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Delete ATU_100_EXT_board/FirmWare_PIC16F1938/1938_EXT_board_sources_V_3.2/main.h

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David Fainitski 2024-01-08 12:15:30 -08:00 zatwierdzone przez GitHub
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// Main.h
// David Fainitski
// ATU-100 project 2016
//
static char ind = 0, cap = 0, SW = 0, step_cap = 0, step_ind = 0, L_linear = 0, C_linear = 0, L_q = 7, C_q = 7, D_correction = 1, L_invert = 0, L_mult = 1,
C_mult = 1, P_High = 0, K_Mult = 32, Overload = 0, Loss_ind = 0, Relay_off = 0;
static int Rel_Del, min_for_start, max_for_start, max_swr;
int SWR, PWR, P_max, swr_a;
char rready = 0, p_cnt = 0;
//
void btn_push(void);
void lcd_prep(void);
void lcd_swr(int);
void lcd_pwr(void);
void show_pwr(int, int);
void lcd_ind(void);
void crypto(void);
void show_reset(void);
void cells_init(void);
void test_init(void);
void button_proc(void);
void button_proc_test(void);
void button_delay(void);
void show_loss(void);
//
void atu_reset(void);
int get_reverse(void);
int get_forward(void);
int correction(int);
void get_swr(void);
void get_pwr(void);
void set_sw(char);
void coarse_cap();
void sharp_cap();
void sharp_ind();
void coarse_tune();
void tune(void);
void sub_tune(void);
//
int correction(int input) {
//
if(input <= 80) return 0;
if(input <= 171) input += 244;
else if(input <= 328) input += 254;
else if(input <= 582) input += 280;
else if(input <= 820) input += 297;
else if(input <= 1100) input += 310;
else if(input <= 2181) input += 430;
else if(input <= 3322) input += 484;
else if(input <= 4623) input += 530;
else if(input <= 5862) input += 648;
else if(input <= 7146) input += 743;
else if(input <= 8502) input += 800;
else if(input <= 10500) input += 840;
else input += 860;
//
return input;
}
//
int get_reverse() {
int Reverse;
FVRCON = 0b10000001; // ADC 1024 vmV Vref
while(FVRCON.B6 == 0);
Reverse = ADC_Get_Sample(0);
if(Reverse <= 1000) return Reverse;
FVRCON = 0b10000010; // ADC 2048 vmV Vref
while(FVRCON.B6 == 0);
Reverse = ADC_Get_Sample(0);
if(Reverse <= 1000) return Reverse * 2;
FVRCON = 0b10000011; // ADC 4096 vmV Vref
while(FVRCON.B6 == 0);
Reverse = ADC_Get_Sample(0);
return Reverse * 4;
}
//
int get_forward() {
int Forward;
FVRCON = 0b10000001; // ADC 1024 vmV Vref
while(FVRCON.B6 == 0);
Forward = ADC_Get_Sample(1);
if(Forward <= 1000){
Overload = 0;
return Forward;
}
FVRCON = 0b10000010; // ADC 2048 vmV Vref
while(FVRCON.B6 == 0);
Forward = ADC_Get_Sample(1);
if(Forward <= 1000){
Overload = 0;
return Forward * 2;
}
FVRCON = 0b10000011; // ADC 4096 vmV Vref
while(FVRCON.B6 == 0);
Forward = ADC_Get_Sample(1);
if(Forward > 1000) Overload = 1;
else Overload = 0;
return Forward * 4;
}
void get_pwr() {
long Forward, Reverse;
float p;
asm CLRWDT;
//
Forward = get_forward();
Reverse = get_reverse();
if(D_correction==1) p = correction(Forward * 3);
else p = Forward * 3;
//
if(Reverse >= Forward)
Forward = 999;
else {
Forward = ((Forward + Reverse) * 100) / (Forward - Reverse);
if(Forward>999) Forward = 999;
}
//
p = p * K_Mult / 1000.0; // mV to Volts on Input
p = p / 1.414;
if(P_High==1) p = p * p / 50; // 0 - 1500 ( 1500 Watts)
else p = p * p / 5; // 0 - 1510 (151.0 Watts)
p = p + 0.5; // rounding
//
PWR = p;
if(Forward<100) SWR = 999;
else SWR = Forward;
return;
}
void get_swr() {
get_pwr();
if(p_cnt!=100) {
p_cnt += 1;
if(PWR>P_max) P_max = PWR;
}
else {
p_cnt = 0;
show_pwr(P_max, SWR);
P_max = 0;
}
while(PWR<min_for_start | (PWR> max_for_start & max_for_start>0)) { // waiting for good power
asm CLRWDT;
get_pwr();
if(p_cnt!=100) {
p_cnt += 1;
if(PWR>P_max) P_max = PWR;
}
else {
p_cnt = 0;
show_pwr(P_max, SWR);
P_max = 0;
}
//
if(Button(&PORTB, 0, 5, 1)) rready = 1;
if(rready==1 & Button(&PORTB, 0, 5, 0)) { // press button Tune
show_reset();
SWR = 0;
return;
}
} // good power
return;
}
void set_ind(char Ind) {
if(L_invert == 0) {
Ind_005 = Ind.B0;
Ind_011 = Ind.B1;
Ind_022 = Ind.B2;
Ind_045 = Ind.B3;
Ind_1 = Ind.B4;
Ind_22 = Ind.B5;
Ind_45 = Ind.B6;
//
}
else {
Ind_005 = ~Ind.B0;
Ind_011 = ~Ind.B1;
Ind_022 = ~Ind.B2;
Ind_045 = ~Ind.B3;
Ind_1 = ~Ind.B4;
Ind_22 = ~Ind.B5;
Ind_45 = ~Ind.B6;
//
}
Vdelay_ms(Rel_Del);
}
void set_cap(char Cap) {
Cap_10 = Cap.B0;
Cap_22 = Cap.B1;
Cap_47 = Cap.B2;
Cap_100 = Cap.B3;
Cap_220 = Cap.B4;
Cap_470 = Cap.B5;
Cap_1000 = Cap.B6;
//
Vdelay_ms(Rel_Del);
}
void set_sw(char SW) { // 0 - IN, 1 - OUT
Cap_sw = SW;
Vdelay_ms(Rel_Del);
}
void atu_reset() {
ind = 0;
cap = 0;
set_ind(ind);
set_cap(cap);
Vdelay_ms(Rel_Del);
}
void coarse_cap() {
char step = 3;
char count;
int min_swr;
cap = 0;
set_cap(cap);
step_cap = step;
get_swr(); if(SWR==0) return;
min_swr = SWR + SWR/20;
for(count=step; count<=31;) {
set_cap(count*C_mult);
get_swr(); if(SWR==0) return;
if(SWR < min_swr) {
min_swr = SWR + SWR/20;
cap = count*C_mult;
step_cap = step;
if(SWR<120) break;
count +=step;
if(C_linear==0 & count==9) count = 8;
else if(C_linear==0 & count==17) {count = 16; step = 4;}
}
else break;
}
set_cap(cap);
return;
}
void coarse_tune() {
char step = 3;
char count;
char mem_cap, mem_step_cap;
int min_swr;
mem_cap = 0;
step_ind = step;
mem_step_cap = 3;
min_swr = SWR + SWR/20;
for(count=0; count<=31;) {
set_ind(count*L_mult);
coarse_cap();
get_swr(); if(SWR==0) return;
if(SWR < min_swr) {
min_swr = SWR + SWR/20;
ind = count*L_mult;
mem_cap = cap;
step_ind = step;
mem_step_cap = step_cap;
if(SWR<120) break;
count +=step;
if(L_linear==0 & count==9) count = 8;
else if(L_linear==0 & count==17) {count = 16; step = 4;}
}
else break;
}
cap = mem_cap;
set_ind(ind);
set_cap(cap);
step_cap = mem_step_cap;
Delay_ms(10);
return;
}
void sharp_cap() {
char range, count, max_range, min_range;
int min_swr;
range = step_cap*C_mult;
//
max_range = cap + range;
if(max_range>32*C_mult-1) max_range = 32*C_mult-1;
if(cap>range) min_range = cap - range; else min_range = 0;
cap = min_range;
set_cap(cap);
get_swr(); if(SWR==0) return;
min_SWR = SWR;
for(count=min_range+C_mult; count<=max_range; count+=C_mult) {
set_cap(count);
get_swr(); if(SWR==0) return;
if(SWR>=min_SWR) { Delay_ms(10); get_swr(); }
if(SWR>=min_SWR) { Delay_ms(10); get_swr(); }
if(SWR < min_SWR) {
min_SWR = SWR;
cap = count;
if(SWR<120) break;
}
else break;
}
set_cap(cap);
return;
}
void sharp_ind() {
char range, count, max_range, min_range;
int min_SWR;
range = step_ind * L_mult;
//
max_range = ind + range;
if(max_range>32*L_mult-1) max_range = 32*L_mult-1;
if(ind>range) min_range = ind - range; else min_range = 0;
ind = min_range;
set_ind(ind);
get_swr(); if(SWR==0) return;
min_SWR = SWR;
for(count=min_range+L_mult; count<=max_range; count+=L_mult) {
set_ind(count);
get_swr(); if(SWR==0) return;
if(SWR>=min_SWR) { Delay_ms(10); get_swr(); }
if(SWR>=min_SWR) { Delay_ms(10); get_swr(); }
if(SWR < min_SWR) {
min_SWR = SWR;
ind = count;
if(SWR<120) break;
}
else break;
}
set_ind(ind);
return;
}
void sub_tune () {
int swr_mem, ind_mem, cap_mem;
//
swr_mem = SWR;
coarse_tune(); if(SWR==0) {atu_reset(); return;}
get_swr(); if(SWR<120) return;
sharp_ind(); if(SWR==0) {atu_reset(); return;}
get_swr(); if(SWR<120) return;
sharp_cap(); if(SWR==0) {atu_reset(); return;}
get_swr(); if(SWR<120) return;
//
if(SWR<200 & SWR<swr_mem & (swr_mem-SWR)>100) return;
swr_mem = SWR;
ind_mem = ind;
cap_mem = cap;
//
if(SW==1) SW = 0; else SW = 1;
atu_reset();
set_sw(SW);
Delay_ms(50);
get_swr(); if(SWR<120) return;
//
coarse_tune(); if(SWR==0) {atu_reset(); return;}
get_swr(); if(SWR<120) return;
sharp_ind(); if(SWR==0) {atu_reset(); return;}
get_swr(); if(SWR<120) return;
sharp_cap(); if(SWR==0) {atu_reset(); return;}
get_swr(); if(SWR<120) return;
//
if(SWR>swr_mem) {
if(SW==1) SW = 0; else SW = 1;
set_sw(SW);
ind = ind_mem;
cap = cap_mem;
set_ind(ind);
set_cap(cap);
SWR = swr_mem;
}
//
asm CLRWDT;
return;
}
void tune() {
//int swr_mem, ind_mem, cap_mem, sw_mem;
asm CLRWDT;
//
p_cnt = 0;
P_max = 0;
//
rready = 0;
get_swr();
if(SWR<110) return;
atu_reset();
if(Loss_ind==0) lcd_ind();
Delay_ms(50);
get_swr();
swr_a = SWR;
if(SWR<110) return;
if(max_swr>110 & SWR>max_swr) return;
//
sub_tune(); if(SWR==0) {atu_reset(); return;}
if(SWR<120) return;
if(C_q==5 & L_q==5) return;
if(L_q>5) {
step_ind = L_mult;
L_mult = 1;
sharp_ind();
}
if(SWR<120) return;
if(C_q>5) {
step_cap = C_mult; // = C_mult
C_mult = 1;
sharp_cap();
}
if(L_q==5)L_mult = 1;
else if(L_q==6) L_mult = 2;
else if(L_q==7) L_mult = 4;
if(C_q==5) C_mult =1;
else if(C_q==6) C_mult = 2;
else if(C_q==7) C_mult = 4;
asm CLRWDT;
return;
}