/*************************************************************************** Declaration : void init_mcu (void) Function : Initializes ATmega88 MCU ***************************************************************************/ void init_mcu (void) { #ifdef DEBUG debug(); #endif /* System Clocks Configuration */ RCC_Configuration(); /* Configure the GPIO ports */ GPIO_Configuration(); /* Configure EXTI Line9 to generate an interrupt on falling edge */ EXTI_Configuration(); /* SPI the GPIO ports */ SPI_Configuration(); /* USART Configuration as SPI */ USART1_Configuration(); /* TIM2 Configuration */ TIM2_Configuration(); /* TIM3 Configuration */ TIM3_Configuration(); /* TIM4 Configuration */ TIM4_Configuration(); /* Configure RTC clock source and prescaler */ RTC_Configuration(); /* NVIC configuration */ NVIC_Configuration(); }
void TIM_Init(void) { //TIM2_Configuration(); //TIM3_Configuration(); TIM4_Configuration(); // TIM5_Configuration(); // TIM6_Configuration(); // TIM7_Configuration(); }
int main(void) { // setup SYSCLK SYSCLK_Configuration(); // setup RCC RCC_Configuration(); // Remap JTRST so PB4 (red LED) can be used as GPIO_PinRemapConfig(GPIO_Remap_SWJ_NoJTRST , ENABLE); // setup system tick timer // SysTick_Configuration(); // set SysTick priority NVIC_SetPriority (SysTick_IRQn, NVIC_IPR0_PRI_1); //NVIC->ISER[0] |= (1 << SysTick_IRQn); // enable SysTick int in NVIC // Configure PB5 (green LED) and PB4 (red LED) GPIO_InitTypeDef GPIO_InitStructure; GPIO_InitStructure.GPIO_Pin = GPIO_Pin_5 | GPIO_Pin_4; GPIO_InitStructure.GPIO_Speed = GPIO_Speed_50MHz; GPIO_InitStructure.GPIO_Mode = GPIO_Mode_Out_PP; GPIO_Init(GPIOB, &GPIO_InitStructure); // Configure Timer3 & 4 to be used as push pull alternative function on pins 0 1 8 9 GPIO_InitStructure.GPIO_Pin = GPIO_Pin_0 | GPIO_Pin_1 | GPIO_Pin_8 | GPIO_Pin_9; GPIO_InitStructure.GPIO_Speed = GPIO_Speed_50MHz; GPIO_InitStructure.GPIO_Mode = GPIO_Mode_AF_PP; GPIO_Init(GPIOB, &GPIO_InitStructure); GPIO_PinRemapConfig(GPIO_PartialRemap_TIM3, ENABLE); // Setup timers TIM1_Configuration(); TIM2_Configuration(); TIM3_Configuration(); TIM4_Configuration(); // FreeRTOS initialization FreeRTOS_Configuration(); // start scheduler vTaskStartScheduler(); return 0; }
void Hardware_Init(void) { RCC_Configuration(); SysTick_Configuration(); NVIC_Configuration(); GPIO_Configuration(); //TIM1_Configuration(); TIM2_Configuration(); TIM3_Configuration(); TIM4_Configuration(); UART2_Init(); Unselect_SPI_Device(); //不选中任何一个SPI设备 SPI1_FLASH_Init(); }
/** * @brief Main program * @param None * @retval None */ int main(void) { RCC_Configuration(); GPIO_Configuration(); CAN_Configuration(); TIM4_Configuration(); CAN_ITConfig(CAN1, CAN_IT_FMP0, ENABLE); //CAN_ITConfig(CAN2, CAN_IT_FMP0, ENABLE); USART_Config(USART1); USART_Cmd(USART1, ENABLE); USART_Config(UART4);////////Rs232 USART_Cmd(UART4, ENABLE); //GPIO_ResetBits(GPIOB, GPIO_Pin_8|GPIO_Pin_9); //GPIO_SetBits(GPIOB, GPIO_Pin_6|GPIO_Pin_7); USART_ITConfig(USART1, USART_IT_RXNE, ENABLE); USART_ITConfig(UART4, USART_IT_RXNE, ENABLE); NVIC_Configuration(); //USART_ITConfig(USART2, USART_IT_RXNE, DISABLE); while (1) { if(rec_f==1) { rec_f=0; /* TxMessage.ExtId=0x1210; TxMessage.RTR=CAN_RTR_DATA; TxMessage.IDE=CAN_ID_STD; TxMessage.DLC=5; TxMessage.Data[0]=TxBuffer1[1]; TxMessage.Data[1]=TxBuffer1[2]; TxMessage.Data[2]=TxBuffer1[3]; TxMessage.Data[3]=TxBuffer1[4]; TxMessage.Data[4]=TxBuffer1[5];*/ //CAN_Transmit(CAN1, &TxMessage); //*******USART_ITConfig(USARTy, USART_IT_RXNE, ENABLE); 防止接收太快,导致发送的数据不准确 //UART_OUT(&TxBuffer1[0],6); //用rs485把 初始距离数据传出去 TxMessage.ExtId=0x111214; TxMessage.RTR=CAN_RTR_DATA; TxMessage.IDE=CAN_ID_EXT; TxMessage.DLC=8; for(n=0,m=0;n<6;n++,m++) { switch( TxBuffer1[n]) { case 0x30:TxMessage.Data[m]=0x0; break; case 0x31:TxMessage.Data[m]=0x01; break; case 0x32:TxMessage.Data[m]=0x02; break; case 0x33:TxMessage.Data[m]=0x03; break; case 0x34:TxMessage.Data[m]=0x04; break; case 0x35:TxMessage.Data[m]=0x05; break; case 0x36:TxMessage.Data[m]=0x06; break; case 0x37:TxMessage.Data[m]=0x07; break; case 0x38:TxMessage.Data[m]=0x08; break; case 0x39:TxMessage.Data[m]=0x09; break; } } CAN_Transmit(CAN1, &TxMessage); //这里是将距离值的1000被传给DSP 通过CAN 比如距离是18.555 传给DSP 是18555 } } }
/** * @brief Main program * @param None * @retval None */ int main(void) { /*!< At this stage the microcontroller clock setting is already configured, this is done through SystemInit() function which is called from startup file (startup_stm32f10x_xx.s) before to branch to application main. To reconfigure the default setting of SystemInit() function, refer to system_stm32f10x.c file */ /* System Clocks Configuration */ RCC_Configuration(); /* System Tick Configuration at 1us */ SysTick_Config(SystemCoreClock / 1000000); #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* TIM2 Configuration (Client & ATFC Server) */ TIM2_Configuration(); #elif defined USE_EQDAS_SERVER /* TIM4 Configuration */ TIM4_Configuration(); #endif /* TIM5 Configuration (GLCD & Ethernet) */ TIM5_Configuration(); /* TIM6 Configuration (RTC load) */ //TIM6_Configuration(); /* CLCD Configuration */ CLCD_Configuration(); /* GLCD Configuration */ GLCD_Configuration(); /* UART1 Configuration */ UART_Configuration(); /* RTC configuration by setting the time by Serial USART1 */ RTC_SetTimeBySerial(); /* Let user set the IP through terminal forcefully */ //ForceIPSetBySerial(); /* WIZ820io SPI1 configuration */ WIZ820io_SPI1_Configuration(); /* W5200 Configuration */ Set_network(); /* Print WIZ820io configuration */ printSysCfg(); /* EXTI Configuration */ EXTI_Configuration(); /* FatFS configuration */ f_mount(0, &fs); // mSD //f_mount(1, &fs); // NAND /* Display Total size of SD card in MB scale */ SD_TotalSize(); /* Scan all files in mSD card */ //scan_files(path); /* MAL configuration */ //Set_System(); /* UMS configuration */ //Set_USBClock(); //USB_Interrupts_Config(); //USB_Init(); /* loop upon completion of USB Enumeration */ //while (bDeviceState != CONFIGURED); /* ATFC Algorithm GPIO */ ATFC_GPIO_Configuration(); /* ATFC Parameter Initialization */ ATFCAlgorithmParameterSetup(); /* GPS-UART3 Configuration - This have to be here otherwise it wouldn't work */ GPS_Configuration(); // For TCP client's connection request delay presentTime = my_time; /* Create directory and sub directory in accordance with current date */ filePath = CreateDirectoryAccordingly(GetYearAndMergeToInt(), GetMonthAndMergeToInt(), GetDayAndMergeToInt(), RTC_GetCounter() / 3600); /* Create file in append mode in accordance with current minute */ CreateFileAppendModeAccordingly(filePath, (RTC_GetCounter() % 3600) / 60); /* Clear GLCD to better represent waveform */ GLCD_Clear(); //BKP_WriteBackupRegister(BKP_DR8, 0); // When everything is set, print message printf("\r\n\n - System is ready - "); while (1) { #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* Index synchronization routine -----------------------------------------------*/ if(SyncFlag) { // prevent unpleasant impuse from happening // Index synchronization dedicated to GLCD & Ethernet if(arrIdx != index) { // Index synchronization arrIdx = index; } } /* End of index synchronization routine -----------------------------------------*/ if(TimerCount > 999) { // 0 ~ 999 (1000) = 1 sec TimerCount = 0; //my_time++; // uncomment when tcp connection is needed /* Setup TCP Client or Server -------------------------------------------------*/ /* Please open config.h file to choose a proper board you wish to use ---------*/ /* Start TCP Client process */ ProcessTcpClient(SOCK_ZERO); // TCP Client /* Parameter setting Server side with port 5050 in default */ ATFCTcpServer(SOCK_TWO, EQDAS_Conf_PORT); // SOCK_TWO because of flag conformity /*------------------------------------------------------------------------------*/ /* Process Parameter Text Stream -----------------------------------------------*/ if(PCFlag) { // EQDAS Client System and ATFC Algorithm Setting PCFlag = false; ProcessParameterStream(); } /* End of Parameter process ----------------------------------------------------*/ } /* 10ms interval between points */ if(TIM5Count >= 9) { TIM5Count = 0; // Make a copy from raw collected data to temporary array CopyToTmpArray(arrIdx); // Determine KMA scale KMAGrade = DetermineKMA(arrIdx); // Check sign bit and apply to int container CheckSignAndToInt(arrIdx); // this function also cuts surplus 1G /* Switch menu & waveform display through graphic lcd */ GLCD_AxisViewWithWaveform(mode, arrIdx); //int mATFCBit; //mATFCBit_lcd = mAxisBuf.ATFCBit_lcd[arrIdx]; int AxisDataToATFCAlgorithm, mATFCEventDetection; AxisDataToATFCAlgorithm = mAxisBuf.tmp_data_y_lcd[arrIdx]; // Axis Z ATFCAlgorithm(AxisDataToATFCAlgorithm); mATFCEventDetection = EventDetection; /* Display KMA Intensity on Graphic LCD */ GLCD_DisplayKMAIntensity(KMAGrade, mATFCEventDetection); /* Prevent access to volatile variable warning */ /* This have to be here in order to correct data to be used in ATFC */ /* ATFC Server side for each EQ DAS Client */ if(EQATFCFlag) { int mYear, mMonth, mDay, mHour, mMin, mSec, mTMSec; mYear = year; mMonth = month; mDay = day; mHour = hour; mMin = minute; mSec = second; mTMSec = arrIdx; int mX, mY, mZ, mATFCBit; mX = mAxisBuf.tmp_data_x_lcd[arrIdx] >> 2; mY = mAxisBuf.tmp_data_y_lcd[arrIdx] >> 2; mZ = mAxisBuf.tmp_data_z_lcd[arrIdx] >> 2; mATFCBit = mATFCEventDetection; char ATFC_Buf[40]; sprintf(ATFC_Buf, "%04d%02d%02d_%02d%02d%02d%02d_%+05d_%+05d_%+05d_%d\r\n", mYear, mMonth, mDay, mHour, mMin, mSec, mTMSec, mX, mY, mZ, mATFCBit); // Only when socket is established, allow send data if(getSn_SR(SOCK_TWO) == SOCK_ESTABLISHED) { // SOCK_TWO : PC /* send selected data */ send(SOCK_TWO, (uint8_t*)ATFC_Buf, strlen(ATFC_Buf), (bool)false); } } // Copy to data buffer to be written through FATFS //CopyToFatFsDataBuffer(arrIdx); } /* RTC 1Hz interrupt */ if(RTCTimeDisplay) { // 1Hz calibrated by RTC RTCTimeDisplay = false; int TimeVar; TimeVar = RTC_GetCounter(); /* Compute hour */ THH = TimeVar / 3600; /* Compute minute */ TMM = (TimeVar % 3600) / 60; /* Compute second */ TSS = (TimeVar % 3600) % 60; /* Refresh date on every 1s */ year = GetYearAndMergeToInt(); month = GetMonthAndMergeToInt(); day = GetDayAndMergeToInt(); hour = THH; minute = TMM; second = TSS; tmsecond = 0; if(ThirtyMinuteMark == 1799) { ThirtyMinuteMark = 0; ThirtyMinuteFlag = true; } else { ThirtyMinuteMark++; } /* Adjust realtime clock deviation */ if(hour > 23) { int i, currentDay, mDay, mHour, mMin, mSec; mDay = hour / 24; for(i=0; i<mDay; i++) { IncreaseSingleDay(); if(i == mDay - 1) { currentDay = (GetMonthAndMergeToInt() * 100) + GetDayAndMergeToInt(); BKP_WriteBackupRegister(BKP_DR3, currentDay); // Save Month and Date } } mHour = THH % 24; mMin = TMM; mSec = TSS; /* Change the current time */ RTC_SetCounter(mHour*3600 + mMin*60 + mSec); } } #endif if(ParseGPS) { ParseGPS = false; char *srcstr = "$GPRMC"; char *token = ","; char *processedString; char StringYear[3], StringMonth[3], StringDay[3], StringHour[3], StringMinute[3], StringSecond[3]; int GPSYear, GPSMonth, GPSDay, GPSHour, GPSMinute, GPSSecond; if(strncmp((char const*)GPS_Buffer, srcstr, 6) == 0) { //printf("GPS_Buffer = %s\r\n\r\n", (char*)GPS_Buffer); processedString = strtok((char*)GPS_Buffer, token); processedString = strtok(NULL, token); strncpy(StringHour, processedString, 2); StringHour[2] = 0; strncpy(StringMinute, processedString+2, 2); StringMinute[2] = 0; strncpy(StringSecond, processedString+4, 2); StringSecond[2] = 0; GPSHour = atoi(StringHour) + 9; // Current Hour = StringHour + 9 GPSMinute = atoi(StringMinute); GPSSecond = atoi(StringSecond); int i; for(i=4; i!=0 ; i--) processedString = strtok(NULL, token); strncpy(StringYear, processedString+4, 2); StringYear[2] = 0; strncpy(StringMonth, processedString+2, 2); StringMonth[2] = 0; strncpy(StringDay, processedString, 2); StringDay[2] = 0; GPSYear = atoi(StringYear) + 2000; // Currnet Year = StringYear + 2000 GPSMonth = atoi(StringMonth); GPSDay = atoi(StringDay); /* The Year is chosen as criteria to the time */ if( (GPSYear == GetYearAndMergeToInt()) && ThirtyMinuteFlag ) { // only when year matches between RTC and GPS ThirtyMinuteFlag = false; if(GPSMonth != GetMonthAndMergeToInt() || GPSDay != GetDayAndMergeToInt() || GPSHour != THH || GPSMinute != TMM || GPSSecond != TSS) { /* Change the month and day */ TranslateIntoMonth(GPSMonth); TranslateIntoDay(GPSDay); /* Save year data to unresettable backup register addr. no. 3 */ int MMDD; MMDD = (GPSMonth * 100) + GPSDay; BKP_WriteBackupRegister(BKP_DR3, MMDD); // Save Month and Date /* Change the current time */ RTC_SetCounter(GPSHour*3600 + GPSMinute*60 + GPSSecond); printf("GPSHour = %d\r\n", GPSHour); printf("GPSMinute = %d\r\n", GPSMinute); printf("GPSSecond = %d\r\n\r\n", GPSSecond); printf("GPSYear = %d\r\n", GPSYear); printf("GPSMonth = %d\r\n", GPSMonth); printf("GPSDay = %d\r\n\r\n", GPSDay); printf("GPS-to-System synchronization complete!\r\n\r\n"); } } } } if(ParseUSART1) { ParseUSART1 = false; // run some test on SDIO //SDIO_TEST(); #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* Print WIZ820io configuration */ printSysCfg(); printf("\r\n"); printf("BKP_DR1 = %d\r\n", BKP_ReadBackupRegister(BKP_DR1)); printf("BKP_DR2 = %d\r\n", BKP_ReadBackupRegister(BKP_DR2)); printf("BKP_DR3 = %d\r\n", BKP_ReadBackupRegister(BKP_DR3)); printf("BKP_DR4 = %d\r\n", BKP_ReadBackupRegister(BKP_DR4)); printf("BKP_DR5 = %d\r\n", BKP_ReadBackupRegister(BKP_DR5)); printf("BKP_DR6 = %d\r\n", BKP_ReadBackupRegister(BKP_DR6)); printf("BKP_DR7 = %d\r\n", BKP_ReadBackupRegister(BKP_DR7)); printf("BKP_DR8 = %d\r\n", BKP_ReadBackupRegister(BKP_DR8)); printf("BKP_DR9 = %d\r\n", BKP_ReadBackupRegister(BKP_DR9)); printf("BKP_DR10 = %d\r\n", BKP_ReadBackupRegister(BKP_DR10)); printf("BKP_DR11 = %d\r\n", BKP_ReadBackupRegister(BKP_DR11)); printf("BKP_DR12 = %d\r\n", BKP_ReadBackupRegister(BKP_DR12)); printf("BKP_DR13 = %d\r\n", BKP_ReadBackupRegister(BKP_DR13)); printf("BKP_DR14 = %d\r\n", BKP_ReadBackupRegister(BKP_DR14)); printf("BKP_DR15 = %d\r\n", BKP_ReadBackupRegister(BKP_DR15)); printf("BKP_DR16 = %d\r\n\r\n", BKP_ReadBackupRegister(BKP_DR16)); printf("RX_BUF = %s\r\n", RX_BUF); /* printf("\r\nstrlen(HEADER) : %d %s", strlen(HEADER), HEADER); printf("\r\nf_mkdir1 : "); char *dirPath = "0:/20130517"; res = f_mkdir(dirPath); FPrintFatResult(res); printf("\r\nf_mkdir2 : "); dirPath = "0:/20130517/22H-23H"; res = f_mkdir(dirPath); FPrintFatResult(res); char *filePath = "0:/20130517/2-23H/test.txt"; // Create log file on the drive 0 res = open_append(&fsrc, filePath); FPrintFatResult(res); if(res == FR_OK) { printf("test.txt successfully created\r\n"); // Write buffer to file int bytesWritten; bytesWritten = f_printf(&fsrc, HEADER); printf("\r\n%d of bytesWritten", bytesWritten); // Close file f_close(&fsrc); } else if ( res == FR_EXIST ) { printf("\r\ntest.txt already exist"); } */ #elif (defined) USE_EQDAS_SERVER char buffer[40]; sprintf(buffer, "%s_%s_%s_%s_%s\r\n", DAQBoardOne[arrIdx].Date, DAQBoardOne[arrIdx].Time, DAQBoardOne[arrIdx].AxisX, DAQBoardOne[arrIdx].AxisY, DAQBoardOne[arrIdx].AxisZ); printf("\r\nRX_BUF : %s, strlen(RX_BUF) : %d", (char*)RX_BUF, strlen((char*)RX_BUF)); printf("\r\nstrlen(buffer) = %d\n%s", strlen(buffer), buffer); #endif } // following routine is only necessary when the board works as server #if defined USE_EQDAS_SERVER /* Server also needs to have get CLCD going while running */ /* RTC 1Hz interrupt */ if(RTCTimeDisplay) { // 1Hz calibrated by RTC RTCTimeDisplay = false; /* Adjust realtime clock deviation */ if(hour > 23) { int i, currentDay, mDay, mHour, mMin, mSec; mDay = hour / 24; for(i=0; i<mDay; i++) { IncreaseSingleDay(); if(i == mDay - 1) { currentDay = (GetMonthAndMergeToInt() * 100) + GetDayAndMergeToInt(); BKP_WriteBackupRegister(BKP_DR3, currentDay); // Save Month and Date } } mHour = THH % 24; mMin = TMM; mSec = TSS; /* Change the current time */ RTC_SetCounter(mHour*3600 + mMin*60 + mSec); } /* Display current time */ Time_Display(RTC_GetCounter()); } /* EQ-DAQ-01 Parsing routine ------------------------------------------------- */ /* Set E1Flag indicate that we have valid connection from EQ-DAQ-01(port 5050) */ if(E1Flag) { E1Flag = false; // clear flag since this routine excutes ceaselessly over time ProcessTextStream(EQ_ONE, (char*)RX_BUF, E1Order); /* PC Client Parsing routine ------------------------------------------------- */ /* Set PCFlag indicate that we have valid connection from PC Client(port 7070) */ if(PCFlag && !E2Flag) { // only when PC is connected and EQ-DAQ-02 is not connected // Send directly to PC SingleBoardDataToSendToPC(EQ_ONE, E1Order-10); } if(E1Order < 99) E1Order++; else E1Order = 0; } /* EQ-DAQ-02 Parsing routine ------------------------------------------------- */ /* Set E2Flag indicate that we have valid connection from EQ-DAQ-02(port 6060) */ if(E2Flag) { E2Flag = false; ProcessTextStream(EQ_TWO, (char*)RX_BUF, E2Order); /* PC Client Parsing routine ------------------------------------------------- */ /* Set PCFlag indicate that we have valid connection from PC Client(port 7070) */ if(PCFlag && !E1Flag) { // only when PC is connected and EQ-DAQ-01 is not connected // Send directly to PC //SendToPC(EQ_TWO, E2Order); } if(E2Order < 99) E2Order++; else E2Order = 0; /* PC Client Parsing routine ------------------------------------------------- */ /* Set PCFlag indicate that we have valid connection from PC Client(port 7070) */ if(PCFlag) { // Send directly to PC MultipleBoardDataToSendToPC(EQ_BOTH, E1Order-10, E2Order-10); } } /* Process server socket with each port */ ProcessTcpServer(SOCK_ZERO, 5050); // designated as for EQM-DAQ-01 with port 5050 ProcessTcpServer(SOCK_ONE, 6060); // designated as for EQM-DAQ-02 with port 6060 ProcessTcpServer(SOCK_TWO, 7070); // designated as for PC-CLIENT with port 7070 ProcessTcpServer(SOCK_THREE, 8080); // designated as for PC_DUMP with port 8080 /* ProcessTcpServer(SOCK_FOUR, 9090); // designated as for TOBEUSED with port 9090 ProcessTcpServer(SOCK_FIVE, 10010); // designated as for TOBEUSED with port 10010 ProcessTcpServer(SOCK_SIX, 10020); // designated as for TOBEUSED with port 10020 ProcessTcpServer(SOCK_SEVEN, 10030); // designated as for TOBEUSED with port 10030 */ #endif }
/** * @brief Main program * @param None * @retval None */ int main(void) { /*!< At this stage the microcontroller clock setting is already configured, this is done through SystemInit() function which is called from startup file (startup_stm32f10x_xx.s) before to branch to application main. To reconfigure the default setting of SystemInit() function, refer to system_stm32f10x.c file */ /* System Clocks Configuration */ RCC_Configuration(); /* System Tick Configuration at 1us */ SysTick_Config(SystemCoreClock / 1000000); #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* TIM2 Configuration */ TIM2_Configuration(); /* TIM3 Configuration */ TIM3_Configuration(); /* TIM6 Configuration (RTC load) */ TIM6_Configuration(); #elif defined USE_EQDAS_SERVER /* TIM4 Configuration */ TIM4_Configuration(); #endif /* CLCD Configuration */ CLCD_Configuration(); /* GLCD Configuration */ GLCD_Configuration(); /* UART1 Configuration */ UART_Configuration(); /* RTC configuration by setting the time by Serial USART1 */ //RTC_SetTimeBySerial(); /* WIZ820io SPI1 configuration */ WIZ820io_SPI1_Configuration(); /* W5200 Configuration */ Set_network(); /* Print WIZ820io configuration */ printSysCfg(); /* EXTI Configuration */ EXTI_Configuration(); /* FatFS configuration */ f_mount(0, &fs); // mSD //f_mount(1, &fs); // NAND /* Display Total size of SD card in MB scale */ SD_TotalSize(); /* Scan all files in mSD card */ scan_files(path); /* MAL configuration */ //Set_System(); /* UMS configuration */ //Set_USBClock(); //USB_Interrupts_Config(); //USB_Init(); /* loop upon completion of USB Enumeration */ //while (bDeviceState != CONFIGURED); /* ATFC Algorithm GPIO */ ATFC_GPIO_Configuration(); /* ATFC Parameter Initialization */ ATFCAlgorithmParameterSetup(); // For TCP client's connection request delay presentTime = my_time; /* Clear CLCD before branch into main */ CLCD_Clear(); /* Alarm in 3 second */ //RTC_SetAlarm(RTC_GetCounter() + 3); /* Wait until last write operation on RTC registers has finished */ //RTC_WaitForLastTask(); /* Create directory and sub directory in accordance with current date */ //filePath = CreateDirectoryAccordingly(GetYearAndMergeToInt(), GetMonthAndMergeToInt(), //GetDayAndMergeToInt(), RTC_GetCounter() / 3600); /* Create file in append mode in accordance with current minute */ //CreateFileAppendModeAccordingly(filePath, (RTC_GetCounter() % 3600) / 60); // When everything is set, print message printf("\r\n\n - System is ready - "); while (1) { #if (defined USE_EQDAS01) || (defined USE_EQDAS02) if(TimerCount > 1000) { // 0 ~ 999 (1000) = 1 sec TimerCount = 0; /* int x, y, z; x = mAxisBuf.tmp_data_x_lcd[index]; y = mAxisBuf.tmp_data_y_lcd[index]; z = mAxisBuf.tmp_data_z_lcd[index]; char Serial_Buf[37]; int hour, minute, second, tmsecond; hour = THH; minute = TMM; second = TSS; tmsecond = 0; sprintf(Serial_Buf, "%04d%02d%02d_%02d%02d%02d%02d_%+05d_%+05d_%+05d\r\n", year, month, day, hour, minute, second, tmsecond, x, y, z); printf(Serial_Buf); */ //my_time++; // uncomment when tcp connection is needed /* Process Parameter Text Stream */ if(PCFlag) { // EQDAS Client System and ATFC Algorithm Setting PCFlag = false; ProcessParameterStream(); } } /* Clock generated by TIM3 */ if(ClientTimerCounter > 10) { // 0 ~ 999 (1000) = 1 sec ClientTimerCounter = 0; int mAlgorithmContainer; year = GetYearAndMergeToInt(); month = GetMonthAndMergeToInt(); day = GetDayAndMergeToInt(); hour = THH; minute = TMM; second = TSS; tmsecond = 0; int mYear, mMonth, mDay, mHour, mMin, mSec, mTMSec; mYear = year; mMonth = month; mDay = day; mHour = hour; mMin = minute; mSec = second; mTMSec = tmsecond; x = mAxisBuf.tmp_data_x_lcd[arrIdx]; y = mAxisBuf.tmp_data_y_lcd[arrIdx]; z = mAxisBuf.tmp_data_z_lcd[arrIdx]; if(flag_uart) { // prevent unpleasant impuse // Index synchronization arrIdx = index; // Make a copy from raw collected data to temporary array CopyToTmpArray(arrIdx); // Copy to Temporary GAL array CopyToTmpGalArray(arrIdx); // Calculate GAL and copy to single temporary GAL value CalculateGalAndCopyToGal(arrIdx); // Determine KMA scale DetermineKMA(arrIdx); // Check sign bit and apply to int container CheckSignAndToInt(arrIdx); // this function also cuts surplus 1G /* Switch menu & waveform display through graphic lcd */ GLCD_AxisViewWithWaveform(mode, arrIdx, x, y, z); if(GoATFCFlag) { // Apply ATFC Algorithm to Axis x ATFCAlgorithm(mAxisBuf.tmp_data_x_lcd[arrIdx]); } } if(EventDetection) { GPIO_WriteBit(GPIOE, GPIO_Pin_15, Bit_SET); mAlgorithmContainer = x; } else { GPIO_WriteBit(GPIOE, GPIO_Pin_15, Bit_RESET); mAlgorithmContainer = 0; } // Copy to data buffer to be written through FATFS //CopyToFatFsDataBuffer(arrIdx); /* EQDAQ01, 02 Client Routine ---------------------------------------------*/ /* E1Flag or E2Flag set when client board successfully connect to server --*/ /* Refer to wiz820.c line no. 300 for which flag to be set */ if(E1Flag) { char E1_Buf[45]; sprintf(E1_Buf, "%04d%02d%02d_%02d%02d%02d%02d_%+05d_%+05d_%+05d_%+05d\r\n", mYear, mMonth, mDay, mHour, mMin, mSec, mTMSec, x, y, z, mAlgorithmContainer); // Only when socket is established, allow send data if(getSn_SR(SOCK_TWO) == SOCK_ESTABLISHED) { /* send selected data */ CountSendByte = send(SOCK_TWO, (uint8_t*)E1_Buf, strlen(E1_Buf), (bool)false); } } if(E2Flag) { char E2_Buf[45]; sprintf(E2_Buf, "%04d%02d%02d_%02d%02d%02d%02d_%+05d_%+05d_%+05d\r\n", mYear, mMonth, mDay, mHour, mMin, mSec, mTMSec, x, y, z); // Only when socket is established, allow send data if(getSn_SR(SOCK_ZERO) == SOCK_ESTABLISHED) { /* send selected data */ send(SOCK_ZERO, (uint8_t*)E2_Buf, strlen(E2_Buf), (bool)false); } } } /* do RTC work on every second */ if(RTCTIM6Count > 1000) { RTCTIM6Count = 0; if(InitialThirteenSeconds == 12) { InitialThirteenSeconds = 0; GoATFCFlag = true; } else { if(!GoATFCFlag) { InitialThirteenSeconds++; } } /* RTC 1Hz interrupt */ if(RTCTimeDisplay) { // 1Hz calibrated by RTC RTCTimeDisplay = false; /* Display current time */ Time_Display(RTC_GetCounter()); } /* RTC Alarm interrupt */ if(RTCAlarmFlag) { RTCAlarmFlag = false; printf("\r\nRTC Alarm Actviated!"); } } /* Save log to file process ------------------------------------------------*/ /* Save process needs to be run every single cycle due to delay might occur */ if(GoAppendDataFlag) { // every 500 sample (equals 5 sec), go save file. GoAppendDataFlag = false; int bytesWritten = 0; if(EachSecFlag) { // it means that DATA1_BUF is full and ready to flush out // be sure to empty out DATA1_BUF or will overflow and cause system to halt. /* Append first data for the duration of 1 second */ bytesWritten = f_printf(&fsrc, DATA1_BUF); printf("\r\n%d of bytesWritten", bytesWritten); if(FileRecordCompleteFlag) { FileRecordCompleteFlag = false; printf("\r\nFile Record Complete!"); /* Close the file */ f_close(&fsrc); } // Reset DATA1_BUF memset(DATA1_BUF, 0, sizeof(DATA1_BUF)); } else { /* Append another second of data */ bytesWritten = f_printf(&fsrc, DATA2_BUF); printf("\r\n%d of bytesWritten", bytesWritten); if(FileRecordCompleteFlag) { FileRecordCompleteFlag = false; printf("\r\nFile Record Complete!"); /* Close the file */ f_close(&fsrc); } // Reset DATA2_BUF memset(DATA2_BUF, 0, sizeof(DATA2_BUF)); } } #endif if(ParseUSART1) { ParseUSART1 = false; // run some test on SDIO //SDIO_TEST(); #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* Print WIZ820io configuration */ printSysCfg(); printf("\r\n"); printf("\r\nBKP_DR1 = %d", BKP_ReadBackupRegister(BKP_DR1)); printf("\r\nBKP_DR2 = %d", BKP_ReadBackupRegister(BKP_DR2)); printf("\r\nBKP_DR3 = %d", BKP_ReadBackupRegister(BKP_DR3)); printf("\r\nBKP_DR4 = %d", BKP_ReadBackupRegister(BKP_DR4)); printf("\r\nBKP_DR5 = %d", BKP_ReadBackupRegister(BKP_DR5)); printf("\r\nBKP_DR6 = %d", BKP_ReadBackupRegister(BKP_DR6)); printf("\r\nBKP_DR7 = %d", BKP_ReadBackupRegister(BKP_DR7)); printf("\r\nBKP_DR8 = %d", BKP_ReadBackupRegister(BKP_DR8)); printf("\r\nBKP_DR9 = %d", BKP_ReadBackupRegister(BKP_DR9)); printf("\r\nBKP_DR10 = %d", BKP_ReadBackupRegister(BKP_DR10)); printf("\r\nBKP_DR11 = %d", BKP_ReadBackupRegister(BKP_DR11)); printf("\r\nBKP_DR12 = %d", BKP_ReadBackupRegister(BKP_DR12)); printf("\r\nBKP_DR13 = %d", BKP_ReadBackupRegister(BKP_DR13)); printf("\r\nBKP_DR14 = %d", BKP_ReadBackupRegister(BKP_DR14)); printf("\r\nBKP_DR15 = %d", BKP_ReadBackupRegister(BKP_DR15)); printf("\r\nBKP_DR16 = %d", BKP_ReadBackupRegister(BKP_DR16)); #elif (defined) USE_EQDAS_SERVER char buffer[37]; sprintf(buffer, "%s_%s_%s_%s_%s\r\n", DAQBoardOne[arrIdx].Date, DAQBoardOne[arrIdx].Time, DAQBoardOne[arrIdx].AxisX, DAQBoardOne[arrIdx].AxisY, DAQBoardOne[arrIdx].AxisZ); printf("\r\nRX_BUF : %s, strlen(RX_BUF) : %d", (char*)RX_BUF, strlen((char*)RX_BUF)); printf("\r\nstrlen(buffer) = %d\n%s", strlen(buffer), buffer); /* char *original = "-3843,+4095,+2069"; char target[20]; strncpy(target, original, strlen(original)); char *one, *two, *three; char *AfterToken; AfterToken = strtok(target, ","); one = AfterToken; AfterToken = strtok(NULL, ","); two = AfterToken; AfterToken = strtok(NULL, ","); three = AfterToken; AfterToken = strtok(NULL, ","); if(AfterToken != NULL) printf("AfterToken is not empty"); printf("\r\none : %s, two : %s, three : %s", one, two, three);*/ #endif } #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* for(i=0; i<100; i++) { if(flag_uart) { // Make a copy from raw collected data to temporary array CopyToTmpArray(i); // Copy to Temporary GAL array CopyToTmpGalArray(i); // Calculate GAL and copy to single temporary GAL value CalculateGalAndCopyToGal(i); // Determine KMA scale DetermineKMA(i); // Check sign bit and apply to int container CheckSignAndToInt(i); // this function also cuts surplus 1G } } */ // following routine is only necessary when the board works as server #elif defined USE_EQDAS_SERVER /* EQ-DAQ-01 Parsing routine ------------------------------------------------- */ /* Set E1Flag indicate that we have valid connection from EQ-DAQ-01(port 5050) */ if(E1Flag) { E1Flag = false; // clear flag since this routine excutes ceaselessly over time ProcessTextStream(EQ_ONE, (char*)RX_BUF, E1Order); /* PC Client Parsing routine ------------------------------------------------- */ /* Set PCFlag indicate that we have valid connection from PC Client(port 7070) */ if(PCFlag) { // Send directly to PC SendToPC(E1Order); } if(E1Order < 99) E1Order++; else E1Order = 0; } /* EQ-DAQ-02 Parsing routine ------------------------------------------------- */ /* Set E2Flag indicate that we have valid connection from EQ-DAQ-02(port 6060) */ if(E2Flag) { E2Flag = false; ProcessTextStream(EQ_TWO, (char*)RX_BUF, E2Order); /* PC Client Parsing routine ------------------------------------------------- */ /* Set PCFlag indicate that we have valid connection from PC Client(port 7070) */ if(PCFlag) { // Send directly to PC SendToPC(E2Order); } if(E2Order < 99) E2Order++; else E2Order = 0; } #endif /* Setup TCP Client or Server -----------------------------------------------------*/ /* Please open config.h file to choose a proper board you wish to use */ #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* Start TCP Client process */ ProcessTcpClient(SOCK_ZERO); // TCP Client /* Parameter setting Server side with port 5050 in default */ ATFCTcpServer(SOCK_TWO, EQDAS_Conf_PORT); // SOCK_TWO because of flag conformity #elif defined USE_EQDAS_SERVER /* Process server socket with each port */ ProcessTcpServer(SOCK_ZERO, 5050); // designated as for EQM-DAQ-01 with port 5050 ProcessTcpServer(SOCK_ONE, 6060); // designated as for EQM-DAQ-02 with port 6060 ProcessTcpServer(SOCK_TWO, 7070); // designated as for PC-CLIENT with port 7070 ProcessTcpServer(SOCK_THREE, 8080); // designated as for PC_DUMP with port 8080 /* ProcessTcpServer(SOCK_FOUR, 9090); // designated as for TOBEUSED with port 9090 ProcessTcpServer(SOCK_FIVE, 10010); // designated as for TOBEUSED with port 10010 ProcessTcpServer(SOCK_SIX, 10020); // designated as for TOBEUSED with port 10020 ProcessTcpServer(SOCK_SEVEN, 10030); // designated as for TOBEUSED with port 10030 */ #endif } }
/** * @brief Main program * @param None * @retval None */ int main(void) { /*!< At this stage the microcontroller clock setting is already configured, this is done through SystemInit() function which is called from startup file (startup_stm32f10x_xx.s) before to branch to application main. To reconfigure the default setting of SystemInit() function, refer to system_stm32f10x.c file */ /* RCC configuration */ RCC_Configuration(); /* TIM4 configuration */ TIM4_Configuration(); /* UART4 configuration */ UART4_Configuration(); /* WIZ820io SPI2 configuration */ WIZ820io_SPI2_Configuration(); // one that is on left one /* WIZ820io SPI3 configuration */ //WIZ820io_SPI3_Configuration(); // one that is on right one /* W5200 Configuration */ Set_network(); /* TLCD configuration */ TLCD_Configuration(); //TLCD_Write(0, 0, str1); //TLCD_Write(0, 1, str2); /* RTC Configuration */ RTC_Configuration(); /* EXIT4(Mode select button) configuration */ EXTILine4_Configuration(); /* EXIT5(F_SYNC : 100Hz) configuration */ EXTILine5_Configuration(); /* EXIT6(F_SCLK : 10KHz) configuration */ EXTILine6_Configuration(); /* myAccel3LV02 Configuration */ Accel3LV02_Configuration(); //myAccel3LV02 setup 1000.0111 Power on, enable all axis, self test off Accel_WriteReg(CTRL_REG1, 0xC7); // following routine setup myAccel3LV02 6g mode //Accel_WriteReg(CTRL_REG2, 0x80); /* GLCD configuration */ GLCD_Configuration(); // For TCP client's connection request delay presentTime = my_time; // When everything is set, print message printf("\r\n - System is ready - "); while(1) { if(TimerCount >= 1000) { // thousand equals one second TimerCount = 0; // for Calculate connection delay my_time++; // retrieve axis data GetAccelValue(AXIS_X, &Xdata); GetAccelValue(AXIS_Y, &Ydata); GetAccelValue(AXIS_Z, &Zdata); char str[30]; sprintf(str, "%d,%d,%d", 0xFFF&Xdata, 0xFFF&Ydata, 0xFFF&Zdata); TLCD_Clear(); TLCD_Write(0, 0, str); } if(ParseUART4) { ParseUART4 = False; // print Wiz810io configuration printSysCfg(); } if(flag_uart == 1) { tmp_start = start; } switch(mode) { case SELECT_AXIS_X : break; case SELECT_AXIS_Y : break; case SELECT_AXIS_Z : break; } /* Ethernet Client Routine -----------------------------------------------*/ /* SendFlag get set from when socket established and received any message */ if(SendFlag) { SendFlag = False; char AxisData[30]; for(order = 0; order < 100 ; order++) { float EW = 0; float NS = 0; float UD = 0; EW = data_x[order] * 1e-7; NS = data_y[order] * 1e-7; UD = data_z[order] * 1e-7; sprintf(AxisData, "%-0.7f,%-0.7f,%-0.7f\n", EW, NS, UD); // Only when socket is established, send data if(getSn_SR(SOCK_ZERO) == SOCK_ESTABLISHED) { /* send the received data */ send(SOCK_ZERO, (uint8*)AxisData, strlen(AxisData), (bool)False); } } } /* Process client socket with port 5050 */ //ProcessTcpClient(SOCK_ZERO); } }
/** * @brief Main program * @param None * @retval None */ int main(void) { /*!< At this stage the microcontroller clock setting is already configured, this is done through SystemInit() function which is called from startup file (startup_stm32f10x_xx.s) before to branch to application main. To reconfigure the default setting of SystemInit() function, refer to system_stm32f10x.c file */ /* System Clocks Configuration */ RCC_Configuration(); /* System Tick Configuration at 1us */ SysTick_Config(SystemCoreClock / 1000000); #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* TIM2 Configuration */ TIM2_Configuration(); /* TIM3 Configuration (10ms for Network Transmission)*/ TIM3_Configuration(); /* TIM5 Configuration (GLCD Time Share)*/ TIM5_Configuration(); /* TIM6 Configuration (RTC load) */ TIM6_Configuration(); #elif defined USE_EQDAS_SERVER /* TIM4 Configuration */ TIM4_Configuration(); #endif /* CLCD Configuration */ CLCD_Configuration(); /* GLCD Configuration */ GLCD_Configuration(); /* UART1 Configuration */ UART_Configuration(); /* GPS-UART3 Configuration */ //GPS_Configuration(); /* RTC configuration by setting the time by Serial USART1 */ RTC_SetTimeBySerial(); /* Forcefully let user set the IP through terminal */ //ForceIPSetBySerial(); /* WIZ820io SPI1 configuration */ WIZ820io_SPI1_Configuration(); /* W5200 Configuration */ Set_network(); /* Print WIZ820io configuration */ printSysCfg(); /* EXTI Configuration */ EXTI_Configuration(); /* FatFS configuration */ f_mount(0, &fs); // mSD //f_mount(1, &fs); // NAND /* Display Total size of SD card in MB scale */ SD_TotalSize(); /* Scan all files in mSD card */ scan_files(path); /* MAL configuration */ //Set_System(); /* UMS configuration */ //Set_USBClock(); //USB_Interrupts_Config(); //USB_Init(); /* loop upon completion of USB Enumeration */ //while (bDeviceState != CONFIGURED); /* ATFC Algorithm GPIO */ ATFC_GPIO_Configuration(); /* ATFC Parameter Initialization */ ATFCAlgorithmParameterSetup(); // For TCP client's connection request delay presentTime = my_time; /* Clear CLCD before branch into main */ CLCD_Clear(); /* Create directory and sub directory in accordance with current date */ filePath = CreateDirectoryAccordingly(GetYearAndMergeToInt(), GetMonthAndMergeToInt(), GetDayAndMergeToInt(), RTC_GetCounter() / 3600); /* Create file in append mode in accordance with current minute */ CreateFileAppendModeAccordingly(filePath, (RTC_GetCounter() % 3600) / 60); // When everything is set, print message printf("\r\n\n - System is ready - "); while (1) { #if (defined USE_EQDAS01) || (defined USE_EQDAS02) if(TimerCount > 1000) { // 0 ~ 999 (1000) = 1 sec TimerCount = 0; /* int x, y, z; x = mAxisBuf.tmp_data_x_lcd[index]; y = mAxisBuf.tmp_data_y_lcd[index]; z = mAxisBuf.tmp_data_z_lcd[index]; char Serial_Buf[37]; int hour, minute, second, tmsecond; hour = THH; minute = TMM; second = TSS; tmsecond = 0; sprintf(Serial_Buf, "%04d%02d%02d_%02d%02d%02d%02d_%+05d_%+05d_%+05d\r\n", year, month, day, hour, minute, second, tmsecond, x, y, z); printf(Serial_Buf); */ //my_time++; // uncomment when tcp connection is needed /* Process Parameter Text Stream */ /* if(PCFlag) { // EQDAS Client System and ATFC Algorithm Setting PCFlag = false; ProcessParameterStream(); } */ } /* GLCD Time Share */ if(TIM5GLCDCount > 95) { // Allocate proper time to share mcu resource with network TIM5GLCDCount = 0; /* Graphic LCD Copy and Process Routine -------------------------------------- */ if(SyncFlag) { // prevent unpleasant impuse // Index synchronization dedicate to GLCD arrGLCDIdx = index; // Make a copy from raw collected data to temporary array CopyToTmpArray(arrGLCDIdx); // Copy to Temporary GAL array //CopyToTmpGalArray(arrIdx); // Calculate GAL and copy to single temporary GAL value //CalculateGalAndCopyToGal(arrIdx); // Determine KMA scale KMAGrade = DetermineKMA(arrGLCDIdx); // Check sign bit and apply to int container CheckSignAndToInt(arrGLCDIdx); // this function also cuts surplus 1G } int mATFCBit_lcd; mATFCBit_lcd = mAxisBuf.ATFCBit_lcd[arrGLCDIdx]; /* Switch menu & waveform display through graphic lcd */ GLCD_AxisViewWithWaveform(mode, arrGLCDIdx); /* Display KMA Intensity on Graphic LCD */ GLCD_DisplayKMAIntensity(KMAGrade, mATFCBit_lcd); } /* Clock generated by TIM3 */ if(ClientTimerCounter > 10) { // 0 ~ 999 (1000) = 1 sec ClientTimerCounter = 0; year = GetYearAndMergeToInt(); month = GetMonthAndMergeToInt(); day = GetDayAndMergeToInt(); hour = THH; minute = TMM; second = TSS; tmsecond = 0; int mYear, mMonth, mDay, mHour, mMin, mSec, mTMSec; mYear = year; mMonth = month; mDay = day; mHour = hour; mMin = minute; mSec = second; mTMSec = tmsecond; if(SyncFlag) { // Index synchronization arrIdx = index; // Make a copy from raw collected data to temporary net array CopyToNetArray(arrIdx); // Check sign bit and apply to int container CheckSignAndToIntForNet(arrIdx); // this function also cuts surplus 1G } /* Prevent access to volatile variable warning */ /* This have to be here in order to correct data to be used in ATFC */ int mX, mY, mZ, mATFCBit; mX = mAxisNetBuf.axis_x_for_net[arrIdx]; mY = mAxisNetBuf.axis_y_for_net[arrIdx]; mZ = mAxisNetBuf.axis_z_for_net[arrIdx]; mATFCBit = mAxisNetBuf.ATFCBit_net[arrIdx]; /* EQDAQ01, 02 Client Routine ---------------------------------------------*/ /* E1Flag or E2Flag set when client board successfully connect to server --*/ /* Refer to wiz820.c line no. 406 for which flag to be set */ if(E1Flag) { char E1_Buf[45]; sprintf(E1_Buf, "%04d%02d%02d_%02d%02d%02d%02d_%+05d_%+05d_%+05d_%d\r\n", mYear, mMonth, mDay, mHour, mMin, mSec, mTMSec, mX, mY, mZ, mATFCBit); // Only when socket is established, allow send data if(getSn_SR(SOCK_ZERO) == SOCK_ESTABLISHED) { /* send selected data */ CountSendByte = send(SOCK_ZERO, (uint8_t*)E1_Buf, strlen(E1_Buf), (bool)false); } } if(E2Flag) { char E2_Buf[45]; sprintf(E2_Buf, "%04d%02d%02d_%02d%02d%02d%02d_%+05d_%+05d_%+05d_%d\r\n", mYear, mMonth, mDay, mHour, mMin, mSec, mTMSec, mX, mY, mZ, mATFCBit); // Only when socket is established, allow send data if(getSn_SR(SOCK_ZERO) == SOCK_ESTABLISHED) { /* send selected data */ send(SOCK_ZERO, (uint8_t*)E2_Buf, strlen(E2_Buf), (bool)false); } } } /* do RTC work on every second */ if(RTCTIM6Count > 1000) { RTCTIM6Count = 0; if(InitialThirteenSeconds == 12) { InitialThirteenSeconds = 0; GoATFCFlag = true; } else { if(!GoATFCFlag) { InitialThirteenSeconds++; } } /* RTC 1Hz interrupt */ if(RTCTimeDisplay) { // 1Hz calibrated by RTC RTCTimeDisplay = false; /* Adjust realtime clock deviation */ if(hour > 23) { int i, currentDay, mDay, mHour, mMin, mSec; mDay = hour / 24; for(i=0; i<mDay; i++) { IncreaseSingleDay(); if(i == mDay - 1) { currentDay = (GetMonthAndMergeToInt() * 100) + GetDayAndMergeToInt(); BKP_WriteBackupRegister(BKP_DR3, currentDay); // Save Month and Date } } mHour = THH % 24; mMin = TMM; mSec = TSS; /* Change the current time */ RTC_SetCounter(mHour*3600 + mMin*60 + mSec); } /* Display current time */ Time_Display(RTC_GetCounter()); int OrderCount; for(OrderCount = 0; OrderCount < 100; OrderCount++) { // Copy to data buffer to be written through FATFS CopyToFatFsDataBuffer(OrderCount); } } /* RTC Alarm interrupt */ if(RTCAlarmFlag) { RTCAlarmFlag = false; printf("\r\nRTC Alarm Actviated!"); } } #endif if(ParseGPS) { ParseGPS = false; printf("%s", GPS_Buffer); } if(ParseUSART1) { ParseUSART1 = false; // run some test on SDIO //SDIO_TEST(); #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* Print WIZ820io configuration */ printSysCfg(); printf("\r\n"); printf("\r\nBKP_DR1 = %d", BKP_ReadBackupRegister(BKP_DR1)); printf("\r\nBKP_DR2 = %d", BKP_ReadBackupRegister(BKP_DR2)); printf("\r\nBKP_DR3 = %d", BKP_ReadBackupRegister(BKP_DR3)); printf("\r\nBKP_DR4 = %d", BKP_ReadBackupRegister(BKP_DR4)); printf("\r\nBKP_DR5 = %d", BKP_ReadBackupRegister(BKP_DR5)); printf("\r\nBKP_DR6 = %d", BKP_ReadBackupRegister(BKP_DR6)); printf("\r\nBKP_DR7 = %d", BKP_ReadBackupRegister(BKP_DR7)); printf("\r\nBKP_DR8 = %d", BKP_ReadBackupRegister(BKP_DR8)); printf("\r\nBKP_DR9 = %d", BKP_ReadBackupRegister(BKP_DR9)); printf("\r\nBKP_DR10 = %d", BKP_ReadBackupRegister(BKP_DR10)); printf("\r\nBKP_DR11 = %d", BKP_ReadBackupRegister(BKP_DR11)); printf("\r\nBKP_DR12 = %d", BKP_ReadBackupRegister(BKP_DR12)); printf("\r\nBKP_DR13 = %d", BKP_ReadBackupRegister(BKP_DR13)); printf("\r\nBKP_DR14 = %d", BKP_ReadBackupRegister(BKP_DR14)); printf("\r\nBKP_DR15 = %d", BKP_ReadBackupRegister(BKP_DR15)); printf("\r\nBKP_DR16 = %d", BKP_ReadBackupRegister(BKP_DR16)); /* printf("\r\nstrlen(HEADER) : %d %s", strlen(HEADER), HEADER); printf("\r\nf_mkdir1 : "); char *dirPath = "0:/20130517"; res = f_mkdir(dirPath); FPrintFatResult(res); printf("\r\nf_mkdir2 : "); dirPath = "0:/20130517/22H-23H"; res = f_mkdir(dirPath); FPrintFatResult(res); char *filePath = "0:/20130517/2-23H/test.txt"; // Create log file on the drive 0 res = open_append(&fsrc, filePath); FPrintFatResult(res); if(res == FR_OK) { printf("test.txt successfully created\r\n"); // Write buffer to file int bytesWritten; bytesWritten = f_printf(&fsrc, HEADER); printf("\r\n%d of bytesWritten", bytesWritten); // Close file f_close(&fsrc); } else if ( res == FR_EXIST ) { printf("\r\ntest.txt already exist"); } */ #elif (defined) USE_EQDAS_SERVER char buffer[37]; sprintf(buffer, "%s_%s_%s_%s_%s\r\n", DAQBoardOne[arrIdx].Date, DAQBoardOne[arrIdx].Time, DAQBoardOne[arrIdx].AxisX, DAQBoardOne[arrIdx].AxisY, DAQBoardOne[arrIdx].AxisZ); printf("\r\nRX_BUF : %s, strlen(RX_BUF) : %d", (char*)RX_BUF, strlen((char*)RX_BUF)); printf("\r\nstrlen(buffer) = %d\n%s", strlen(buffer), buffer); /* char *original = "-3843,+4095,+2069"; char target[20]; strncpy(target, original, strlen(original)); char *one, *two, *three; char *AfterToken; AfterToken = strtok(target, ","); one = AfterToken; AfterToken = strtok(NULL, ","); two = AfterToken; AfterToken = strtok(NULL, ","); three = AfterToken; AfterToken = strtok(NULL, ","); if(AfterToken != NULL) printf("AfterToken is not empty"); printf("\r\none : %s, two : %s, three : %s", one, two, three);*/ #endif } // following routine is only necessary when the board works as server #if defined USE_EQDAS_SERVER /* Server also needs to have get CLCD going while running */ /* RTC 1Hz interrupt */ if(RTCTimeDisplay) { // 1Hz calibrated by RTC RTCTimeDisplay = false; /* Adjust realtime clock deviation */ if(hour > 23) { int i, currentDay, mDay, mHour, mMin, mSec; mDay = hour / 24; for(i=0; i<mDay; i++) { IncreaseSingleDay(); if(i == mDay - 1) { currentDay = (GetMonthAndMergeToInt() * 100) + GetDayAndMergeToInt(); BKP_WriteBackupRegister(BKP_DR3, currentDay); // Save Month and Date } } mHour = THH % 24; mMin = TMM; mSec = TSS; /* Change the current time */ RTC_SetCounter(mHour*3600 + mMin*60 + mSec); } /* Display current time */ Time_Display(RTC_GetCounter()); } /* EQ-DAQ-01 Parsing routine ------------------------------------------------- */ /* Set E1Flag indicate that we have valid connection from EQ-DAQ-01(port 5050) */ if(E1Flag) { E1Flag = false; // clear flag since this routine excutes ceaselessly over time ProcessTextStream(EQ_ONE, (char*)RX_BUF, E1Order); /* PC Client Parsing routine ------------------------------------------------- */ /* Set PCFlag indicate that we have valid connection from PC Client(port 7070) */ if(PCFlag && !E2Flag) { // only when PC is connected and EQ-DAQ-02 is not connected // Send directly to PC //SendToPC(EQ_ONE, E1Order); } if(E1Order < 99) E1Order++; else E1Order = 0; } /* EQ-DAQ-02 Parsing routine ------------------------------------------------- */ /* Set E2Flag indicate that we have valid connection from EQ-DAQ-02(port 6060) */ if(E2Flag) { E2Flag = false; ProcessTextStream(EQ_TWO, (char*)RX_BUF, E2Order); /* PC Client Parsing routine ------------------------------------------------- */ /* Set PCFlag indicate that we have valid connection from PC Client(port 7070) */ if(PCFlag && !E1Flag) { // only when PC is connected and EQ-DAQ-01 is not connected // Send directly to PC //SendToPC(EQ_TWO, E2Order); } if(E2Order < 99) E2Order++; else E2Order = 0; /* PC Client Parsing routine ------------------------------------------------- */ /* Set PCFlag indicate that we have valid connection from PC Client(port 7070) */ if(PCFlag) { // Send directly to PC MultipleBoardDataToSendToPC(EQ_BOTH, E1Order, E2Order); } } #endif /* Setup TCP Client or Server -----------------------------------------------------*/ /* Please open config.h file to choose a proper board you wish to use -------------*/ #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* Start TCP Client process */ ProcessTcpClient(SOCK_ZERO); // TCP Client /* Parameter setting Server side with port 5050 in default */ ATFCTcpServer(SOCK_TWO, EQDAS_Conf_PORT); // SOCK_TWO because of flag conformity #elif defined USE_EQDAS_SERVER /* Process server socket with each port */ ProcessTcpServer(SOCK_ZERO, 5050); // designated as for EQM-DAQ-01 with port 5050 ProcessTcpServer(SOCK_ONE, 6060); // designated as for EQM-DAQ-02 with port 6060 ProcessTcpServer(SOCK_TWO, 7070); // designated as for PC-CLIENT with port 7070 ProcessTcpServer(SOCK_THREE, 8080); // designated as for PC_DUMP with port 8080 /* ProcessTcpServer(SOCK_FOUR, 9090); // designated as for TOBEUSED with port 9090 ProcessTcpServer(SOCK_FIVE, 10010); // designated as for TOBEUSED with port 10010 ProcessTcpServer(SOCK_SIX, 10020); // designated as for TOBEUSED with port 10020 ProcessTcpServer(SOCK_SEVEN, 10030); // designated as for TOBEUSED with port 10030 */ #endif } }
/** * @brief Main program * @param None * @retval None */ int main(void) { /*!< At this stage the microcontroller clock setting is already configured, this is done through SystemInit() function which is called from startup file (startup_stm32f10x_xx.s) before to branch to application main. To reconfigure the default setting of SystemInit() function, refer to system_stm32f10x.c file */ /* System Clocks Configuration */ RCC_Configuration(); /* System Tick Configuration at 1us */ SysTick_Config(SystemCoreClock / 1000000); #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* TIM2 Configuration */ TIM2_Configuration(); /* TIM3 Configuration */ TIM3_Configuration(); /* TIM6 Configuration (RTC load) */ TIM6_Configuration(); #elif defined USE_EQDAS_SERVER /* TIM4 Configuration */ TIM4_Configuration(); #endif /* UART1 Configuration */ UART_Configuration(); /* WIZ820io SPI1 configuration */ WIZ820io_SPI1_Configuration(); /* W5200 Configuration */ Set_network(); /* EXTI Configuration */ EXTI_Configuration(); /* CLCD Configuration */ CLCD_Configuration(); /* GLCD Configuration */ GLCD_Configuration(); #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* RTC configuration by setting the time by Serial USART1 */ RTC_SetTimeBySerial(); #endif /* FatFS configuration */ f_mount(0, &fs); // mSD //f_mount(1, &fs); // NAND /* Display Total size of SD card in MB scale */ SD_TotalSize(); /* Scan all files in mSD card */ scan_files(path); /* MAL configuration */ //Set_System(); /* UMS configuration */ //Set_USBClock(); //USB_Interrupts_Config(); //USB_Init(); /* loop upon completion of USB Enumeration */ //while (bDeviceState != CONFIGURED); // For TCP client's connection request delay presentTime = my_time; /* Clear CLCD before branch into main */ CLCD_Clear(); /* Alarm in 3 second */ //RTC_SetAlarm(RTC_GetCounter() + 3); /* Wait until last write operation on RTC registers has finished */ //RTC_WaitForLastTask(); // When everything is set, print message printf("\r\n\n - System is ready - "); while (1) { #if (defined USE_EQDAS01) || (defined USE_EQDAS02) if(TimerCount >= 999) { // 0 ~ 999 (1000) = 1 sec TimerCount = 0; /* int x, y, z; x = mAxisBuf.tmp_data_x_lcd[index]; y = mAxisBuf.tmp_data_y_lcd[index]; z = mAxisBuf.tmp_data_z_lcd[index]; char Serial_Buf[37]; int hour, minute, second, tmsecond; hour = THH; minute = TMM; second = TSS; tmsecond = 0; sprintf(Serial_Buf, "%04d%02d%02d_%02d%02d%02d%02d_%+05d_%+05d_%+05d\r\n", year, month, day, hour, minute, second, tmsecond, x, y, z); printf(Serial_Buf); */ //my_time++; // uncomment when tcp connection is needed } /* Clock generated by TIM3 */ if(ClientTimerCounter >= 99) { // 0 ~ 999 (1000) = 1 sec ClientTimerCounter = 0; arrIdx = index; year = GetYearAndMergeToInt(); month = GetMonthAndMergeToInt(); day = GetDayAndMergeToInt(); hour = THH; minute = TMM; second = TSS; tmsecond = 0; /* EQDAQ01, 02 Client Routine ---------------------------------------------*/ /* E1Flag or E2Flag set when client board successfully connect to server --*/ /* Refer to wiz820.c line no. 300 for which flag to be set */ if(E1Flag) { int x, y, z; x = mAxisBuf.tmp_data_x_lcd[arrIdx]; y = mAxisBuf.tmp_data_y_lcd[arrIdx]; z = mAxisBuf.tmp_data_z_lcd[arrIdx]; char E1_Buf[20]; sprintf(E1_Buf, "%04d%02d%02d_%02d%02d%02d%02d_%+05d_%+05d_%+05d\r\n", year, month, day, hour, minute, second, tmsecond, x, y, z); // Only when socket is established, allow send data if(getSn_SR(SOCK_ZERO) == SOCK_ESTABLISHED) { /* send selected data */ CountSendByte = send(SOCK_ZERO, (uint8_t*)E1_Buf, strlen(E1_Buf), (bool)false); } } if(E2Flag) { int x, y, z; x = mAxisBuf.tmp_data_x_lcd[arrIdx]; y = mAxisBuf.tmp_data_y_lcd[arrIdx]; z = mAxisBuf.tmp_data_z_lcd[arrIdx]; char E2_Buf[20]; sprintf(E2_Buf, "%04d%02d%02d_%02d%02d%02d%02d_%+05d_%+05d_%+05d\r\n", year, month, day, hour, minute, second, tmsecond, x, y, z); // Only when socket is established, allow send data if(getSn_SR(SOCK_ZERO) == SOCK_ESTABLISHED) { /* send selected data */ send(SOCK_ZERO, (uint8_t*)E2_Buf, strlen(E2_Buf), (bool)false); } } } /* do RTC work on every 0.5 sec */ if(RTCTIM6Count >= 499) { RTCTIM6Count = 0; /* RTC 1Hz interrupt */ if(RTCTimeDisplay) { // 1Hz calibrated by RTC RTCTimeDisplay = false; /* Display current time */ Time_Display(RTC_GetCounter()); } /* RTC Alarm interrupt */ if(RTCAlarmFlag) { RTCAlarmFlag = false; printf("\r\nRTC Alarm Actviated!"); } } #endif if(ParseUSART1) { ParseUSART1 = false; // print system configuration //printSysCfg(); // run some test on SDIO //SDIO_TEST(); #if (defined USE_EQDAS01) || (defined USE_EQDAS02) #elif (defined) USE_EQDAS_SERVER char buffer[37]; sprintf(buffer, "%s_%s_%s_%s_%s\r\n", DAQBoardOne[arrIdx].Date, DAQBoardOne[arrIdx].Time, DAQBoardOne[arrIdx].AxisX, DAQBoardOne[arrIdx].AxisY, DAQBoardOne[arrIdx].AxisZ); printf("\r\nRX_BUF : %s, strlen(RX_BUF) : %d", (char*)RX_BUF, strlen((char*)RX_BUF)); printf("\r\nstrlen(buffer) = %d\n%s", strlen(buffer), buffer); /* char *original = "-3843,+4095,+2069"; char target[20]; strncpy(target, original, strlen(original)); char *one, *two, *three; char *AfterToken; AfterToken = strtok(target, ","); one = AfterToken; AfterToken = strtok(NULL, ","); two = AfterToken; AfterToken = strtok(NULL, ","); three = AfterToken; AfterToken = strtok(NULL, ","); if(AfterToken != NULL) printf("AfterToken is not empty"); printf("\r\none : %s, two : %s, three : %s", one, two, three);*/ #endif } #if (defined USE_EQDAS01) || (defined USE_EQDAS02) for(i=0; i<100; i++) { // Make a copy from raw collected data to temporary array CopyToTmpArray(i); // Copy to Temporary GAL array CopyToTmpGalArray(i); // Calculate GAL and copy to single temporary GAL value CalculateGalAndCopyToGal(i); // Determine KMA scale DetermineKMA(i); // Check sign bit and apply to int container CheckSignAndToInt(i); // this function also cuts surplus 1G // Copy to data buffer to be written through FATFS //CopyToFatFsDataBuffer(arrIdx); } /* Save log to file process */ if(GoAppendDataFlag) { // every 500 sample (equals 5 sec), go save file. GoAppendDataFlag = false; int bytesWritten = 0; /* Open or create a log file and ready to append */ //char *filePath = "/20130517/22H-23H/test.txt"; //res = open_append(&fsrc, filePath); //FPrintFatResult(res); if(FiveSecFlag) { // it means that DATA1_BUF is full and ready to flush out // be sure to empty out DATA1_BUF or will overflow and cause system to halt. /* Append 5 second of data */ bytesWritten = f_printf(&fsrc, DATA1_BUF); /* Close the file */ f_close(&fsrc); printf("\r\n%d of bytesWritten", bytesWritten); // Reset DATA1_BUF memset(DATA1_BUF, 0, sizeof(DATA1_BUF)); } else { // here means that DATA2_BUF is full and ready to flush out // be sure to empty out DATA2_BUF or will overflow and cause system to halt. /* Append 5 second of data */ bytesWritten = f_printf(&fsrc, DATA2_BUF); /* Close the file */ f_close(&fsrc); printf("\r\n%d of bytesWritten", bytesWritten); // Reset DATA2_BUF memset(DATA2_BUF, 0, sizeof(DATA2_BUF)); } } // following routine is only necessary when the board works as server #elif defined USE_EQDAS_SERVER /* EQ-DAQ-01 Parsing routine ------------------------------------------------- */ /* Set E1Flag indicate that we have valid connection from EQ-DAQ-01(port 5050) */ if(E1Flag) { E1Flag = false; // clear flag since this routine excutes ceaselessly over time ProcessTextStream(EQ_ONE, (char*)RX_BUF, E1Order); /* PC Client Parsing routine ------------------------------------------------- */ /* Set PCFlag indicate that we have valid connection from PC Client(port 7070) */ if(PCFlag) { // Send directly to PC SendToPC(E1Order); } if(E1Order < 99) E1Order++; else E1Order = 0; } /* EQ-DAQ-02 Parsing routine ------------------------------------------------- */ /* Set E2Flag indicate that we have valid connection from EQ-DAQ-02(port 6060) */ if(E2Flag) { E2Flag = false; ProcessTextStream(EQ_TWO, (char*)RX_BUF, E2Order); /* PC Client Parsing routine ------------------------------------------------- */ /* Set PCFlag indicate that we have valid connection from PC Client(port 7070) */ if(PCFlag) { // Send directly to PC SendToPC(E2Order); } if(E2Order < 99) E2Order++; else E2Order = 0; } #endif /* Setup TCP Client or Server -----------------------------------------------------*/ /* Please open config.h file to choose a proper board you wish to use */ #if (defined USE_EQDAS01) || (defined USE_EQDAS02) /* Start TCP Client process */ ProcessTcpClient(SOCK_ZERO); #elif defined USE_EQDAS_SERVER /* Process server socket with each port */ ProcessTcpServer(SOCK_ZERO, 5050); // designated as for EQM-DAQ-01 with port 5050 ProcessTcpServer(SOCK_ONE, 6060); // designated as for EQM-DAQ-02 with port 6060 ProcessTcpServer(SOCK_TWO, 7070); // designated as for PC-CLIENT with port 7070 ProcessTcpServer(SOCK_THREE, 8080); // designated as for PC_DUMP with port 8080 /* ProcessTcpServer(SOCK_FOUR, 9090); // designated as for TOBEUSED with port 9090 ProcessTcpServer(SOCK_FIVE, 10010); // designated as for TOBEUSED with port 10010 ProcessTcpServer(SOCK_SIX, 10020); // designated as for TOBEUSED with port 10020 ProcessTcpServer(SOCK_SEVEN, 10030); // designated as for TOBEUSED with port 10030 */ #endif } }
int main(void) { while (1); /* Configuration */ SystemInit(); LED_Configuration(); BUZZ_Configuration(); //ADC_Configuration(); CAN_Configuration(); /****************************µ×Å̳õʼ»¯******************************/ Elmo_Init(elmo, 3); // PositionPID_Init(); PositionIPD_Init(); MoveLock(); Delay_ms(100); BLUETOOTH_Configuration(); Delay_ms(100); Encoder_Clear(); Delay_ms(1000); MPU6500_init(); TIM1_Configuration(); TIM2_Configuration(); TIM3_Configuration(); TIM4_Configuration(); if (SysTick_Config(SystemCoreClock / 1000)) /* Setup SysTick Timer for 1 msec interrupts */ { while(1){LED_ON(LED2);}/* Capture error */ } // IpdAxisX.setpoint = 200; // IpdAngle.setpoint = 90; // PidAxisX.setpoint = 200; // CMDVelocity.X = 10; // CMDVelocity.Y = 0; // CMDVelocity.A = 0;//Degree/Second // Elmo_Write(&elmo[0],0x01,0x01,50); while (1) { if(MPU_FLAG == 1) { MPU_FLAG = 0; } if(MAPAN_FLAG == 1) { MAPAN_FLAG = 0; // LED_TOGGLE(LED1); MapanTask();//ÂëÅÌ } if(PID_PFLAG ==1) { PID_PFLAG = 0; // PositionPIDCal(); PositionIPDCal(); VelocityTransform(); // LED_TOGGLE(LED2); } if (LED_FLAG == 1) { LED_FLAG = 0; // SquareTracking(); // CircleTracking(); // GoBack(); // LED_TOGGLE(LED3); // SignalTracking(); // angle_print(); // PositionVelocity_print(); } } }
void PWMConfig() { TIM4_Configuration(); }
/** * @brief Main program * @param None * @retval None */ int main(void) { /*!< At this stage the microcontroller clock setting is already configured, this is done through SystemInit() function which is called from startup file (startup_stm32f10x_xx.s) before to branch to application main. To reconfigure the default setting of SystemInit() function, refer to system_stm32f10x.c file */ /* RCC configuration */ RCC_Configuration(); /* TIM4 configuration */ TIM4_Configuration(); /* UART4 configuration */ UART4_Configuration(); /* Configure SysTick for each 1us */ SysTick_Config(SystemCoreClock / 1000000); /* TLCD configuration */ TLCD_Configuration(); /* RTC Configuration */ RTC_Configuration(); /* WIZ820io SPI2 configuration */ WIZ820io_SPI2_Configuration(); // one that is on left one /* WIZ820io SPI3 configuration */ //WIZ820io_SPI3_Configuration(); // one that is on right one /* W5200 Configuration */ Set_network(); /* EXIT4(Mode select button) configuration */ EXTILine4_Configuration(); /* EXIT5(F_SYNC : 100Hz) configuration */ EXTILine5_Configuration(); /* EXIT6(F_SCLK : 10KHz) configuration */ EXTILine6_Configuration(); /* myAccel3LV02 Configuration */ Accel3LV02_Configuration(); //myAccel3LV02 setup 1000.0111 Power on, enable all axis, self test off Accel_WriteReg(CTRL_REG1, 0xC7); // following routine setup myAccel3LV02 6g mode //Accel_WriteReg(CTRL_REG2, 0x80); /* GLCD configuration */ GLCD_Configuration(); /* Clear system loading string of TLCD */ TLCD_Clear(); // When everything is set, print message printf("\r\n - System is ready - "); while(1) { if(TimerCount >= 1000) { // thousand equals one second TimerCount = 0; /* // retrieve axis data GetAccelValue(AXIS_X, &Xdata); GetAccelValue(AXIS_Y, &Ydata); GetAccelValue(AXIS_Z, &Zdata); char str[30]; sprintf(str, "%d,%d,%d", 0xFFF&Xdata, 0xFFF&Ydata, 0xFFF&Zdata); TLCD_Clear(); TLCD_Write(0, 0, str); */ } if(ParseUART4) { ParseUART4 = false; // print Wiz810io configuration printSysCfg(); } if(flag_uart == 1) { tmp_start = index; } // On every impulse out of 100Hz do the work if(RbitFlag) { RbitFlag = false; // copy to buffer mAxisBuf.tmp_data_x_lcd[index] = mAxisData.data_x[index]; mAxisBuf.tmp_data_y_lcd[index] = mAxisData.data_y[index]; mAxisBuf.tmp_data_z_lcd[index] = mAxisData.data_z[index]; // Copy to Temporary GAL array CopyToTmpGalArray(index); // Cut off to 1G CutOffTo1G(index); // Calculate GAL and copy to single temporary GAL value CalculateGalAndCopyToGal(index); // Determine KMA scale DetermineKMA(index); /* PC Client Parsing routine ------------------------------------------------- */ /* Set PCFlag indicate that we have valid connection from PC Client(port 7070) */ if(PCFlag) { //PCFlag = false; char PC_Buf[20]; sprintf(PC_Buf, "%+d,%+d,%+d\n", mAxisBuf.tmp_data_x_lcd[index], mAxisBuf.tmp_data_y_lcd[index], mAxisBuf.tmp_data_z_lcd[index]); // code for stacking algorithm which will combine data from two boards into one // Only when socket is established, allow send data if(getSn_SR(SOCK_TWO) == SOCK_ESTABLISHED) { /* send selected data */ send(SOCK_TWO, (uint8_t*)PC_Buf, strlen(PC_Buf), (bool)false); } } // increase index so that we can add to next array index++; } switch(mode) { case SELECT_AXIS_X : break; case SELECT_AXIS_Y : break; case SELECT_AXIS_Z : break; } // RTC Wakeup event if(WUFlag) { WUFlag = false; // Update current Date and Time RTC_TimeShow(); // Display on TLCD TLCD_Write(0, 0, Date); TLCD_Write(0, 1, Time); } /* EQ-DAQ-01 Parsing routine ------------------------------------------------- */ /* Set E1Flag indicate that we have valid connection from EQ-DAQ-01(port 5050) */ if(E1Flag) { E1Flag = false; ProcessTextStream(EQ_ONE, (char*)RX_BUF); } /* EQ-DAQ-02 Parsing routine ------------------------------------------------- */ /* Set E2Flag indicate that we have valid connection from EQ-DAQ-02(port 6060) */ if(E2Flag) { E2Flag = false; ProcessTextStream(EQ_TWO, (char*)RX_BUF); } /* Process server socket with each port */ ProcessTcpServer(SOCK_ZERO, 5050); // designated as for EQM-DAQ-01 with port 5050 ProcessTcpServer(SOCK_ONE, 6060); // designated as for EQM-DAQ-02 with port 6060 ProcessTcpServer(SOCK_TWO, 7070); // designated as for PC-CLIENT with port 7070 ProcessTcpServer(SOCK_THREE, 8080); // designated as for TOBEUSED with port 8080 /* Socket 4 to 7 reserved for future application * ProcessTcpServer(SOCK_FOUR, 9090); // designated as for TOBEUSED with port 9090 * ProcessTcpServer(SOCK_FIVE, 10010); // designated as for TOBEUSED with port 10010 * ProcessTcpServer(SOCK_SIX, 10020); // designated as for TOBEUSED with port 10020 * ProcessTcpServer(SOCK_SEVEN, 10030); // designated as for TOBEUSED with port 10030 */ } }