/* * Simple data logger. */ #include #include "SdFat.h" // SD chip select pin. Be sure to disable any other SPI devices such as Enet. const uint8_t chipSelect = SS; // Interval between data records in milliseconds. // The interval must be greater than the maximum SD write latency plus the // time to acquire and write data to the SD to avoid overrun errors. // Run the bench example to check the quality of your SD card. const uint32_t SAMPLE_INTERVAL_MS = 1000; // Log file base name. Must be six characters or less. #define FILE_BASE_NAME "Data" //------------------------------------------------------------------------------ // File system object. SdFat sd; // Log file. SdFile file; // Time in micros for next data record. uint32_t logTime; //============================================================================== // User functions. Edit writeHeader() and logData() for your requirements. const uint8_t ANALOG_COUNT = 4; //------------------------------------------------------------------------------ // Write data header. void writeHeader() { file.print(F("micros")); for (uint8_t i = 0; i < ANALOG_COUNT; i++) { file.print(F(",adc")); file.print(i, DEC); } file.println(); } //------------------------------------------------------------------------------ // Log a data record. void logData() { uint16_t data[ANALOG_COUNT]; // Read all channels to avoid SD write latency between readings. for (uint8_t i = 0; i < ANALOG_COUNT; i++) { data[i] = analogRead(i); } // Write data to file. Start with log time in micros. file.print(logTime); // Write ADC data to CSV record. for (uint8_t i = 0; i < ANALOG_COUNT; i++) { file.write(','); file.print(data[i]); } file.println(); } //============================================================================== // Error messages stored in flash. #define error(msg) sd.errorHalt(F(msg)) //------------------------------------------------------------------------------ void setup() { const uint8_t BASE_NAME_SIZE = sizeof(FILE_BASE_NAME) - 1; char fileName[13] = FILE_BASE_NAME "00.csv"; Serial.begin(9600); // Wait for USB Serial while (!Serial) { yield(); } delay(1000); Serial.println(F("Type any character to start")); while (!Serial.available()) { yield(); } // Initialize at the highest speed supported by the board that is // not over 50 MHz. Try a lower speed if SPI errors occur. if (!sd.begin(chipSelect, SD_SCK_MHZ(50))) { sd.initErrorHalt(); } // Find an unused file name. if (BASE_NAME_SIZE > 6) { error("FILE_BASE_NAME too long"); } while (sd.exists(fileName)) { if (fileName[BASE_NAME_SIZE + 1] != '9') { fileName[BASE_NAME_SIZE + 1]++; } else if (fileName[BASE_NAME_SIZE] != '9') { fileName[BASE_NAME_SIZE + 1] = '0'; fileName[BASE_NAME_SIZE]++; } else { error("Can't create file name"); } } if (!file.open(fileName, O_WRONLY | O_CREAT | O_EXCL)) { error("file.open"); } // Read any Serial data. do { delay(10); } while (Serial.available() && Serial.read() >= 0); Serial.print(F("Logging to: ")); Serial.println(fileName); Serial.println(F("Type any character to stop")); // Write data header. writeHeader(); // Start on a multiple of the sample interval. logTime = micros()/(1000UL*SAMPLE_INTERVAL_MS) + 1; logTime *= 1000UL*SAMPLE_INTERVAL_MS; } //------------------------------------------------------------------------------ void loop() { // Time for next record. logTime += 1000UL*SAMPLE_INTERVAL_MS; // Wait for log time. int32_t diff; do { diff = micros() - logTime; } while (diff < 0); // Check for data rate too high. if (diff > 10) { error("Missed data record"); } logData(); // Force data to SD and update the directory entry to avoid data loss. if (!file.sync() || file.getWriteError()) { error("write error"); } if (Serial.available()) { // Close file and stop. file.close(); Serial.println(F("Done")); while (true) {} } }