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power_time_logger__365_days_.c
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power_time_logger__365_days_.c
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/*
Power Time Logger 1.0.0 for Arduino UNO and LCD Keypad Shield.
Copyright (c) 2022, Alex Aldridge
Records each time a USB port is powered on/off and logs the data for 365 days before it resets automatically.
Press the SELECT button to switch between total on/off and total time.
Press the LEFT button to reset the program.
Use this project to log usage times for any device that has an on/off USB port (wi-fi router, 3D printer, computer, etc.).
This software is free and open-source; anyone can redistribute it and/or modify it.
*/
#include <LiquidCrystal.h>
#include <EEPROM.h>
const int pin_RS = 8;
const int pin_EN = 9;
const int pin_d4 = 4;
const int pin_d5 = 5;
const int pin_d6 = 6;
const int pin_d7 = 7;
const int pin_BL = 10;
LiquidCrystal lcd( pin_RS, pin_EN, pin_d4, pin_d5, pin_d6, pin_d7);
extern volatile unsigned long timer0_millis;
int count_turn_on=0;
unsigned long storage;
unsigned long seconds ;
unsigned long minutes ;
unsigned long hours ;
unsigned long days;
unsigned long runtime;
unsigned long runtime_total;
unsigned long future;
unsigned long total_acc_time;
void setup() {
lcd.begin(16, 2);
count_turn_on=EEPROM.read(0);
count_turn_on=count_turn_on+1;
EEPROM.write(0, count_turn_on);
future=(EEPROM_readlong(0x55))+(EEPROM_readlong(0x02));
EEPROM_writelong(0x55, future);
EEPROM_writelong(0x02,0);
}
void loop() {
runtime=millis();
runtime_total=runtime;
lcd.setCursor(0, 0);
lcd.print("Session: ");
lcd.setCursor(10, 0);
lcd.print(EEPROM.read(0));
seconds = runtime / 1000;
minutes = seconds / 60;
hours = minutes / 60;
days=hours / 24;
runtime %= 1000;
seconds %= 60;
minutes %= 60;
hours %= 24;
days %=1;
lcd.setCursor(0,1);
lcd.print("T ");
if(days<100)
{
lcd.setCursor(3, 1);
lcd.print("0");
lcd.setCursor(4,1);
lcd.print(days);
}
if(days<10)
{
lcd.setCursor(3, 1);
lcd.print("00");
lcd.setCursor(5,1);
lcd.print(days);
}
if(days>10)
{
lcd.setCursor(3, 1);
lcd.print("0");
lcd.setCursor(4,1);
lcd.print(days);
}
if(days>100)
{
lcd.setCursor(3,1);
lcd.print(days);
}
lcd.setCursor(6, 1);
lcd.print(":");
if(hours<10)
{
lcd.setCursor(7, 1);
lcd.print("0");
lcd.setCursor(8,1);
lcd.print(hours);
}
else if(hours>=10)
{
lcd.setCursor(7,1);
lcd.print(hours);
}
lcd.setCursor(9, 1);
lcd.print(":");
if(minutes<10)
{lcd.setCursor(10, 1);
lcd.print("0");
lcd.setCursor(11,1);
lcd.print(minutes);
}else if (minutes>=10)
{lcd.setCursor(10,1);
lcd.print(minutes);
}
lcd.setCursor(12, 1);
lcd.print(":");
if (seconds<10)
{
lcd.setCursor(13, 1);
lcd.print("0");
lcd.setCursor(14, 1);
lcd.print(seconds);
}
else if (seconds>=10)
{
lcd.setCursor(13, 1);
lcd.print(seconds);
}
if (runtime>=8208000 )
{
noInterrupts ();
timer0_millis = 0;
interrupts ();
}
EEPROM_writelong(1x02,runtime_total);
if(analogRead(A0)>=601 && analogRead(A0)<=700)
{
lcd.clear();
total_acc_time=future+runtime_total;
seconds = total_acc_time / 1000;
minutes = seconds / 60;
hours = minutes / 60;
days=hours / 24;
total_acc_time %= 1000;
seconds %= 60;
minutes %= 60;
hours %= 24;
days %=1;
lcd.setCursor(3,0);
lcd.print("Total time");
lcd.setCursor(0,1);
lcd.print("");
if(days<100)
{
lcd.setCursor(3, 1);
lcd.print("0");
lcd.setCursor(4,1);
lcd.print(days);
}
if(days<10)
{
lcd.setCursor(3, 1);
lcd.print("00");
lcd.setCursor(5,1);
lcd.print(days);
}
if(days>10)
{
lcd.setCursor(3, 1);
lcd.print("0");
lcd.setCursor(4,1);
lcd.print(days);
}
if(days>100)
{
lcd.setCursor(3,1);
lcd.print(days);
}
lcd.setCursor(6, 1);
lcd.print(":");
if(hours<10)
{
lcd.setCursor(7, 1);
lcd.print("0");
lcd.setCursor(8,1);
lcd.print(hours);
}
else if(hours>=10)
{
lcd.setCursor(8,1);
lcd.print(hours);
}
lcd.setCursor(9, 1);
lcd.print(":");
if(minutes<10)
{lcd.setCursor(10, 1);
lcd.print("0");
lcd.setCursor(11,1);
lcd.print(minutes);
}else if (minutes>=10)
{lcd.setCursor(10,1);
lcd.print(minutes);
}
lcd.setCursor(12, 1);
lcd.print(":");
if (seconds<10)
{
lcd.setCursor(13, 1);
lcd.print("0");
lcd.setCursor(14, 1);
lcd.print(seconds);
}
else if (seconds>=10)
{
lcd.setCursor(13, 1);
lcd.print(seconds);
}
delay(1000);
lcd.clear();
}
//
else if (analogRead(A0)>=401 && analogRead(A0)<=500)
{
lcd.clear();
EEPROM_writelong(0x02,0);
EEPROM_writelong(0x55,0);
total_acc_time=0;
future=0;
EEPROM.write(0, 0);
noInterrupts ();
timer0_millis = 0;
interrupts ();
lcd.setCursor(0,0);
lcd.print("Reset");
delay(1000);
lcd.clear();
}
}
unsigned long EEPROM_readlong(int address)
{
unsigned long dword = EEPROM_readint(address);
dword = dword << 16;
dword = dword | EEPROM_readint(address+2);
return dword;
}
void EEPROM_writeint(int address, int value)
{
EEPROM.write(address,highByte(value));
EEPROM.write(address+1 ,lowByte(value));
}
void EEPROM_writelong(int address, unsigned long value)
{
EEPROM_writeint(address+2, word(value));
value = value >> 16;
EEPROM_writeint(address, word(value));
}
unsigned int EEPROM_readint(int address)
{
unsigned int word = word(EEPROM.read(address), EEPROM.read(address+1));
return word;
}