Buonasera a tutti e grazie UFOSTUFO per la collaborazione nel progetto..
Oltre alla infinita pazienza dimostrata
Di seguito è allegato il CODICE ARDULAB VER 1.0 e le librerie
I problemi riscontrati non sono stati pochi ,alcuni risolvibili ,altri no.
Il progetto nasce come Dummy Load ,ma visto l'ottimo comportamento nei test preliminari abbiamo osato spingerci oltre introducendo altre funzioni utili in un piccolo laboratorio,ma ne potremo aggiungere anche altre.
A voi il codice scritto di facile comprensione e con possibilità di personalizzazioni
//
//LISTATO ARDULAB MEGA VER 1.0
//
//Prodotto da ElettroshockNow & UFOSTUFO (ElettroshockNow@gmail.com)
//Condiviso su http://WWW.EnergiAlternativa.org
//
//Eventuali condivisioni su alri canali/Forum devono specificare
//il forum di origine http://WWW.ENERGIALTERNATIVA.ORG e la licenza
//di seguito specificata
//
//ATTENZIONE:
//
//CC BY-NC-SA 4.0
//Uso non commerciale, modificabile, con obbligo di condivisione-
//http://creativecommons.org/licenses/by-nc-sa/4.0/deed.it
//
//Librerie
#include <Wire.h>
#include <PCF8574_HD44780_I2C.h>
#include <Thermistor.h>
#include <EEPROMex.h>
#include <EEPROMvar.h>
//Configurazione Pin Arduino Mega2560
//USCITA PWM PWM_shunt PIN10
//USCITA PWM PWM_buck PIN9
//Ingressi Analogici
#define V_in_Pin 2
#define V_out_Pin 3
#define I_out_Pin 4
#define I_shunt_Pin 5
#define V_set_Pin 8
#define I_set_Pin 9
#define Key_Pin 10
//Ingressi/Uscite Digitali
#define Led_supply_Pin 2
#define Led_load_Pin 3
#define Led_shunt_Pin 4
#define Stab_Pin 8
#define Reset 9
#define Led_fault_Pin 10
#define Buzzer_Pin 18
//Definizione Costanti
#define menu 5
#define Num_Letture 20
#define Fattore_Corrente_Buck 0.075
#define Fattore_Corrente_Shunt 0.071 //0.0775
#define Fattore_Voltage 0.055
#define Kp_V 5//Gain Feedback Proporzionale //10
#define Ki_V 0 //Gain Feedback Integrale //0
#define Kd_V 0 //Gain Feedback Derivata //2
#define Kp_I 2//Gain Feedback Proporzionale
#define Ki_I 0//Gain Feedback Integrale
#define Kd_I 4//Gain Feedback Derivata
// Indirizzo LCD I2C 0x27, 20*4
PCF8574_HD44780_I2C lcd(0x27, 20, 4);
Thermistor temp(6);
//Variabili
int Temperatura,Offset_I_out,Offset_I_shunt;
unsigned long refresh,check,Start_charge,Time_charge,Last_millis;
float PWM_shunt,PWM_buck,I_out,I_shunt,V_out,V_in,I_max,V_max,Energia;
float errore_V,ePrec_V,eIntegr_V,errore_I,ePrec_I,eIntegr_I;
byte limita,Key,Set,memorizzare,ON;
//SETTAGGIO valori di DEFAULT (1°PowerUp)
int Screen = 20;//pagina di default "DUMMY LOAD"
byte Fuse = 25;
byte Vpot_min = 5;
byte Vpot_max = 30;
byte Ipot_min = 0;
byte Ipot_max = 20;
byte Ipot_min_Dum = 0;
byte Ipot_max_Dum = 20;
byte Ipot_min_Lim = 0;
byte Ipot_max_Lim = 10;
byte Stato_Buzzer = 1;
float VBat_charge = 14.7;
float IBat_charge = 5;
float VBat_discharge = 10.5;
float IBat_discharge = 5;
float VRef = 0.0;
byte clearlcd = 0;
byte sottomenu = 0;
byte Fault = 0;
byte Protezione = 0;
byte Allert = 0;
byte charge = 0 ;
void setup() {
pinMode(6, OUTPUT);
pinMode(7, OUTPUT);
pinMode(Led_supply_Pin, OUTPUT);
pinMode(Led_load_Pin, OUTPUT);
pinMode(Led_shunt_Pin, OUTPUT);
pinMode(Led_fault_Pin, OUTPUT);
pinMode(Buzzer_Pin, OUTPUT);
pinMode(Stab_Pin, OUTPUT);
pinMode(Reset, INPUT);
digitalWrite(6, LOW);
digitalWrite(Led_supply_Pin, LOW);
digitalWrite(Led_load_Pin, LOW);
digitalWrite(Led_shunt_Pin, LOW);
digitalWrite(Led_fault_Pin, LOW);
digitalWrite(Stab_Pin, LOW);
digitalWrite(Reset, HIGH);
// Doppia uscita PWM (BUCK&SHUNT) a 31.2Khz ,511 step
TCCR4A = _BV(COM4A1) | _BV(COM4A0) | _BV(COM4B1) | _BV(COM4B0) | _BV(WGM41); //Fast PWM, 10-bit
TCCR4B = _BV(CS40) | _BV(WGM42); //Prescaler a 1
OCR4A = 511;
OCR4B = 511;
Serial.begin(9600) ;
lcd.init();
lcd.backlight();
lcd.clear();
//MESSAGGIO DI BENVENUTO
lcd.setCursor(1, 0);
lcd.print("ArduLab Vers. 1.0");
lcd.setCursor(9, 1);
lcd.print("By");
lcd.setCursor(1, 2);
lcd.print("EnergiAlternativa");
lcd.setCursor(2, 3);
lcd.print("CC BY-NC-SA 4.0");
delay(2500);
lcd.clear();
lcd.setCursor(8, 1);
lcd.print("WWW.");
lcd.setCursor(1, 2);
lcd.print("ENERGIALTERNATIVA");
lcd.setCursor(8, 3);
lcd.print(".ORG");
delay(3000);
lcd.clear();
Offset_I_out = analogRead(I_out_Pin);
Offset_I_shunt = analogRead(I_shunt_Pin);
if (EEPROM.read(0) != 255) { //SALVATAGGIO DATI IN EEPROM
Vpot_min = EEPROM.read(0);
Vpot_max = EEPROM.read(1);
Ipot_min = EEPROM.read(2);
Ipot_max = EEPROM.read(3);
Ipot_min_Dum = EEPROM.read(4);
Ipot_max_Dum = EEPROM.read(5);
Ipot_min_Lim = EEPROM.read(6);
Ipot_max_Lim = EEPROM.read(7);
Stato_Buzzer = EEPROM.read(8);
VBat_charge = EEPROM.readFloat(20);
IBat_charge = EEPROM.readFloat(24);
VBat_discharge = EEPROM.readFloat(28);
IBat_discharge = EEPROM.readFloat(32);
}
if (Stato_Buzzer) {
digitalWrite(Buzzer_Pin, HIGH);
delay(500);
digitalWrite(Buzzer_Pin, LOW);
}
}
void loop() {
ArduLab(); //Subroutine misure e PWM
Tastiera();//Subroutine la Tastiera
Display();//Subroutine il Display
}
void Display() { //Subroutine visualizzazione su Display LCD 20*4
if (millis() > (refresh + 500))
{
refresh = millis();
if (clearlcd) {
lcd.clear();
clearlcd = 0;
}
if (Fault) { //AVARIA
digitalWrite(Led_fault_Pin, HIGH);
lcd.setCursor(0, 0);
lcd.print("FAULT");
lcd.setCursor(0, 1);
switch (Fault) {
case 1://CORTOCIRCUITO
lcd.print("CORTO");
break;
case 2:
lcd.print("FUSE SEZIONE BUCK");
break;
case 3:
lcd.print("Vin Bassa Tensione");
break;
case 4:
lcd.print("Vin Alta Tensione ");
break;
case 5:
lcd.print("FUSE SEZIONE SHUNT");
break;
case 6:
lcd.print("Temperatura Limite");
break;
case 7:
break;
case 8:
break;
case 9:
break;
case 10:
break;
}
}
else { //NORMAL
lcd.setCursor(0, 0);
if (Set == 1)
{
lcd.print("SET");
memorizzare = 1;
}
else if (ON == 0)
{
lcd.print("OFF");
if (memorizzare) {
EEPROM.write(0, Vpot_min);
EEPROM.write(1, Vpot_max);
EEPROM.write(2, Ipot_min);
EEPROM.write(3, Ipot_max);
EEPROM.write(4, Ipot_min_Dum);
EEPROM.write(5, Ipot_max_Dum);
EEPROM.write(6, Ipot_min_Lim);
EEPROM.write(7, Ipot_max_Lim);
EEPROM.write(8, Stato_Buzzer);
EEPROM.writeFloat(20, VBat_charge);
EEPROM.writeFloat(24, IBat_charge);
EEPROM.writeFloat(28, VBat_discharge);
EEPROM.writeFloat(32, IBat_discharge);
memorizzare = 0;
}
}
else lcd.print("ON");
switch (Screen) {
case 0://MENU
sottomenu = 2;
lcd.setCursor(7, 0);
lcd.print("MENU");
lcd.setCursor(0, 1);
lcd.print("Temp=");
lcd.print(Temperatura, 1);
lcd.print("C");
lcd.setCursor(0, 2);
lcd.print("Buzzer=");
if (Stato_Buzzer)lcd.print("ON");
else lcd.print("OFF");
break;
case 1:
sottomenu = 2;
lcd.setCursor(7, 0);
lcd.print("SILENZIA");
lcd.setCursor(0, 2);
lcd.print("Buzzer=");
if (Stato_Buzzer)lcd.print("ON");
else lcd.print("OFF");
break;
case 2:
sottomenu = 2;
lcd.setCursor(0, 0);
lcd.print("IL PROGETTO ARDULAB");
lcd.setCursor(0, 1);
lcd.print("VIENE RILASCIATO");
lcd.setCursor(0, 2);
lcd.print("CON LICENZA COMMONS");
lcd.setCursor(0, 3);
lcd.print("CC BY-NC-SA 4.0");
break;
case 10: //ALIMENTATORE
sottomenu = 2;
digitalWrite(Stab_Pin, HIGH);
V_max = float(analogRead(V_set_Pin) * (Vpot_max - Vpot_min)) / 1023 + Vpot_min;
I_max = float(analogRead(I_set_Pin) * (Ipot_max - Ipot_min)) / 1023 + Ipot_min;
digitalWrite(Led_supply_Pin, HIGH);
digitalWrite(Led_load_Pin, HIGH);
digitalWrite(Led_shunt_Pin, LOW);
lcd.setCursor(4, 0);
lcd.print("ALIMENTATORE");
lcd.setCursor(0, 1);
lcd.print("Vin=");
lcd.print(V_in, 1);
lcd.print("V ");
lcd.setCursor(10, 1);
lcd.print("Vout=");
lcd.print(V_out, 1);
lcd.print("V ");
lcd.setCursor(0, 2);
lcd.print("Pout=");
lcd.print((V_out * I_out), 0);
lcd.print("W");
lcd.setCursor(10, 2);
lcd.print("Iout=");
lcd.print(I_out, 1);
lcd.print("A ");
lcd.setCursor(0, 3);
lcd.print("Vs=");
lcd.print(V_max, 1);
lcd.print("V ");
lcd.setCursor(10, 3);
lcd.print("Is=");
lcd.print(I_max, 1);
lcd.print("A ");
break;
case 11:
lcd.setCursor(4, 0);
lcd.print("ALIMENTATORE");
lcd.setCursor(0, 1);
lcd.print("Range Pot Tensione ");
lcd.setCursor(0, 2);
lcd.print("min=");
lcd.print(Vpot_min);
lcd.print("V");
lcd.setCursor(10, 2);
lcd.print("max=");
lcd.print(Vpot_max);
lcd.print("V");
lcd.setCursor(0, 3);
//lcd.print("Vset=");
//lcd.print(V_max, 1);
//lcd.print("V");
break;
case 12:
lcd.setCursor(4, 0);
lcd.print("ALIMENTATORE");
lcd.setCursor(0, 1);
lcd.print("Range Pot Corrente ");
lcd.setCursor(0, 2);
lcd.print("min=");
lcd.print(Ipot_min);
lcd.print("A");
lcd.setCursor(10, 2);
lcd.print("max=");
lcd.print(Ipot_max);
lcd.print("A");
lcd.setCursor(0, 3);
lcd.print("Iset=");
lcd.print(I_max, 1);
lcd.print("A");
break;
case 20: //DUMMY LOAD
sottomenu = 1;
digitalWrite(Stab_Pin, LOW);
V_max = 32;
I_max = float(analogRead(I_set_Pin) * (Ipot_max_Dum - Ipot_min_Dum)) / 1023 + Ipot_min_Dum;
digitalWrite(Led_supply_Pin, HIGH);
digitalWrite(Led_load_Pin, LOW);
digitalWrite(Led_shunt_Pin, HIGH);
lcd.setCursor(5, 0);
lcd.print("DUMMY LOAD");
lcd.setCursor(0, 1);
lcd.print("Vin=");
lcd.print(V_in, 1);
lcd.print("V ");
lcd.setCursor(10, 1);
lcd.print("Iout=");
lcd.print(I_shunt, 1);
lcd.print("A ");
lcd.setCursor(0, 2);
lcd.print("Ref=");
lcd.print(VRef, 1);
lcd.print("V ");
lcd.setCursor(10, 2);
lcd.print("Pout=");
lcd.print((V_out * I_shunt), 0);
lcd.print("W");
lcd.setCursor(0, 3);
//lcd.print(Asc(223));
lcd.print("DV=");
lcd.print(V_in-VRef, 1);
lcd.print("V ");
lcd.setCursor(10, 3);
lcd.print("Is=");
lcd.print(I_max, 1);
lcd.print("A ");
break;
case 21:
lcd.setCursor(5, 0);
lcd.print("DUMMY LOAD");
lcd.setCursor(0, 1);
lcd.print("Range Pot Corrente ");
lcd.setCursor(0, 2);
lcd.print("min=");
lcd.print(Ipot_min_Dum);
lcd.print("A");
lcd.setCursor(10, 2);
lcd.print("max=");
lcd.print(Ipot_max_Dum);
lcd.print("A");
lcd.setCursor(0, 3);
break;
case 22:
lcd.setCursor(0, 0);
lcd.print("22");
break;
case 30://LIMITER
sottomenu = 1;
digitalWrite(Stab_Pin, LOW);
V_max = 32;
I_max = float(analogRead(I_set_Pin) * (Ipot_max_Lim - Ipot_min_Lim)) / 1023 + Ipot_min_Lim;
digitalWrite(Led_supply_Pin, HIGH);
digitalWrite(Led_load_Pin, HIGH);
digitalWrite(Led_shunt_Pin, LOW);
lcd.setCursor(6, 0);
lcd.print("LIMITER");
lcd.setCursor(0, 1);
lcd.print("Vin=");
lcd.print(V_in, 1);
lcd.print("V ");
lcd.setCursor(10, 1);
lcd.print("Vout=");
lcd.print(V_out, 1);
lcd.print("V ");
lcd.setCursor(0, 2);
lcd.print("Pout=");
lcd.print((V_out * I_out), 0);
lcd.print("W");
lcd.setCursor(10, 2);
lcd.print("Iout=");
lcd.print(I_out, 1);
lcd.print("A ");
lcd.setCursor(0, 3);
lcd.setCursor(10, 3);
lcd.print("Is=");
lcd.print(I_max, 1);
lcd.print("A ");
break;
case 31:
lcd.setCursor(6, 0);
lcd.print("LIMITER");
lcd.setCursor(0, 1);
lcd.print("Range Pot Corrente ");
lcd.setCursor(0, 2);
lcd.print("min=");
lcd.print(Ipot_min_Lim);
lcd.print("A");
lcd.setCursor(10, 2);
lcd.print("max=");
lcd.print(Ipot_max_Lim);
lcd.print("A");
lcd.setCursor(0, 3);
break;
case 32:
lcd.setCursor(0, 0);
lcd.print("32");
break;
case 40://Carica Batteria
sottomenu = 1;
digitalWrite(Stab_Pin, LOW);
V_max = VBat_charge;
I_max = IBat_charge;
digitalWrite(Led_supply_Pin, HIGH);
digitalWrite(Led_load_Pin, HIGH);
digitalWrite(Led_shunt_Pin, LOW);
lcd.setCursor(4, 0);
lcd.print("CARICA BATTERIA");
lcd.setCursor(0, 1);
lcd.print("V=");
lcd.print(V_out, 1);
lcd.print("V ");
lcd.setCursor(10, 1);
lcd.print("I=");
lcd.print(I_out, 1);
lcd.print("A ");
lcd.setCursor(0, 2);
lcd.print("T=");
lcd.print(Time_charge/60);
lcd.print("min");
lcd.setCursor(10, 2);
lcd.print("E=");
lcd.print(Energia / 3600/1000, 1);
lcd.print("Ah");
lcd.setCursor(0, 3);
if (ON && charge == 0)charge = 1;
if (charge) {
if (ON) {
lcd.print("IN CARICA...");
Time_charge = (millis() - Start_charge) / 1000;
Energia += (millis() - Last_millis) * I_out;
Last_millis = millis();
}
else
lcd.print("CARICA TERMINATA");
}
else {
Start_charge = millis();
Last_millis = millis();
}
if (V_out >= (VBat_charge - 0.1) && I_out < (IBat_charge / 5) && ON) {
ON = 0;
if (Stato_Buzzer) {
digitalWrite(Buzzer_Pin, HIGH);;
delay(100);
digitalWrite(Buzzer_Pin, LOW);
delay(100);
digitalWrite(Buzzer_Pin, HIGH);;
delay(1000);
digitalWrite(Buzzer_Pin, LOW);
}
}
break;
case 41:
lcd.setCursor(0, 0);
lcd.setCursor(4, 0);
lcd.print("CARICA BATTERIA");
lcd.setCursor(4, 1);
lcd.print("IMPOSTAZIONI");
lcd.setCursor(0, 2);
lcd.print("V=");
lcd.print(VBat_charge);
lcd.print("V");
lcd.setCursor(10, 2);
lcd.print("I=");
lcd.print(IBat_charge);
lcd.print("A");
break;
case 42:
break;
case 50://Scarica Batteria
sottomenu = 1;
digitalWrite(Stab_Pin, LOW);
digitalWrite(Led_supply_Pin, LOW);
digitalWrite(Led_load_Pin, HIGH);
digitalWrite(Led_shunt_Pin, HIGH);
lcd.setCursor(4, 0);
lcd.print("SCARICA BATTERIA");
lcd.setCursor(0, 1);
lcd.print("V=");
lcd.print(V_out, 1);
lcd.print("V ");
lcd.setCursor(10, 1);
lcd.print("I=");
lcd.print(I_shunt, 1);
lcd.print("A ");
lcd.setCursor(0, 2);
lcd.print("T=");
lcd.print(Time_charge/60);
lcd.print("min");
lcd.setCursor(10, 2);
lcd.print("E=");
lcd.print(Energia / 3600/1000, 1);
lcd.print("Ah");
lcd.setCursor(0, 3);
if (ON && charge == 0)charge = 1;
if (charge) {
if (ON) {
lcd.print("IN SCARICA...");
Time_charge = (millis() - Start_charge) / 1000;
Energia += (millis() - Last_millis) * I_shunt;
Last_millis = millis();
}
else
lcd.print("SCARICA TERMINATA");
}
else {
Start_charge = millis();
Last_millis = millis();
}
if (V_out < VBat_discharge && ON) {
ON = 0;
if (Stato_Buzzer) {
digitalWrite(Buzzer_Pin, HIGH);;
delay(1000);
digitalWrite(Buzzer_Pin, LOW);
delay(100);
digitalWrite(Buzzer_Pin, HIGH);;
delay(100);
digitalWrite(Buzzer_Pin, LOW);
}
}
break;
case 51:
lcd.setCursor(4, 0);
lcd.print("SCARICA BATTERIA");
lcd.setCursor(4, 1);
lcd.print("IMPOSTAZIONI");
lcd.setCursor(0, 2);
lcd.print("V=");
lcd.print(VBat_discharge);
lcd.print("V");
lcd.setCursor(10, 2);
lcd.print("I=");
lcd.print(IBat_discharge);
lcd.print("A"); ;
break;
case 52:
lcd.setCursor(0, 0);
lcd.print("52");
break;
case 60:
lcd.setCursor(0, 0);
lcd.print("60");
break;
case 61:
lcd.setCursor(0, 0);
lcd.print("61");
break;
case 62:
lcd.setCursor(0, 0);
lcd.print("62");
break;
default:
break;
}
}
}
}
void ArduLab() { //Subroutine misure e controllo PWM
Temperatura = temp.getTemp();
V_in = (analogRead(V_in_Pin) * Fattore_Voltage);
I_out = 0;
V_out = 0;
for (int i = 0; i < Num_Letture; i++) {
I_out = I_out + ((analogRead(I_out_Pin) - Offset_I_out));
I_shunt = I_shunt + ((analogRead(I_shunt_Pin) - Offset_I_shunt));
V_out = V_out + (analogRead(V_out_Pin) );
}
I_out = I_out / Num_Letture * Fattore_Corrente_Buck;
I_shunt = I_shunt / Num_Letture * Fattore_Corrente_Shunt;
V_out = V_out / Num_Letture * Fattore_Voltage;
if (I_shunt < 0)I_shunt = 0;
if (I_out < 0)I_out = 0;
if (Screen >= 10 && Screen < 20 | Screen >= 30 && Screen < 50) { //GESTIONE PWM ALIMENTATORE & LIMITER
PWM_shunt = 0;
//if (I_out < 0)I_out = 0;
if (I_out > I_max)limita = 1;
if (V_out > V_max)limita = 0;
errore_V = V_max - V_out;
errore_I = I_max - I_out;
if (limita)PWM_buck += ((Kp_I * errore_I) + (Ki_I * eIntegr_I) + (Kd_I * ePrec_I));
else PWM_buck += ((Kp_V * errore_V) + (Ki_V * eIntegr_V) + (Kd_V * ePrec_V));
/*
{
if (V_out>V_max)PWM_buck=0;
else PWM_buck=511;
}
*/
eIntegr_V += errore_V;
ePrec_V = errore_V;
eIntegr_I += errore_I;
ePrec_I = errore_I;
if (PWM_buck > 511)PWM_buck = 511;
else if (PWM_buck < 0)PWM_buck = 0;
}
if (Screen >= 20 && Screen < 30 ) { //GESTIONE PWM DUMMY LOAD
PWM_buck = 511;
limita = 1;
//if (I_shunt < 0)I_out = 0;
errore_I = I_max - I_shunt;
PWM_shunt += ((Kp_I * errore_I) + (Ki_I * eIntegr_I) + (Kd_I * ePrec_I));
eIntegr_I += errore_I;
ePrec_I = errore_I;
if (PWM_shunt > 511)PWM_shunt = 511;
else if (PWM_shunt < 0)PWM_shunt = 0;
}
if (Screen >= 50 && Screen < 60 ) { //GESTINE PWM SCARICA BATTERIA
PWM_buck = 0;
errore_I = IBat_discharge - I_shunt;
PWM_shunt += ((Kp_I * errore_I) + (Ki_I * eIntegr_I) + (Kd_I * ePrec_I));
eIntegr_I += errore_I;
ePrec_I = errore_I;
if (PWM_shunt > 511)PWM_shunt = 511;
else if (PWM_shunt < 0)PWM_shunt = 0;
}
//CONTROLLO USCITE
if (ON == 0 | Fault) { //SPENTO o in Fault
ON = 0;
OCR4A = 511;
OCR4B = 511;
errore_V = 0;
eIntegr_V = 0;
ePrec_V = 0;
errore_I = 0;
eIntegr_I = 0;
ePrec_I = 0;
PWM_shunt = 0;
PWM_buck = 0;
}
else { //ACCESO e OPERATIVO
OCR4A = 511 - PWM_shunt;
OCR4B = 511 - PWM_buck;
}
//PROTEZIONI VARIE
if (ON) {
if (I_out > Fuse)Fault = 2; //MAX corrente 25A sezione Buck
if (I_shunt > Fuse)Fault = 5;//MAX corrente 25A sezione Shunt
if (V_in < 5)Fault = 3; //Tensione in ingresso bassa
if (V_in > 35)Fault = 4; //Tensione in ingresso alta
if (Temperatura > 70)Fault = 6; //Temperatura
if (Fault)clearlcd = 1; //pulisci il display per visualizzare fault
}
}
void Tastiera() {//Selezione Pagine e gestione Variabili
if (digitalRead(Reset) == 0 && Screen==20)VRef=V_in;
if (digitalRead(Reset) == 0 && ON == 0) { //Resetta il Fault e charge
Energia = 0;
charge = 0;
Time_charge = 0;
Fault = 0;
clearlcd = 1;
digitalWrite(Led_fault_Pin, LOW);
}
if (Fault == 0) { //disattiva Tastiera se in Fault
byte decine = Screen / 10;
byte unita = Screen - (decine * 10);
int Key_Read = analogRead(Key_Pin);
Key = 0;
if (Key_Read < 880)Key = 1;
if (Key_Read < 620)Key = 2;
if (Key_Read < 414)Key = 3;
if (Key_Read < 233)Key = 4;
if (Key_Read < 70)Key = 5;
if (Key > 0)clearlcd = 1;
if (Key == 1 && unita == 0) {
if (ON)ON = 0;
else ON = 1;
}
if (Key == 1 && unita > 0) {
if (Set == 0) {
Set = 1;
ON = 0;
}
else {
Set = 0;
ON = 0;
Screen = decine * 10;
}
}
if (Set == 0) { //modalità navigazione menù
if (unita < sottomenu && Key == 3)Screen++;
if (unita > 0 && Key == 4)Screen--;
if (unita == 0 && decine < (menu + 1) && Key == 2) {
Screen += 10;
if (Screen == 10)Screen += 10; //SALTA FUNZIONE ALIMENTATORE
ON = 0;
}
if (Screen == ((menu + 1) * 10))Screen = 0;
if (unita == 0 && decine > 0 && Key == 5) {
Screen -= 10;
if (Screen == 10)Screen -= 10; //SALTA FUNZIONE ALIMENTATORE
ON = 0;
}
//if (Screen < 0)Screen = (menu * 10);
}
else switch (Screen) {
case 1:
if (Stato_Buzzer < 1 && Key == 2)Stato_Buzzer++;
if (Stato_Buzzer > 0 && Key == 5)Stato_Buzzer--;
break;
case 10:
break;
case 11:
if (Vpot_max < 32 && Key == 2)Vpot_max++;
if (Vpot_max > 0 && Key == 5)Vpot_max--;
if (Vpot_min < Vpot_max && Key == 4)Vpot_min++;
if (Vpot_min > 0 && Key == 3)Vpot_min--;
break;
case 12:
if (Ipot_max < 20 && Key == 2)Ipot_max++;
if (Ipot_max > 0 && Key == 5)Ipot_max--;
if (Ipot_min < Vpot_max && Key == 4)Ipot_min++;
if (Ipot_min > 0 && Key == 3)Ipot_min--;
break;
case 20:
break;
case 21:
if (Ipot_max_Dum < 20 && Key == 2)Ipot_max_Dum++;
if (Ipot_max_Dum > 0 && Key == 5)Ipot_max_Dum--;
if (Ipot_min_Dum < Vpot_max && Key == 4)Ipot_min_Dum++;
if (Ipot_min_Dum > 0 && Key == 3)Ipot_min_Dum--;
break;
case 22:
break;
case 30:
break;
case 31:
if (Ipot_max_Lim < 20 && Key == 2)Ipot_max_Lim++;
if (Ipot_max_Lim > 0 && Key == 5)Ipot_max_Lim--;
if (Ipot_min_Lim < Vpot_max && Key == 4)Ipot_min_Lim++;
if (Ipot_min_Lim > 0 && Key == 3)Ipot_min_Lim--;
break;
case 32:
break;
case 40:
break;
case 41:
if (VBat_charge < 32 && Key == 4)VBat_charge += 0.1;
if (VBat_charge > 0 && Key == 3)VBat_charge -= 0.1;
if (IBat_charge < 20 && Key == 2)IBat_charge += 0.1;
if (IBat_charge > 0 && Key == 5)IBat_charge -= 0.1;
break;
case 42:
break;
case 50:
break;
case 51:
if (VBat_discharge < 32 && Key == 4)VBat_discharge += 0.1;
if (VBat_discharge > 0 && Key == 3)VBat_discharge -= 0.1;
if (IBat_discharge < 20 && Key == 2)IBat_discharge += 0.1;
if (IBat_discharge > 0 && Key == 5)IBat_discharge -= 0.1;
break;
default:
break;
}
}
while (analogRead(Key_Pin) < 880) {//BEEP
if (Stato_Buzzer)digitalWrite(Buzzer_Pin, HIGH);
};
delay(50);
if (Stato_Buzzer)digitalWrite(Buzzer_Pin, LOW);
}
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Dummy Load con Arduino (Read 73308 times)
