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view Small_CPU/Src/uartProtocol_Co2.c @ 1078:082825daccb5 Icon_Integration tip
Added control views for HUD:
The HUD implementation may now be activated by the compile switch ENABLE_HUD_SUPPORT. The HUD will become visible onces detected in the CvOpt overview menu. The first implementation is for testing only => The LEDs may be operated by a number field. Positiv values activate the red, negativ the green LEDs. Depending on the value blink sequences will be scheduled.
At the moment no dive specific data is mapped to the LED operation (like e.g. warnings).
| author | Ideenmodellierer |
|---|---|
| date | Mon, 02 Mar 2026 17:30:38 +0100 |
| parents | 8b97003dbb60 |
| children |
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/** ****************************************************************************** * @file uartProtocol_Co2.c * @author heinrichs weikamp gmbh * @version V0.0.1 * @date 31-Jul-2023 * @brief Interface functionality to external, UART based CO2 sensors * @verbatim @endverbatim ****************************************************************************** * @attention * * <h2><center>© COPYRIGHT(c) 2023 heinrichs weikamp</center></h2> * ****************************************************************************** */ /* Includes ------------------------------------------------------------------*/ #include <string.h> #include <uartProtocol_Co2.h> #include "uart.h" #include "externalInterface.h" #ifdef ENABLE_CO2_SUPPORT static uint8_t CO2Connected = 0; /* Binary indicator if a sensor is connected or not */ static receiveStateCO2_t rxState = CO2RX_Ready; float LED_Level = 0.0; /* Normalized LED value which may be used as indication for the health status of the sensor */ float LED_ZeroOffset = 0.0; float pCO2 = 0.0; void uartCo2_SendCmd(uint8_t CO2Cmd, uint8_t *cmdString, uint8_t *cmdLength) { *cmdLength = 0; switch (CO2Cmd) { case CO2CMD_MODE_POLL: *cmdLength = snprintf((char*)cmdString, 20, "K 2\r\n"); break; case CO2CMD_MODE_STREAM: *cmdLength = snprintf((char*)cmdString, 20, "K 1\r\n"); break; case CO2CMD_CALIBRATE_H: *cmdLength = snprintf((char*)cmdString, 20, "P 10 1\r\n"); /* set 400ppm as reference => 1 (256) and 144 */ break; case CO2CMD_CALIBRATE_L: *cmdLength = snprintf((char*)cmdString, 20, "P 11 144\r\n"); break; case CO2CMD_CALIBRATE: *cmdLength = snprintf((char*)cmdString, 20, "G\r\n"); break; case CO2CMD_GETDATA: *cmdLength = snprintf((char*)cmdString, 20, "Q\r\n"); break; case CO2CMD_GETSCALE: *cmdLength = snprintf((char*)cmdString, 20, ".\r\n"); break; default: *cmdLength = 0; break; } if(cmdLength != 0) { UART_SendCmdString(cmdString); } } void uartCo2_Control(void) { static uint8_t cmdString[20]; static uint8_t cmdLength = 0; static uint8_t lastComState = UART_CO2_INIT; uint8_t activeSensor = externalInterface_GetActiveUartSensor(); uartCO2Status_t localComState = externalInterface_GetSensorState(activeSensor + EXT_INTERFACE_MUX_OFFSET); if(localComState == UART_CO2_ERROR) { localComState = lastComState; } switch(localComState) { case UART_CO2_INIT: CO2Connected = 0; externalInterface_SetCO2Scale(0.0); UART_ReadData(SENSOR_CO2, 1); /* flush buffer */ UART_StartDMA_Receiption(&Uart1Ctrl); localComState = UART_CO2_SETUP; uartCo2_SendCmd(CO2CMD_GETSCALE, cmdString, &cmdLength); break; case UART_CO2_SETUP: if(externalInterface_GetCO2Scale() == 0.0) { uartCo2_SendCmd(CO2CMD_GETSCALE, cmdString, &cmdLength); } else { uartCo2_SendCmd(CO2CMD_MODE_POLL, cmdString, &cmdLength); localComState = UART_CO2_MODE; } break; case UART_CO2_MODE: uartCo2_SendCmd(CO2CMD_MODE_POLL, cmdString, &cmdLength); break; case UART_CO2_CALIBRATE_H: uartCo2_SendCmd(CO2CMD_CALIBRATE_H, cmdString, &cmdLength); break; case UART_CO2_CALIBRATE_L: uartCo2_SendCmd(CO2CMD_CALIBRATE_L, cmdString, &cmdLength); break; case UART_CO2_CALIBRATE: uartCo2_SendCmd(CO2CMD_CALIBRATE, cmdString, &cmdLength); localComState = UART_CO2_IDLE; break; case UART_CO2_IDLE: if(externalInterface_GetCO2Scale() == 0.0) /* artifact from streaming mode => not needed for polling */ { uartCo2_SendCmd(CO2CMD_GETSCALE, cmdString, &cmdLength); localComState = UART_CO2_SETUP; } else { uartCo2_SendCmd(CO2CMD_GETDATA, cmdString, &cmdLength); localComState = UART_CO2_OPERATING; } break; default: if(cmdLength != 0) { UART_SendCmdString(cmdString); /* resend last command */ cmdLength = 0; } break; } lastComState = localComState; externalInterface_SetSensorState(activeSensor + EXT_INTERFACE_MUX_OFFSET,localComState); } void uartCo2_ProcessData(uint8_t data) { static uint8_t dataType = 0; static uint32_t dataValue[3]; static uint8_t dataIndex = 0; uint8_t activeSensor = externalInterface_GetActiveUartSensor(); uartCO2Status_t localComState = externalInterface_GetSensorState(activeSensor + EXT_INTERFACE_MUX_OFFSET); if(rxState == CO2RX_Ready) /* identify data content */ { switch(data) { case 'P': case 'G': case 'K': case 'l': case 'D': case 'Z': case '.': dataType = data; rxState = CO2RX_Data0; dataValue[0] = 0; dataIndex = 0; break; case '?': localComState = UART_CO2_ERROR; rxState = CO2RX_Ready; break; default: /* unknown or corrupted => ignore */ break; } } else if((data >= '0') && (data <= '9')) { if((rxState >= CO2RX_Data0) && (rxState <= CO2RX_Data9)) { dataValue[dataIndex] = dataValue[dataIndex] * 10 + (data - '0'); switch (dataType) { case 'G': case 'K': case 'l': case 'D': case 'Z': case '.': default: if((rxState == CO2RX_Data4)) { rxState = CO2RX_DataComplete; /* just one value to be received */ } else { rxState++; } break; case 'P': if(rxState == CO2RX_Data9) /* get second parameter */ { rxState = CO2RX_DataComplete; } else { rxState++; } break; } } else /* protocol error data has max 5 digits */ { if(rxState != CO2RX_DataComplete) /* commands will not answer with number values */ { rxState = CO2RX_Ready; } } } else if((data == ' ') || (data == '\n')) /* Abort data detection */ { if(rxState == CO2RX_DataComplete) { CO2Connected = 1; switch(localComState) { case UART_CO2_SETUP: if(dataType == '.') { localComState = UART_CO2_MODE; } break; case UART_CO2_MODE: if((dataType == 'K') && (dataValue[dataIndex] == 2)) { localComState = UART_CO2_IDLE; } break; case UART_CO2_CALIBRATE_H: if((dataType == 'P') && (dataValue[0] == 10) && (dataValue[1] == 1)) { localComState = UART_CO2_CALIBRATE_L; } else { localComState = UART_CO2_IDLE; } break; case UART_CO2_CALIBRATE_L: if((dataType == 'P') && (dataValue[0] == 11) && (dataValue[1] == 144)) { localComState = UART_CO2_CALIBRATE; } else { localComState = UART_CO2_IDLE; } break; default: localComState = UART_CO2_IDLE; break; } switch(dataType) { case 'D': externalInterface_SetCO2SignalStrength(dataValue[dataIndex]); break; case 'l': LED_ZeroOffset = dataValue[dataIndex]; break; case 'Z': externalInterface_SetCO2Value(dataValue[dataIndex]); break; case '.': externalInterface_SetCO2Scale(dataValue[dataIndex]); break; default: rxState = CO2RX_Ready; break; } rxState = CO2RX_Ready; } else /* multi parameter */ { if(rxState == CO2RX_Data5) { switch(dataType) { case 'P': dataIndex++; dataValue[dataIndex] = 0; break; default: break; } } } if((rxState != CO2RX_Data0) && (rxState != CO2RX_Data5)) /* reset state machine because message in wrong format */ { rxState = CO2RX_Ready; } } else { if((rxState >= CO2RX_Data0) && (rxState <= CO2RX_Data4)) { rxState = CO2RX_Ready; /* numerical data expected => abort */ } } externalInterface_SetSensorState(activeSensor + EXT_INTERFACE_MUX_OFFSET,localComState); } uint8_t uartCo2_isSensorConnected() { return CO2Connected; } #endif