Using the SD card
The first thing that we are going to do in this project is to test whether we can actually access the SD card. This will ensure that we don't run into SD card-related problems later in the project.
This is a picture of the Ethernet Shield that I used, with the microSD card mounted on the right:
Let's now see the code that we will use to test the SD card's functionalities. The following is the complete code for this section:
// Include the SD library #include <SPI.h> #include <SD.h> // Set up variables using the SD utility library functions: Sd2Card card; SdVolume volume; SdFile root; // change this to match your SD shield or module; // Arduino Ethernet shield: pin 4 // Adafruit SD shields and modules: pin 10 // Sparkfun SD shield: pin 8 const int chipSelect = 4; void setup() { // Open serial communications and wait for port to open: Serial.begin(115200); while (!Serial) { ; // wait for serial port to connect. Needed for Leonardo only } Serial.print("\nInitializing SD card..."); // we'll use the initialization code from the utility libraries // since we're just testing if the card is working! if (!card.init(SPI_HALF_SPEED, chipSelect)) { Serial.println("initialization failed. Things to check:"); Serial.println("* is a card inserted?"); Serial.println("* is your wiring correct?"); Serial.println("* did you change the chipSelect pin to match your shield or module?"); return; } else { Serial.println("Wiring is correct and a card is present."); } // print the type of card Serial.print("\nCard type: "); switch (card.type()) { case SD_CARD_TYPE_SD1: Serial.println("SD1"); break; case SD_CARD_TYPE_SD2: Serial.println("SD2"); break; case SD_CARD_TYPE_SDHC: Serial.println("SDHC"); break; default: Serial.println("Unknown"); } // Now we will try to open the 'volume'/'partition' - it should be FAT16 or FAT32 if (!volume.init(card)) { Serial.println("Could not find FAT16/FAT32 partition.\nMake sure you've formatted the card"); return; } // print the type and size of the first FAT-type volume uint32_t volumesize; Serial.print("\nVolume type is FAT"); Serial.println(volume.fatType(), DEC); Serial.println(); volumesize = volume.blocksPerCluster(); // clusters are collections of blocks volumesize *= volume.clusterCount(); // we'll have a lot of clusters volumesize *= 512; // SD card blocks are always 512 bytes Serial.print("Volume size (bytes): "); Serial.println(volumesize); Serial.print("Volume size (Kbytes): "); volumesize /= 1024; Serial.println(volumesize); Serial.print("Volume size (Mbytes): "); volumesize /= 1024; Serial.println(volumesize); Serial.println("\nFiles found on the card (name, date and size in bytes): "); root.openRoot(volume); // list all files in the card with date and size root.ls(LS_R | LS_DATE | LS_SIZE); } void loop(void) { }
This code tests a lot of things on the SD card, such as the file format and available space, and also lists all the files present on the SD card. However, what we are really interested in is to know whether the SD card can be read by the Arduino board. This is done with the following code snippet:
if (!card.init(SPI_HALF_SPEED, chipSelect)) { Serial.println("initialization failed. Things to check:"); Serial.println("* is a card inserted?"); Serial.println("* is your wiring correct?"); Serial.println("* did you change the chipSelect pin to match your shield or module?"); return; } else { Serial.println("Wiring is correct and a card is present."); }
Now, let's test the code. You can simply copy this code and paste it into the Arduino IDE.
Then, upload it to the Arduino Uno board and open the serial monitor. Make sure that the serial speed is set to 115200
bps. This is what you will see:
If you can see this, congratulations, your SD card and card reader are correctly configured and ready to host some spy audio recordings!