/* mija 2009 - process
SW pro ATmega8 mereni + regulace teploty
Fosc = 8192000Hz externi krystal
ver.: 0.0 - start
*/
#include <avr/io.h>
#include <stdio.h>
#include <math.h>
#include "process.h"
#include "key.h"
#include "lcd.h"
#include "clock.h"
uint8_t ProcesStart(char *buffer,uint8_t key,uint16_t temp)
{
static uint8_t proces = SOLDER;
static uint8_t displ = 1;
static uint16_t LastTemp;
HeatOff();
if (key == TL1){
displ = 1;
return proces;
}
if ((key == TL2)){
switch (proces)
{
case POSITIV: proces = DRY;
break;
case DRY: proces = SOLDER;
break;
case SOLDER:
default: proces = POSITIV;
break;
}
displ = 1;
}
if (displ){
switch(proces)
{
case POSITIV:sprintf(buffer,"\fPOSITIV\n%3dC ch",temp);
break;
case DRY: sprintf(buffer,"\fDRY\n%3dC ch",temp);
break;
case SOLDER:
default: sprintf(buffer,"\fSOLDER\n%3dC ch",temp);
}
displ = 0;
}
else{
if (temp !=LastTemp){
sprintf(buffer,"\n%3d",temp);
LastTemp=temp;
}
}
return START;
}
/*uint8_t ProcesSolder(char *buffer,uint8_t key,uint16_t temp,Clockt_t *clock)
{
enum{SOLDER_START,SOLDER_PREHEAT,SOLDER_SOLDER,SOLDER_COOL};
static uint8_t stav=SOLDER_START;
static uint8_t timer=PREHEATTIME;
static uint8_t TimerFlag=0;
static uint8_t PrevSec;
if (key != NOKEY){
stav = SOLDER_START;
return START;
}
switch(stav)
{
case SOLDER_START:
timer = PREHEATTIME+1;
TimerFlag = 0;
stav = SOLDER_PREHEAT;
ClockInit(0,0,0,clock);
PrevSec = 0xff;
sprintf(buffer,"\f");
break;
case SOLDER_PREHEAT:
if(temp >= PREHEATTEMPSTART) TimerFlag=1;
ProcesHeat(PREHEATTEMP,temp);
if (!timer){
stav = SOLDER_SOLDER;
timer = SOLDERTIME+1;
TimerFlag = 0;
PrevSec = 0xff;
}
sprintf(buffer,"\rpreheat\n%3dC %3ds",temp,timer-1);
break;
case SOLDER_SOLDER:
if(temp >= SOLDERTEMP) TimerFlag=1;
ProcesHeat(SOLDERTEMP,temp);
if (!timer){
stav = SOLDER_COOL;
timer = COOLTIME+1;
TimerFlag = 0;
PrevSec = 0xff;
}
sprintf(buffer,"\rsolder \n%3dC %3ds",temp,timer-1);
break;
case SOLDER_COOL:
HeatOff();
TimerFlag=1;
if (!timer){
stav = SOLDER_START;
PrevSec = 0xff;
return START;
}
sprintf(buffer,"\rcool \n%3dC %3ds",temp,timer-1);
break;
default: HeatOff();
stav = SOLDER_START;
return START;
}
if ((PrevSec != clock->sec) && TimerFlag){
PrevSec = clock->sec;
timer --;
}
return SOLDER;
}*/
uint8_t ProcesSolder(char *buffer,uint8_t key,uint16_t temp,Clockt_t *clock)
{
enum{SOLDER_START,SOLDER_PREHEAT,SOLDER_SOLDER,SOLDER_COOL};
static uint8_t stav=SOLDER_START;
static uint8_t timer=PREHEATTIME;
static uint8_t Timer2=0;
static uint8_t TimerFlag2=0;
static uint8_t TimerFlag=0;
static uint8_t FlagSolder=0;
static uint8_t PrevSec;
static uint16_t LastTemp=0;
if (key != NOKEY){
stav = SOLDER_START;
return START;
}
switch(stav)
{
case SOLDER_START:
timer = 0;
TimerFlag = 0;
Timer2 = 0;
TimerFlag2 = 0;
stav = SOLDER_PREHEAT;
ClockInit(0,0,0,clock);
PrevSec = 0xff;
LastTemp = 0;
sprintf(buffer,"\f");
break;
case SOLDER_PREHEAT:
if(temp >= PREHEATTEMPSTART) TimerFlag=1;
if(temp >= PREHEATTEMP) TimerFlag2 = 1;
if(temp >= PREHEATTEMPSTOP){
stav = SOLDER_SOLDER;
TimerFlag = 0;
FlagSolder = 0;
TimerFlag2 = 0;
Timer2 = timer;
timer=0;
break;
}
if (TimerFlag2 && (Timer2 < PREHEATTIMEOFF)){
if (LastTemp > temp) HeatOn();
else {
HeatOff();
if ((clock->sec & 0x4) == 0x4) LastTemp = temp; //4sec vzorkovani;
}
//LastTemp=temp;
}
else HeatOn();
sprintf(buffer,"\rpreheat\n%3dC %3ds",temp,timer);
break;
case SOLDER_SOLDER:
if(temp >= SOLDERTEMPSTART) TimerFlag=1;
if(temp >= SOLDERTEMP) FlagSolder = 1;
if (FlagSolder){
HeatOff();
if(temp <= SOLDERTEMPSTART){
stav = SOLDER_COOL;
timer=0x1;
TimerFlag = 0;
break;
}
}
else HeatOn();
if (TimerFlag) Timer2=timer;
sprintf(buffer,"\rsolder \n%3dC %3ds",temp,Timer2);
break;
case SOLDER_COOL:
HeatOff();
TimerFlag=1;
if (!timer){
stav = SOLDER_START;
//PrevSec = 0xff;
return START;
}
sprintf(buffer,"\rcool \n%3dC",temp);
break;
default: HeatOff();
stav = SOLDER_START;
return START;
}
if ((PrevSec != clock->sec)){
PrevSec = clock->sec;
if (TimerFlag)timer ++;
if (TimerFlag2) Timer2 ++;
}
return SOLDER;
}
uint8_t ProcesPositiv(char *buffer,uint8_t key,uint16_t temp,Clockt_t *clock)
{
static uint8_t time = 0;
static uint8_t PrevSec;
if (!time){
time = POSITIVTIME+1;
ClockInit(0,0,0,clock);
PrevSec = 1;
}
ProcesHeat(POSITIVTEMP,temp);
if (key == TL1) time +=5;
if (key == TL2) {
time = 0;
return START;
}
if (PrevSec != clock->sec){
PrevSec = clock->sec;
if (PrevSec == 0) time --;
}
sprintf(buffer,"\n%3dC %3dm",temp,time);
if (!time) return START;
return POSITIV;
}
uint8_t ProcesDry(char *buffer,uint8_t key,uint16_t temp,Clockt_t *clock)
{
static uint8_t time;
static uint8_t PrevSec;
if (!time){
time = DRYTIME+1;
ClockInit(0,0,0,clock);
PrevSec = 1;
}
ProcesHeat(DRYTEMP,temp);
if (key == TL1) time +=5;
if (key == TL2) {
time = 0;
return START;
}
if (PrevSec != clock->sec){
PrevSec = clock->sec;
if (PrevSec == 0) time --;
}
sprintf(buffer,"\n%3dC %3dm",temp,time);
if (!time) return START;
return DRY;
}
/*
uint8_t ProcesTest(char *buffer,uint8_t key,uint16_t temp,Clockt_t *clock)
{
HeatOff();
sprintf(buffer,"\r%2d:%02d:%02d\n%3dC ",clock->hour,clock->min,clock->sec,temp);
if (key == TL2) return START;
return TEST;
}*/
void ProcesDispl(char *data)
{
uint8_t a,b;
for (a=0;a<MAXDISPLBUFFER;a++)
{
switch (*(data+a))
{
case 0: *data = 0;return;
case '\n': LCD_gotoxy(1,2);break;
case '\r': LCD_gotoxy(1,1);break;
case '\f': LCD_gotoxy(1,1);
for (b=0;b<8;b++) LCD_putc(0x20);
LCD_gotoxy(1,2);
for (b=0;b<8;b++) LCD_putc(0x20);
LCD_gotoxy(1,1);
break;
default : LCD_putc(*(data+a));
}
}
*data = 0;
}
void ProcesTemp(uint16_t adc,uint16_t *temp)
{
double Rpt;
double Tpt;
Rpt = 1.0*adc*2350.0/1024.0;
#define A 3.90802e-3
#define B -5.802e-7
Tpt = (-A + sqrt(A*A - 4*B*(1.0 - Rpt/1000.0)))/2.0/B;
//Tpt = (-A + sqrt(A*A - 4*B*(1.0 - Rpt)))/2.0/B;
//Tpt = (Rpt/1000.0 - 1.0)/A;
*temp = (int16_t)Tpt;
}
/*
void ProcesHeat(uint16_t temp,uint16_t ActualTemp)
{
enum{HEAT_STABLE,HEAT_UP_1,HEAT_UP_2,HEAT_UP_3,HEAT_UP_4,HEAT_UP_5,HEAT_DOWN_1,HEAT_DOWN_2,HEAT_DOWN_3,HEAT_DOWN_4,HEAT_DOWN_5};
static uint8_t stav = HEAT_STABLE;
static uint8_t PrevTemp = 0;
static uint8_t TimeChange=0;
if (ActualTemp < (temp)
switch(stav)
{
case HEAT_STABLE:
if (ActualTemp>temp) HeatOff();
else HeatOn();
break;
case HEAT_UP_1:
break;
case HEAT_UP_2:
break;
case HEAT_UP_3:
break;
case HEAT_UP_4:
break;
case HEAT_UP_5:
break;
case HEAT_DOWN_1:
break;
case HEAT_DOWN_2:
break;
case HEAT_DOWN_3:
break;
case HEAT_DOWN_4:
break;
case HEAT_DOWN_5:
break;
}
if (ActualTemp>temp) HeatOff();
else HeatOn();
}
*/
/*
void ProcesHeat(uint16_t GequestTemp,uint16_t ActualTemp)
{
#define TERM_STOP 15 //teplotni rozdil do regulace - trouba topi
#define T1 20 //vzorkovani pøi nabìhu teploty [s]
#define T2 10 //vzorkovani pøi poklesu teploty [s]
#define T3 5 //vzorkovani pøi ustalene teplotì [s]
#define T4 5 //doba topení [s]
#define MAINCYKLSPEED 100
static uint8_t delta_s=0;
static uint16_t T_LAST=0;
static uint8_t clock=MAINCYKLSPEED; //pocet opakovani teto fce za 1 sekundu
if (!(-- clock)) {delta_s++;clock = MAINCYKLSPEED;}
if( ActualTemp < (GequestTemp - TERM_STOP)){
HeatOn();
delta_s=0;
T_LAST=ActualTemp;
}
else{
if (ActualTemp < GequestTemp){
if (ActualTemp == T_LAST){
if (delta_s < T1) HeatOff();
else HeatOn();
if (delta_s > (T1 + T4)) delta_s = 0;
}
else{
if (T_LAST > ActualTemp) delta_s=(T1 - T2);
else delta_s=0;
T_LAST=ActualTemp;HeatOff();
}
}
else{
HeatOff();T_LAST=ActualTemp;
if (ActualTemp == GequestTemp) delta_s = (T1 - T3);
else delta_s = 0;
}
}
}
*/
/*
void ProcesHeat(uint16_t RequestTemp,uint16_t ActualTemp)
{
#define TERM_STOP 15 //teplotni rozdil do regulace - trouba topi
#define T1 20 //vzorkovani pøi nabìhu teploty [s]
#define T2 10 //vzorkovani pøi poklesu teploty [s]
#define T3 5 //vzorkovani pøi ustalene teplotì [s]
#define T4 5 //doba topení [s]
#define PERIOD 15 //[s]
#define MAINCYKLSPEED 100
static uint8_t delta_s=0;
static uint16_t LastTemp=0;
static uint8_t clock=MAINCYKLSPEED; //pocet opakovani teto fce za 1 sekundu
static uint8_t Pwm=0;
static uint8_t DutyPwm = 0;
static uint8_t FlagTemp = 1;
static uint8_t FlagPwm = 0;
if (!(-- clock)){
delta_s++;
clock = MAINCYKLSPEED;
if ((++Pwm) > PERIOD){
Pwm = 0;
FlagPwm = 1;
}
}
if( ActualTemp < (RequestTemp - TERM_STOP)){
DutyPwm = PERIOD;
LastTemp = ActualTemp;
FlagTemp=1;
}
else{
if (FlagTemp){
DutyPwm=0;
FlagTemp = 0;
}
else
if (FlagPwm)
{
FlagPwm=0;
if (ActualTemp >= RequestTemp){
if(LastTemp < ActualTemp ) { if (DutyPwm) DutyPwm --;}
}
else{
if (LastTemp >= ActualTemp) {if (DutyPwm<PERIOD)DutyPwm ++;}
}
LastTemp = ActualTemp;
}
}
if(ActualTemp<RequestTemp){
if (DutyPwm >= Pwm) HeatOn();
else HeatOff();
}
else HeatOff();
}*/
void ProcesHeat(uint16_t RequestTemp,uint16_t ActualTemp)
{
#define TERM_STOP 15 //teplotni rozdil do regulace - trouba topi
#define PERIOD 15 //[s]
#define MAINCYKLSPEED 100
static uint8_t delta_s=0;
static uint16_t LastTemp=0;
static uint8_t clock=MAINCYKLSPEED; //pocet opakovani teto fce za 1 sekundu
static uint8_t Pwm=0;
static uint8_t DutyPwm = 0;
static uint8_t FlagTemp = 1;
static uint8_t FlagPwm = 0;
if (!(-- clock)){
clock = MAINCYKLSPEED;
if ((++Pwm) > PERIOD){
Pwm = 0;
FlagPwm = 1;
}
}
if( ActualTemp < (RequestTemp - TERM_STOP)){
DutyPwm = PERIOD;
LastTemp = ActualTemp;
FlagTemp=1;
}
else{
if (FlagTemp){
DutyPwm=0;
FlagTemp = 0;
}
else
if (FlagPwm)
{
FlagPwm=0;
if (ActualTemp >= RequestTemp){
if (ActualTemp != RequestTemp)
if(LastTemp < ActualTemp ){
//if ((ActualTemp-LastTemp) > 1)
if (DutyPwm) DutyPwm --;
}
}
else{
if (LastTemp >= ActualTemp){
//if ((ActulaTemp - LastTemp)>1)
if (DutyPwm<PERIOD)DutyPwm ++;
}
if(LastTemp < ActualTemp ){
if ((ActualTemp-LastTemp) > 5)
if (DutyPwm) DutyPwm --;
}
}
LastTemp = ActualTemp;
}
}
if(ActualTemp < RequestTemp)
{
if (DutyPwm == PERIOD) HeatOn();
else{
if (DutyPwm > Pwm) HeatOn();
else HeatOff();
}
}
else HeatOff();
}