X-Git-Url: http://dolda2000.com/gitweb/?a=blobdiff_plain;f=kokare.c;h=35e5a0107026c18432e2dee8413f50300a6f8941;hb=c77327664d2a8fd272e91c2c99b8803ad123beb3;hp=18379e9fc53a88f343caf6437bfc1f6e18c36898;hpb=314156469153a9cbf5a74660c1d69808ad35a924;p=kokare.git

diff --git a/kokare.c b/kokare.c
index 18379e9..35e5a01 100644
--- a/kokare.c
+++ b/kokare.c
@@ -1,15 +1,16 @@
 #include <avr/io.h>
 #include <avr/interrupt.h>
 #include <inttypes.h>
+#include <math.h>
 
-#define SEGA 128
-#define SEGB 64
-#define SEGC 4
-#define SEGD 16
-#define SEGE 32
-#define SEGF 2
-#define SEGG 1
-#define SEGP 8
+#define SEGA 4
+#define SEGB 2
+#define SEGC 1
+#define SEGD 32
+#define SEGE 64
+#define SEGF 16
+#define SEGG 8
+#define SEGP 128
 
 uint8_t font[16] = {
     SEGA | SEGB | SEGC | SEGD | SEGE | SEGF,
@@ -30,30 +31,49 @@ uint8_t font[16] = {
     SEGA | SEGE | SEGF | SEGG,
 };
 /* LED */
+#define LCDELAY 1000
 uint8_t dsp[2] = {0, 0};
 char leda = 0;
 char ledc = 0;
 /* Timer */
-char of = 0;
-int oticks = 0;
+volatile char of = 0;
+volatile int oticks = 0;
+unsigned long mnow;
 /* Pulse counter */
-char pstate = 0;
+volatile char pstate = 0;
 char pval = 0;
 /* Switch */
-char sstate = 0;
+volatile char sstate = 0;
 int stime = 0;
 /* Temp sensor */
-char tstate = 0;
-char tlock = 0;
+volatile char tstate = 0;
+volatile char tlock = 0;
 unsigned long tstart;
 unsigned long ttime;
 unsigned long ttimea = 10000;
+char tavgok = 0;
+/* Conversion loop */
+int tempk;
+volatile ktok = 0;
 /* Zero-cross detector*/
+volatile char zok = 0;
+volatile char ztime = 0;
 /* Triac */
+char trstate = 0;
+char tron = 0;
+volatile char trtime;
+volatile char trdelay = 0;
 
 void init(void)
 {
-    /* Timer init */
+    /* Timer init
+     * Timer 0 cycles timing sensitive subsystems
+     * Timer 1 is used for global timing
+     */
+    OCR0A = 100;
+    TCCR0A = 2;
+    TCCR0B = 1;
+    TIMSK0 = 2;
     TCCR1A = 0;
     TCCR1B = 1;
     TIMSK1 = 1;
@@ -63,7 +83,7 @@ void init(void)
      * B3..5 = ISP
      * B6..7 = CLK
      */
-    DDRB = 0x00;
+    DDRB = 0x38;
     PORTB = 0x07;
     PCMSK0 = 0x07;
     PCICR = 0x01;
@@ -134,7 +154,7 @@ void ledcycle(void)
     static uint16_t last = 0;
     uint8_t c, d, v;
     
-    if(TCNT1 - last > 500) {
+    if(TCNT1 - last > LCDELAY) {
 	last = TCNT1;
 	if(++leda >= 8) {
 	    leda = 0;
@@ -153,27 +173,30 @@ void ledcycle(void)
 	} else {
 	    c = d = 0;
 	}
+	cli();
 	PORTC = c;
 	PORTD = (PORTD & 0x0f) | d;
+	sei();
     }
 }
 
 void tempcycle(void)
 {
-    unsigned long now;
-    
-    now = getticks();
     if(tstate == 0) {
 	if((PIND & 8) && (tlock == 0)) {
+	    cli();
 	    PORTD |= 2;
-	    tstart = now;
+	    sei();
+	    tstart = mnow;
 	    tstate = 1;
 	}
     } else if(tstate == 1) {
-	if(now - tstart > 1000) {
+	if(mnow - tstart > 1000) {
+	    cli();
 	    PORTD &= ~2;
+	    sei();
 	    tstate = 0;
-	    tstart = now;
+	    tstart = mnow;
 	}
     }
 }
@@ -184,22 +207,133 @@ void calcavg(void)
 	tlock = 2;
 	ttimea = ((ttimea * 15) + ttime) >> 4;
 	tlock = 0;
+	tavgok = 1;
+    }
+}
+
+void convcycle(void)
+{
+    static char state = 0;
+    static unsigned long last = 0;
+    static float a, ra, l, t;
+    
+    /*
+     * Theoretically:
+     *  t = RC * ln(2) => R = t / (C * ln(2))
+     *  R = A * exp(B / T) => T = B / ln(R / A)
+     *  T = B / ln(R / (A * C * ln(2)))
+     * In the following: 
+     *  a = ttimea as float
+     *  C = 1e6 / (A * C * ln(2))
+     *  ra = a * C
+     *  l = ln(ra)
+     *  t = B / l
+     * Note, temperature is in Kelvin
+     */
+#define C 9.792934
+#define B 4020.0
+    if(state == 0) {
+	if((mnow - last > 200000) && tavgok) {
+	    a = (float)ttimea;
+	    state = 1;
+	    tavgok = 0;
+	    last = mnow;
+	}
+    } else if(state == 1) {
+	ra = a * C;
+	state = 2;
+    } else if(state == 2) {
+	l = log(ra);
+	state = 3;
+    } else if(state == 3) {
+	t = B / l;
+	state = 4;
+    } else if(state == 4) {
+	tempk = (int)t;
+	ktok = 1;
+	state = 0;
     }
 }
 
 int main(void)
 {
-    int cur;
+    int state, cur;
+    unsigned long utime;
     
-    cur = 0;
+    state = 0;
+    cur = 99;
     init();
     sei();
     display(0);
+
     while(1) {
+	mnow = getticks();
 	ledcycle();
 	tempcycle();
 	calcavg();
+	convcycle();
 
+#if 1
+	/*
+	 * User interface
+	 */
+	if(state == 0) {
+	    /* Display temperature */
+	    if(ktok) {
+		ktok = 0;
+		if((tempk >= 273) && (tempk <= 372)) {
+		    display(tempk - 273);
+		} else {
+		    dsp[0] = dsp[1] = SEGG;
+		}
+	    }
+	    if(pval != 0) {
+		state = 1;
+		utime = mnow;
+	    }
+	    if(sstate == 2) {
+		sstate = 0;
+		if(stime > 10) {
+		    state = 2;
+		} else {
+		    tron = !tron;
+		}
+	    }
+	} else if(state == 1) {
+	    /* Triac control */
+	    if(pval != 0) {
+		cur += pval;
+		pval = 0;
+		if(cur < 0)
+		    cur = 0;
+		if(cur > 99)
+		    cur = 99;
+		display(cur);
+		trdelay = 99 - cur;
+		utime = mnow;
+	    }
+	    if(mnow - utime > 1000000) {
+		state = 0;
+	    }
+	    if(sstate == 2) {
+		tron = !tron;
+		sstate = 0;
+	    }
+	} else if(state == 2) {
+	    if(ttimea < 20000) {
+		display((ttimea / 100) % 100);
+		dsp[0] |= SEGP;
+		if(ttimea >= 10000)
+		    dsp[1] |= SEGP;
+	    } else {
+		display(ttimea / 1000);
+	    }
+	    if(sstate == 2) {
+		state = 0;
+		sstate = 0;
+	    }
+	}
+#endif
 	/*
 	  dsp[0] = bindisp((ttimea & 0xff00) >> 8);
 	  dsp[1] = bindisp(ttimea & 0x00ff);
@@ -207,6 +341,10 @@ int main(void)
 	/*
 	  disphex((ttimea & 0xff000) >> 12);
 	*/
+#if 0
+	/*
+	  Temp display
+	*/
 	if(ttimea < 20000) {
 	    display((ttimea / 100) % 100);
 	    dsp[0] |= SEGP;
@@ -215,8 +353,45 @@ int main(void)
 	} else {
 	    display(ttimea / 1000);
 	}
-
+#endif
+#if 0
+	/*
+	 * ZVD debug
+	 */
+	if(zok) {
+	    if(++cur > 99)
+		cur = 0;
+	    display(cur);
+	    zok = 0;
+	}
+#endif
+#if 0
+	/*
+	  Phony Triac control
+	 */
+	if(pval != 0) {
+	    cur += pval;
+	    if(cur < 0)
+		cur = 0;
+	    if(cur > 99)
+		cur = 99;
+	    display(cur);
+	    trdelay = 99 - cur;
+	    pval = 0;
+	}
+	if(sstate == 2) {
+	    tron = !tron;
+	    sstate = 0;
+	}
+	if(tron)
+	    dsp[1] |= SEGP;
+	else
+	    dsp[1] &= ~SEGP;
+#endif
+#if 0
 	/*
+	  Pulse counter display
+	*/
 	cur += pval;
 	pval = 0;
 	if(sstate == 2) {
@@ -233,12 +408,16 @@ int main(void)
 	} else {
 	    display(cur);
 	}
-	*/
+	if(PINB & 4)
+	    dsp[1] |= SEGP;
+#endif
     }
 }
 
 ISR(SIG_INTERRUPT0)
 {
+    ztime = 0;
+    zok = 1;
 }
 
 ISR(SIG_INTERRUPT1)
@@ -256,6 +435,24 @@ ISR(SIG_INTERRUPT1)
     }
 }
 
+ISR(SIG_OUTPUT_COMPARE0A)
+{
+    if(trstate == 0) {
+	ztime++;
+	if(tron && (ztime >= trdelay)) {
+	    PORTD |= 1;
+	    trstate = 1;
+	    trtime = 0;
+	}
+    } else if(trstate == 1) {
+	trtime++;
+	if(trtime >= 5) {
+	    PORTD &= ~1;
+	    trstate = 0;
+	}
+    }
+}
+
 ISR(SIG_OVERFLOW1)
 {
     of = 1;
@@ -264,22 +461,22 @@ ISR(SIG_OVERFLOW1)
 
 ISR(SIG_PIN_CHANGE0)
 {
-    if((sstate == 0) & ((PINB & 1) == 0)) {
+    if((sstate == 0) && !(PINB & 4)) {
 	stime = oticks;
 	sstate = 1;
     }
-    if((sstate == 1) & ((PINB & 1) == 1)) {
+    if((sstate == 1) && (PINB & 4)) {
 	stime = oticks - stime;
 	sstate = 2;
     }
     if(pstate == 0) {
 	if((PINB & 2) == 0) {
 	    pstate = 1;
-	} else if((PINB & 4) == 0) {
+	} else if((PINB & 1) == 0) {
 	    pstate = 2;
 	}
     } else if(pstate == 1) {
-	if((PINB & 4) == 0) {
+	if((PINB & 1) == 0) {
 	    pval++;
 	    pstate = 3;
 	} else {
@@ -293,7 +490,7 @@ ISR(SIG_PIN_CHANGE0)
 	    pstate = 0;
 	}
     } else {
-	if((PINB & 2) && (PINB & 4))
+	if((PINB & 2) && (PINB & 1))
 	    pstate = 0;
     }
 }