_INIT; externalInterface_SwitchUART(EXT_INTERFACE_UART_O2 >> 8); break; case DETECTION_DIGO2_0: case DETECTION_DIGO2_1: case DETECTION_DIGO2_2: case DETECTION_DIGO2_3: if(uartO2_isSensorConnected()) { foundSensorMap[externalAutoDetect - DETECTION_DIGO2_0 + EXT_INTERFACE_MUX_OFFSET] = SENSOR_DIGO2; } if(uartMuxChannel) { externalInterface_SwitchUART(EXT_INTERFACE_UART_O2 >> 8); UART_MUX_SelectAddress(uartMuxChannel); externalInterface_SensorState[uartMuxChannel + EXT_INTERFACE_MUX_OFFSET] = UART_O2_INIT; uartO2_SetChannel(uartMuxChannel); activeUartChannel = uartMuxChannel; tmpSensorMap[uartMuxChannel - 1 + EXT_INTERFACE_MUX_OFFSET] = SENSOR_NONE; tmpSensorMap[uartMuxChannel + EXT_INTERFACE_MUX_OFFSET] = SENSOR_DIGO2; if(uartMuxChannel < MAX_MUX_CHANNEL - 1) { uartMuxChannel++; } } else { externalAutoDetect = DETECTION_DIGO2_3; /* skip detection of other serial sensors */ } externalAutoDetect++; #ifdef ENABLE_CO2_SUPPORT if(externalAutoDetect == DETECTION_CO2) { externalInterface_SwitchUART(EXT_INTERFACE_UART_CO2 >> 8); if(tmpSensorMap[EXT_INTERFACE_SENSOR_CNT-1] == SENSOR_MUX) /* switch sensor operation mode depending on HW config */ { DigitalCO2_SendCmd(CO2CMD_MODE_POLL, cmdString, &cmdLength); } else { DigitalCO2_SendCmd(CO2CMD_MODE_STREAM, cmdString, &cmdLength); } } break; case DETECTION_CO2: if(UART_isCO2Connected()) { for(index = 0; index < 3; index++) /* lookup a channel which may be used by CO2*/ { if(tmpSensorMap[index] == SENSOR_NONE) { break; } } if(index == 3) { tmpSensorMap[sensorIndex++] = SENSOR_CO2; /* place Co2 sensor behind O2 sensors (not visible) */ } else { tmpSensorMap[index] = SENSOR_CO2; } } externalAutoDetect++; #endif #ifdef ENABLE_SENTINEL_MODE if(externalAutoDetect == DETECTION_SENTINEL) { externalInterface_SwitchUART(EXT_INTERFACE_UART_SENTINEL >> 8); UART_StartDMA_Receiption(); } break; case DETECTION_SENTINEL: case DETECTION_SENTINEL2: if(UART_isSentinelConnected()) { for(index = 0; index < 3; index++) /* Sentinel is occupiing all sensor slots */ { tmpSensorMap[index] = SENSOR_SENTINEL; } sensorIndex = 3; } externalAutoDetect++; #endif break; case DETECTION_DONE: externalAutoDetect = DETECTION_OFF; externalInterface_SwitchUART(0); activeUartChannel = 0xFF; cntSensor = 0; cntUARTSensor = 0; for(index = 0; index < EXT_INTERFACE_SENSOR_CNT-1; index++) { if((foundSensorMap[index] >= SENSOR_ANALOG) && (foundSensorMap[index] < SENSOR_TYPE_O2_END)) { cntSensor++; } if((foundSensorMap[index] == SENSOR_DIGO2) || (foundSensorMap[index] == SENSOR_CO2)) { cntUARTSensor++; } /* Map Mux O2 sensors to ADC Slot if ADC slot is not in use */ if(foundSensorMap[index] == SENSOR_DIGO2) { for(index2 = 0; index2 < MAX_ADC_CHANNEL; index2++) { if(foundSensorMap[index2] == SENSOR_NONE) { foundSensorMap[index2] = SENSOR_DIGO2M; /* store a mirror instance needed for visualization */ Mux2ADCMap[index2] = index; break; } } } } externalInterfaceMuxReqIntervall = 0xFFFF; if(cntSensor == 0) /* return default sensor map if no sensor at all has been detected */ { foundSensorMap[0] = SENSOR_OPTIC; foundSensorMap[1] = SENSOR_OPTIC; foundSensorMap[2] = SENSOR_OPTIC; } else { if(cntUARTSensor != 0) { externalInterfaceMuxReqIntervall = REQUEST_INT_SENSOR_MS / cntUARTSensor; } } memcpy(SensorMap, foundSensorMap, sizeof(foundSensorMap)); memset(externalInterface_SensorState,UART_O2_INIT,sizeof(externalInterface_SensorState)); break; default: break; } } } void externalInterface_ExecuteCmd(uint16_t Cmd) { char cmdString[10]; uint8_t cmdLength = 0; uint8_t index, index2; uint8_t cntUARTSensor = 0; uint8_t lastMappedID = 0; switch(Cmd & 0x00FF) /* lower byte is reserved for commands */ { case EXT_INTERFACE_AUTODETECT: externalAutoDetect = DETECTION_INIT; for(index = 0; index < 3; index++) { SensorMap[index] = SENSOR_SEARCH; } break; case EXT_INTERFACE_CO2_CALIB: cmdLength = snprintf(cmdString, 10, "G\r\n"); break; case EXT_INTERFACE_COPY_SENSORMAP: if(externalAutoDetect == DETECTION_OFF) { memcpy(SensorMap, MasterSensorMap, sizeof(MasterSensorMap)); for(index = 0; index < EXT_INTERFACE_SENSOR_CNT; index++) { if((SensorMap[index] == SENSOR_DIGO2) || (SensorMap[index] == SENSOR_CO2)) { cntUARTSensor++; } if(SensorMap[index] == SENSOR_DIGO2M) /* find matching sensor for mirror */ { for(index2 = EXT_INTERFACE_MUX_OFFSET; index2 < EXT_INTERFACE_SENSOR_CNT; index2++) { if(SensorMap[index2] == SENSOR_DIGO2) { if(lastMappedID < index2) { lastMappedID = index2; Mux2ADCMap[index] = index2; break; } } } } } if(cntUARTSensor > 0) { externalInterfaceMuxReqIntervall = REQUEST_INT_SENSOR_MS / cntUARTSensor; activeUartChannel = 0xFF; } else { externalInterfaceMuxReqIntervall = 0xFFFF; } } break; default: break; } if(cmdLength != 0) { HAL_UART_Transmit(&huart1,(uint8_t*)cmdString,cmdLength,10); } return; } uint8_t ExternalInterface_SelectUsedMuxChannel(uint8_t currentChannel) { uint8_t index = currentChannel; uint8_t newChannel = index; uint8_t *pmap = externalInterface_GetSensorMapPointer(0); do { index++; if(index == MAX_MUX_CHANNEL) { index = 0; } if(((pmap[index + EXT_INTERFACE_MUX_OFFSET] == SENSOR_DIGO2) || (pmap[index + EXT_INTERFACE_MUX_OFFSET] == SENSOR_CO2)) && (index != activeUartChannel)) { newChannel = index; break; } } while(index != currentChannel); return newChannel; } void externalInterface_HandleUART() { static uint8_t retryRequest = 0; static uint32_t lastRequestTick = 0; static uint32_t TriggerTick = 0; uint8_t index = 0; static uint8_t timeToTrigger = 0; uint32_t tick = HAL_GetTick(); uint8_t *pmap = externalInterface_GetSensorMapPointer(0); UART_ReadData(pmap[activeSensorId]); if(activeUartChannel == 0xFF) { activeUartChannel = ExternalInterface_SelectUsedMuxChannel(0); uartO2_SetChannel(activeUartChannel); if(pmap[EXT_INTERFACE_SENSOR_CNT-1] == SENSOR_MUX) { UART_MUX_SelectAddress(activeUartChannel); } UART_FlushRxBuffer(); } if(externalInterfaceMuxReqIntervall != 0xFFFF) { if(externalInterface_SensorState[activeSensorId] == UART_O2_INIT) { lastRequestTick = tick; TriggerTick = tick - 10; /* just to make sure control is triggered */ timeToTrigger = 1; retryRequest = 0; } else if(((retryRequest == 0) /* timeout or error */ && (((time_elapsed_ms(lastRequestTick,tick) > (TIMEOUT_SENSOR_ANSWER)) && (externalInterface_SensorState[activeSensorId] != UART_O2_IDLE)) /* retry if no answer after half request interval */ || (externalInterface_SensorState[activeSensorId] == UART_O2_ERROR)))) { /* The channel switch will cause the sensor to respond with an error message. */ /* The sensor needs ~30ms to recover before he is ready to receive the next command => transmission delay needed */ TriggerTick = tick; timeToTrigger = COMMAND_TX_DELAY; retryRequest = 1; } else if(time_elapsed_ms(lastRequestTick,tick) > externalInterfaceMuxReqIntervall) /* switch sensor and / or trigger next request */ { lastRequestTick = tick; TriggerTick = tick; retryRequest = 0; timeToTrigger = 1; if((externalInterface_SensorState[activeSensorId] == UART_O2_REQ_O2) /* timeout */ || (externalInterface_SensorState[activeSensorId] == UART_O2_REQ_RAW)) { setExternalInterfaceChannel(activeSensorId,0.0); } if(pmap[EXT_INTERFACE_SENSOR_CNT-1] == SENSOR_MUX) /* select next sensor if mux is connected */ { if(activeUartChannel < MAX_MUX_CHANNEL) { index = ExternalInterface_SelectUsedMuxChannel(activeUartChannel); if(index != activeUartChannel) { timeToTrigger = 100; activeUartChannel = index; if(pmap[index + EXT_INTERFACE_MUX_OFFSET] == SENSOR_DIGO2) { uartO2_SetChannel(activeUartChannel); UART_MUX_SelectAddress(activeUartChannel); } } } } else { timeToTrigger = 1; } } if((timeToTrigger != 0) && (time_elapsed_ms(TriggerTick,tick) > timeToTrigger)) { timeToTrigger = 0; switch (pmap[activeSensorId]) { case SENSOR_MUX: case SENSOR_DIGO2: uartO2_Control(); break; // case SENSOR_CO2: uartCO2_Control(); break; default: break; } } } #if 0 #ifdef ENABLE_CO2_SUPPORT if(externalInterface_GetUARTProtocol() & (EXT_INTERFACE_UART_CO2 >> 8)) { UART_HandleCO2Data(); } #endif #ifdef ENABLE_SENTINEL_MODE if(externalInterface_GetUARTProtocol() & (EXT_INTERFACE_UART_SENTINEL >> 8)) { UART_HandleSentinelData(); } #endif if(externalInterface_GetUARTProtocol() & (EXT_INTERFACE_UART_O2 >> 8)) { UART_HandleDigitalO2(); } #endif }