Here I'd like share with hobbyists community a simple project that can be used as a base to learn Arduino programming - the electronic clock with RTC (Real Time Clock) module and LCD/keypad shield.
Hardware:
1) MINI Arduino I2C RTC DS1307 AT24C32 module.
eBay item# 180646747674 by seller: e_goto
Serial: SKU 00100-049
2) Keypad Shield 1602 LCD For Arduino MEGA 2560 1280 UNO R3 A005
eBay item# 261039184894 by seller: womarts
The LCD/keypad shield you just put on top of the Arduino Uno compatible board. The RTC module is connected as outlined below:
RTC module -> Arduino Uno
SCL -> A5
SDA -> A4
VCC -> A3
GND -> A2
Note: the power to RTC (i2c_ds1307_at24c32) module is provided via Arduino's A2, A3 pins. The program code ensures proper logic levels/polarity on these pins so the RTC module gets the power through them.
Keypad functions:
SELECT - Switch between Clock Set/Clock Run modes. Select the date/time
parameter to setup in the Clock Set mode.
LEFT - Immediately exit Clock Set mode and set the clock.
UP/DOWN - Increment/decrement selected date/time parameter.
The code:
/*
* Date and time functions using a DS1307 RTC connected via I2C
* and Wire lib
* It is a simple clock application.
* Author: Marek Karcz 2013. All rights reserved.
* License: Freeware.
* Disclaimer: Use at your own risk.
* Hardware:
* 1) MINI Arduino I2C RTC DS1307 AT24C32 module.
* eBay item# 180646747674 by seller: e_goto
* Serial: SKU 00100-049
* 2) Keypad Shield 1602 LCD For Arduino MEGA 2560 1280 UNO
* R3 A005
* eBay item# 261039184894 by seller: womarts
*/
/*
The LCD circuit:
* LCD RS pin to digital pin 8
* LCD Enable pin to digital pin 9
* LCD D4 pin to digital pin 4
* LCD D5 pin to digital pin 5
* LCD D6 pin to digital pin 6
* LCD D7 pin to digital pin 7
* LCD BL pin to digital pin 10
* KEY pin to analog pin 0
*/
#include <Wire.h>
#include "RTClib.h"
#include <LiquidCrystal.h>
#define LOOP_DELAY 2000
LiquidCrystal lcd(8, 13, 9, 4, 5, 6, 7);
RTC_DS1307 RTC;
boolean bBlink = true;
const char *appVer = "MKHBC RTC 1.3 ";
const char *modTxt = "Set clock ... ";
// Global variables for time setup/displaying purposes.
uint16_t set_Year;
uint8_t set_Month;
uint8_t set_Day;
uint8_t set_Hour;
uint8_t set_Minute;
/*
* Keypad shield uses resistors array and single analog input.
* The values in adc_key_val array help to determine which
* key on the shield was pressed by checking the analog input
* read value.
*/
const int adc_key_val[5] ={50, 200, 400, 600, 800 };
int adc_key_in;
// keypad keys definitions
enum KP
{
KEY_RIGHT = 0,
KEY_UP,
KEY_DOWN,
KEY_LEFT,
KEY_SELECT,
KEY_NUMKEYS, // mark the end of key definitions
KEY_NONE // definition of none of the keys pressed
};
// Finite Machine States
enum FMS
{
RUN = 0,
SETCLOCK,
SETYEAR,
SETMONTH,
SETDAY,
SETHOUR,
SETMINUTE
} ClockState;
// Finite Machine State Transitions Table.
// Defines the flow of the application modes from one to another.
enum FMS StateMachine[] =
{
/* RUN -> */ SETCLOCK,
/* SETCLOCK -> */ SETYEAR,
/* SETYEAR -> */ SETMONTH,
/* SETMONTH -> */ SETDAY,
/* SETDAY -> */ SETHOUR,
/* SETHOUR -> */ SETMINUTE,
/* SETMINUTE -> */ RUN
};
enum KP key = KEY_NONE;
// Array of the numbers of month days.
const unsigned int month_days [] =
{31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31};
const char *daysOfWeek[] =
{ "Su", "Mo", "Tu", "We", "Th", "Fr", "Sa" };
int nDelay = 0; // controlling loops/key press latency
void setup ()
{
nDelay = 0;
key = KEY_NONE;
// initialize LCD keypad module
lcd.clear();
lcd.begin(16, 2);
lcd.setCursor(0,0);
lcd.print(appVer);
// power to i2c_ds1307_at24c32 module provided via A2, A3 pins
pinMode(A3, OUTPUT);
digitalWrite(A3, HIGH);
pinMode(A2, OUTPUT);
digitalWrite(A2, LOW);
// start communication, I2C and RTC
Wire.begin();
RTC.begin();
ClockState = RUN;
readKey();
// if key SELECT is held at RESET/Start up procedure
if (key == KEY_SELECT)
{
setClock(RTC.isrunning());
}
else if (key == KEY_LEFT) // if key LEFT is held at RESET
{
// following line sets the RTC to the date & time this sketch
// was compiled
RTC.adjust(DateTime(__DATE__, __TIME__));
}
else if (! RTC.isrunning()) // if battery was changed
{
setClock(false);
}
}
void loop ()
{
readKey();
if (key == KEY_SELECT)
{
ClockState = StateMachine[ClockState]; // switch mode
delay(330);
}
switch (ClockState)
{
case RUN:
if (nDelay <= 0)
{
DateTime now = RTC.now();
dispTime(now.year(),
now.month(),
now.day(),
now.hour(),
now.minute(),
now.dayOfWeek());
bBlink = ((bBlink) ? false : true);
}
break;
case SETCLOCK:
nDelay = 0;
lcd.setCursor(0,0);
lcd.print(modTxt);
setClock(RTC.isrunning());
lcd.setCursor(0,0);
lcd.print(appVer);
break;
default: break;
}
if (nDelay <= 0)
nDelay = LOOP_DELAY;
else
nDelay--;
}
/*
* Functions to aid displaying the date/time.
*/
void dispYear(uint16_t yr)
{
if (ClockState == SETYEAR)
{
if (bBlink)
lcd.print(yr, DEC);
else
lcd.print(" ");
}
else
lcd.print(yr, DEC);
}
void dispMonth(uint8_t mo)
{
if (ClockState == SETMONTH)
{
if (bBlink)
lcd.print(mo, DEC);
else
{
lcd.print(' ');
if (mo >= 10)
lcd.print(' ');
}
}
else
lcd.print(mo, DEC);
}
void dispDay(uint8_t dy)
{
if (ClockState == SETDAY)
{
if (bBlink)
lcd.print(dy, DEC);
else
{
lcd.print(' ');
if (dy >= 10)
lcd.print(' ');
}
}
else
lcd.print(dy, DEC);
}
void dispHour(uint8_t hr)
{
if (hr < 10)
{
if (ClockState == SETHOUR)
{
if (bBlink)
lcd.print('0');
else
lcd.print(' ');
}
else
lcd.print('0');
}
if (ClockState == SETHOUR)
{
if (bBlink)
lcd.print(hr, DEC);
else
{
lcd.print(' ');
if (hr >= 10)
lcd.print(' ');
}
}
else
lcd.print(hr, DEC);
}
void dispMinute(uint8_t mn)
{
if (mn < 10)
{
if (ClockState == SETMINUTE)
{
if (bBlink)
lcd.print('0');
else
lcd.print(' ');
}
else
lcd.print('0');
}
if (ClockState == SETMINUTE)
{
if (bBlink)
lcd.print(mn, DEC);
else
{
lcd.print(' ');
if (mn >= 10)
lcd.print(' ');
}
}
else
lcd.print(mn, DEC);
}
void dispTime(uint16_t yr,
uint8_t mo,
uint8_t dy,
uint8_t hr,
uint8_t mn,
uint8_t dow)
{
lcd.setCursor(0,1);
dispYear(yr);
lcd.print('/');
dispMonth(mo);
lcd.print('/');
dispDay(dy);
lcd.print(' ');
lcd.print(' ');
lcd.setCursor(11,1);
dispHour(hr);
if (ClockState == RUN)
{
if (bBlink)
lcd.print(':');
else
lcd.print(' ');
}
else
lcd.print(':');
dispMinute(mn);
lcd.setCursor (14, 0);
lcd.print(daysOfWeek[dow]);
}
/*
* Functions to aid setting date/time.
*/
void setYear(boolean incdec)
{
if (incdec)
{
if (set_Year < 2100)
set_Year++;
}
else
{
if (set_Year > 2000)
set_Year--;
}
}
void setMonth(boolean incdec)
{
if (incdec)
{
if (set_Month < 12)
set_Month++;
}
else
{
if (set_Month > 1)
set_Month--;
}
}
void setDay(boolean incdec)
{
if (incdec)
{
if ((set_Month != 2 && set_Day < month_days[set_Month])
||
(set_Month == 2 && set_Day < 28)
||
(set_Month == 2 && set_Day == 28 && isLeapYear(set_Year))
)
set_Day++;
}
else
{
if (set_Day > 1)
set_Day--;
}
}
void setHour(boolean incdec)
{
if (incdec)
{
if (set_Hour < 23)
set_Hour++;
else
set_Hour = 0;
}
else
{
if (set_Hour > 1)
set_Hour--;
else
set_Hour = 23;
}
}
void setMinute(boolean incdec)
{
if (incdec)
{
if (set_Minute < 59)
set_Minute++;
else
set_Minute = 0;
}
else
{
if (set_Minute > 1)
set_Minute--;
else
set_Minute = 59;
}
}
void setDateTime(boolean incdec)
{
if (incdec)
{
switch (ClockState)
{
case SETYEAR:
setYear(true); // increment year
break;
case SETMONTH:
setMonth(true); // increment month
break;
case SETDAY:
setDay(true); // increment day
break;
case SETHOUR:
setHour(true); // increment hour
break;
case SETMINUTE:
setMinute(true); // increment minute
break;
default: break;
}
}
else
{
switch (ClockState)
{
case SETYEAR:
setYear(false); // decrement year
break;
case SETMONTH:
setMonth(false); // decrement month
break;
case SETDAY:
setDay(false); // decrement day
break;
case SETHOUR:
setHour(false); // decrement hour
break;
case SETMINUTE:
setMinute(false); // decrement minute
default: break;
}
}
}
void setClock(boolean readrtc)
{
DateTime now = DateTime(2013,1,1,0,0,0);
if (readrtc)
now = RTC.now();
delay(500);
set_Year = now.year();
set_Month = now.month();
set_Day = now.day();
set_Hour = now.hour();
set_Minute = now.minute();
ClockState = SETYEAR;
while (ClockState >= SETCLOCK)
{
if (nDelay <= 0)
{
dispTime(set_Year,
set_Month,
set_Day,
set_Hour,
set_Minute,
now.dayOfWeek());
bBlink = ((bBlink) ? false : true);
}
readKey();
if (key == KEY_UP || key == KEY_DOWN)
bBlink = true;
if (key == KEY_SELECT)
{
ClockState = StateMachine[ClockState];
delay(330);
}
else
{
if (nDelay <= 0)
{
if (key == KEY_UP)
{
setDateTime(true); // increment
}
else if (key == KEY_DOWN)
{
setDateTime(false); // decrement
}
else if (key == KEY_LEFT)
{
ClockState = RUN; // exit set clock mode
}
nDelay = LOOP_DELAY;
}
}
if (nDelay <= 0)
nDelay = LOOP_DELAY;
else
nDelay--;
//delay(330);
}
RTC.adjust(DateTime(set_Year,
set_Month,
set_Day,
set_Hour,
set_Minute,
0));
}
// Determine the leap year.
boolean isLeapYear(uint16_t yr)
{
if ((yr%400)==0)
return true;
else if ((yr%100)==0)
return false;
else if ((yr%4)==0)
return true;
return false;
}
// Get key code from analog input.
unsigned int get_key(unsigned int input)
{
unsigned int k;
for (k = KEY_RIGHT; k < KEY_NUMKEYS; k++)
{
if (input < adc_key_val[k])
{
return k;
}
}
if (k >= KEY_NUMKEYS) k = KEY_NONE; // No valid key pressed
return k;
}
// Read analog input 0 to obtain key code in global variable: key
void readKey(void)
{
key = KEY_NONE;
adc_key_in = analogRead(0); // read the value from the sensor
// convert into key press
key = (enum KP) get_key(adc_key_in);
}
Some pictures of the working application/hardware:
Thanks for looking.
Marek Karcz
2013/1/5
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