Humidity Logger and display to 7segment

Hi all,

I need a help to build a humidity data logger using 7 segment with sd card and RTC DS1307. So far i already log the humidity data to SD card but i can not display with 7 segment 4 digit,can you help me to add the code for 7 segment
Below is my code :

#include <SD.h>
#include <Wire.h>
#include "RTClib.h"
#include <SHT1x.h>

// Specify data and clock connections and instantiate SHT1x object
#define dataPin  5
#define clockPin 6

SHT1x sht1x(dataPin, clockPin);

// A simple data logger for the Arduino analog pins

// how many milliseconds between grabbing data and logging it. 1000 ms is once a second
#define LOG_INTERVAL 10*1000 // mills between entries (reduce to take more/faster data)

// how many milliseconds before writing the logged data permanently to disk
// set it to the LOG_INTERVAL to write each time (safest)
// set it to 10*LOG_INTERVAL to write all data every 10 datareads, you could lose up to
// the last 10 reads if power is lost but it uses less power and is much faster!
#define SYNC_INTERVAL 1000 // mills between calls to flush() - to write data to the card
uint32_t syncTime = 0; // time of last sync()

#define ECHO_TO_SERIAL 1 // echo data to serial port
#define WAIT_TO_START 0 // Wait for serial input in setup()

// the digital pins that connect to the LEDs
#define redLEDpin 2
#define greenLEDpin 3

// The analog pins that connect to the sensors
#define photocellPin 0 // analog 0
#define tempPin 1 // analog 1
#define BANDGAPREF 14 // special indicator that we want to measure the bandgap

#define aref_voltage 3.3 // we tie 3.3V to ARef and measure it with a multimeter!
#define bandgap_voltage 1.1 // this is not super guaranteed but its not -too- off

RTC_DS1307 RTC; // define the Real Time Clock object

// for the data logging shield, we use digital pin 10 for the SD cs line
const int chipSelect = 10;

// the logging file
File logfile;

void error(char *str)
{
  Serial.print("error: ");
  Serial.println(str);

  // red LED indicates error
  digitalWrite(redLEDpin, HIGH);

  while(1);
}

void setup(void)
{
  Serial.begin(9600);
  Serial.println();

  // use debugging LEDs
  pinMode(redLEDpin, OUTPUT);
  pinMode(greenLEDpin, OUTPUT);

#if WAIT_TO_START
  Serial.println("Type any character to start");
  while (!Serial.available());
#endif //WAIT_TO_START

  // initialize the SD card
  Serial.print("Initializing SD card...");
  // make sure that the default chip select pin is set to
  // output, even if you don't use it:
  pinMode(10, OUTPUT);

  // see if the card is present and can be initialized:
  if (!SD.begin(chipSelect)) {
    error("Card failed, or not present");
  }
  Serial.println("card initialized.");

  // create a new file
  char filename[] = "LOGGER00.CSV";
  for (uint8_t i = 0; i < 100; i++) {
    filename[6] = i/10 + '0';
    filename[7] = i%10 + '0';
    if (! SD.exists(filename)) {
      // only open a new file if it doesn't exist
      logfile = SD.open(filename, FILE_WRITE);
      break; // leave the loop!
    }
  }

  if (! logfile) {
    error("couldnt create file");
  }

  Serial.print("Logging to: ");
  Serial.println(filename);

  // connect to RTC
  Wire.begin();
  if (!RTC.begin()) {
    logfile.println("RTC failed");
#if ECHO_TO_SERIAL
    Serial.println("RTC failed");
#endif //ECHO_TO_SERIAL
  }


  logfile.println("millis,stamp,datetime,light,temp,tempc,humidity,vcc");
#if ECHO_TO_SERIAL
  Serial.println("millis,stamp,datetime,light,temp,tempc,humidity,vcc");
#endif //ECHO_TO_SERIAL

  // If you want to set the aref to something other than 5v
  analogReference(EXTERNAL);
}

void loop(void)
{
  float temp_c;
  float humidity;
  float humidityOffset = 0.0;
  float tempOffset = -3.0;

  // Read values from the sensor
  temp_c = sht1x.readTemperatureC()  + tempOffset; 
  humidity = sht1x.readHumidity() + humidityOffset;
  DateTime now;

  // delay for the amount of time we want between readings
  delay((LOG_INTERVAL -1) - (millis() % LOG_INTERVAL));

  digitalWrite(greenLEDpin, HIGH);

  // log milliseconds since starting
  uint32_t m = millis();
  logfile.print(m); // milliseconds since start
  logfile.print(", ");
#if ECHO_TO_SERIAL
  Serial.print(m); // milliseconds since start
  Serial.print(", ");
#endif

  // fetch the time
  now = RTC.now();
  // log time
  logfile.print(now.unixtime()); // seconds since 1/1/1970
  logfile.print(", ");
  logfile.print('"');
  logfile.print(now.year(), DEC);
  logfile.print("/");
  logfile.print(now.month(), DEC);
  logfile.print("/");
  logfile.print(now.day(), DEC);
  logfile.print(" ");
  logfile.print(now.hour(), DEC);
  logfile.print(":");
  logfile.print(now.minute(), DEC);
  logfile.print('"');
#if ECHO_TO_SERIAL
  Serial.print(now.unixtime()); // seconds since 1/1/1970
  Serial.print(", ");
  Serial.print('"');
  Serial.print(now.year(), DEC);
  Serial.print("/");
  Serial.print(now.month(), DEC);
  Serial.print("/");
  Serial.print(now.day(), DEC);
  Serial.print(" ");
  Serial.print(now.hour(), DEC);
  Serial.print(":");
  Serial.print(now.minute(), DEC);
  Serial.print('"');
#endif //ECHO_TO_SERIAL

  analogRead(photocellPin);
  delay(10);
  int photocellReading = analogRead(photocellPin);

  analogRead(tempPin);
  delay(10);
  int tempReading = analogRead(tempPin);

  // converting that reading to voltage, for 3.3v arduino use 3.3, for 5.0, use 5.0
  float voltage = tempReading * aref_voltage / 1024;
  float temperatureC = (voltage - 0.5) * 100 ;
  float temperatureF = (temperatureC * 9 / 5) + 32;

  logfile.print(", ");
  logfile.print(photocellReading);
  logfile.print(", ");
  logfile.print(temperatureF);
  logfile.print(", ");
  logfile.print(temp_c, DEC);
  logfile.print(", ");
  logfile.print(humidity, DEC);
#if ECHO_TO_SERIAL
  Serial.print(", ");
  Serial.print(photocellReading);
  Serial.print(", ");
  Serial.print(temperatureF);
  Serial.print(", ");
  Serial.print(temp_c, DEC);
  Serial.print(", ");
  Serial.print(humidity, DEC);
#endif //ECHO_TO_SERIAL

  // Log the estimated 'VCC' voltage by measuring the internal 1.1v ref
  analogRead(BANDGAPREF);
  delay(10);
  int refReading = analogRead(BANDGAPREF);
  float supplyvoltage = (bandgap_voltage * 1024) / refReading;

  logfile.print(", ");
  logfile.print(supplyvoltage);
#if ECHO_TO_SERIAL
  Serial.print(", ");
  Serial.print(supplyvoltage);
#endif // ECHO_TO_SERIAL

  logfile.println();
#if ECHO_TO_SERIAL
  Serial.println();
#endif // ECHO_TO_SERIAL

  digitalWrite(greenLEDpin, LOW);

  // Now we write data to disk! Don't sync too often - requires 2048 bytes of I/O to SD card
  // which uses a bunch of power and takes time
  if ((millis() - syncTime) < SYNC_INTERVAL) return;
  syncTime = millis();

  // blink LED to show we are syncing data to the card & updating FAT!
  digitalWrite(redLEDpin, HIGH);
  logfile.flush();
  digitalWrite(redLEDpin, LOW);
  // delay(300000);

}

What kind of 7-segment display do you have? Please provide a link to the hardware you're using, there are many different types of these displays on the market.

I am using 7segment like this http://www.digikey.com/product-detail/en/LF-301MA/511-1568-6-ND/1851274

The link shows a one digit element. Do you have four of these? How have you wired them? Do you have the common anode or the common cathode version of the modules? To which type of Arduino are you connecting them?

the circuit for 7 segment like this :
i attach file as pdf

ARDUINO-7-SEG-DISPLAY-REV1.1.pdf (16.3 KB)

And wich pins are you using for data, latch and clock?

Didn't you get an Arduino library to use with this design too?

And you can already prepare your sketch: remove all calls to delay()! Your loop must run at least 200 times a second, so the slightest delay will cause a flickering on the display. Learn with the BlinkWithoutDelay example of the Arduino IDE how to code wait periods without blocking the processor.

I have try it but it does'nt work..please help me to add the code to show with 7 segment.

Have you read my post? You neither did answer my questions nor change the sketch as instructed.