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/**** IR Mrakomer 4 ****/ |
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/**** IR Mrakomer 4 ****/ |
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#define VERSION "4.0" |
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#define VERSION "4.0" |
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#define ID "$Id: irmrak4.c 1282 2009-01-07 13:07:23Z kakl $" |
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#define ID "$Id: irmrak4.c 1283 2009-01-07 14:07:16Z kakl $" |
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#include "irmrak4.h" |
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#include "irmrak4.h" |
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#define MAXHEAT 20 // Number of cycles for heating |
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#define MAXHEAT 20 // Number of cycles for heating |
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#define MAXOPEN 20 // Number of cycles for dome open |
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#define MAXOPEN 20 // Number of cycles for dome open |
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#define MEASURE_DELAY 10000 // Delay to a next measurement |
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#define MEASURE_DELAY 10000 // Delay to a next measurement |
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#define RESPONSE_DELAY 100 // Reaction time after receiving a command |
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#define RESPONSE_DELAY 100 // Reaction time after receiving a command |
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#define SAFETY_COUNT 100 // Time of one emergency cycle |
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#define SAFETY_COUNT 100 // Time of one emergency cycle |
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#define SEND_DELAY 50 // Time between two characters on RS232 |
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#define SEND_DELAY 50 // Time between two characters on RS232 |
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|
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|
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#define DOME PIN_B4 // Dome controll port |
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#define DOME PIN_B4 // Dome controll port |
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#define HEATING PIN_B3 // Heating for defrosting |
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#define HEATING PIN_B3 // Heating for defrosting |
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|
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|
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#bit CREN = 0x18.4 // USART registers |
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#bit CREN = 0x18.4 // USART registers |
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#bit SPEN = 0x18.7 |
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#bit SPEN = 0x18.7 |
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#bit OERR = 0x18.1 |
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#bit OERR = 0x18.1 |
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#bit FERR = 0x18.2 |
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#bit FERR = 0x18.2 |
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|
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|
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char VER[4]=VERSION; // Buffer for concatenate of a version string |
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char VER[4]=VERSION; // Buffer for concatenate of a version string |
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char REV[50]=ID; |
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char REV[50]=ID; |
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|
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|
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int8 heat; // Status variables |
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int8 heat; // Status variables |
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int8 open; |
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int8 open; |
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|
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|
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inline void toggle_dome(void) |
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inline void toggle_dome(void) |
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{ |
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{ |
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if (open>0) |
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if (open>0) |
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{output_toggle(DOME);} |
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{output_toggle(DOME);} |
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else |
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else |
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{output_low(DOME);} |
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{output_low(DOME);} |
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} |
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} |
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|
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|
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void delay(int16 cycles) |
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void delay(int16 cycles) |
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{ |
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{ |
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int16 i; |
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int16 i; |
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|
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|
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for(i=0; i<cycles; i++) {toggle_dome(); delay_us(100);} |
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for(i=0; i<cycles; i++) {toggle_dome(); delay_us(100);} |
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} |
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} |
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#include "smb.c" |
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#include "smb.c" |
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|
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// Read sensor RAM |
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// Read sensor RAM |
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// Returns temperature in °K |
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// Returns temperature in °K |
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int16 ReadTemp(int8 addr, int8 select) |
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int16 ReadTemp(int8 addr, int8 select) |
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{ |
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{ |
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unsigned char arr[6]; // Buffer for the sent bytes |
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unsigned char arr[6]; // Buffer for the sent bytes |
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int8 crc; // Readed CRC |
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int8 crc; // Readed CRC |
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int16 temp; // Readed temperature |
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int16 temp; // Readed temperature |
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|
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|
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addr<<=1; |
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addr<<=1; |
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|
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|
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SMB_STOP_bit(); //If slave send NACK stop comunication |
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SMB_STOP_bit(); //If slave send NACK stop comunication |
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SMB_START_bit(); //Start condition |
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SMB_START_bit(); //Start condition |
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SMB_TX_byte(addr); |
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SMB_TX_byte(addr); |
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SMB_TX_byte(RAM_Access|select); |
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SMB_TX_byte(RAM_Access|select); |
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SMB_START_bit(); //Repeated Start condition |
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SMB_START_bit(); //Repeated Start condition |
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SMB_TX_byte(addr); |
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SMB_TX_byte(addr); |
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arr[2]=SMB_RX_byte(ACK); //Read low data,master must send ACK |
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arr[2]=SMB_RX_byte(ACK); //Read low data,master must send ACK |
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arr[1]=SMB_RX_byte(ACK); //Read high data,master must send ACK |
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arr[1]=SMB_RX_byte(ACK); //Read high data,master must send ACK |
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temp=MAKE16(arr[1],arr[2]); |
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temp=MAKE16(arr[1],arr[2]); |
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crc=SMB_RX_byte(NACK); //Read PEC byte, master must send NACK |
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crc=SMB_RX_byte(NACK); //Read PEC byte, master must send NACK |
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SMB_STOP_bit(); //Stop condition |
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SMB_STOP_bit(); //Stop condition |
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|
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|
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arr[5]=addr; |
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arr[5]=addr; |
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arr[4]=RAM_Access|select; |
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arr[4]=RAM_Access|select; |
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arr[3]=addr; |
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arr[3]=addr; |
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arr[0]=0; |
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arr[0]=0; |
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if (crc != PEC_calculation(arr)) temp=0; // Calculate and check CRC |
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if (crc != PEC_calculation(arr)) temp=0; // Calculate and check CRC |
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|
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|
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return temp; |
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return temp; |
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} |
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} |
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|
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void main() |
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void main() |
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{ |
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{ |
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unsigned int16 seq, temp, tempa; |
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unsigned int16 seq, temp, tempa; |
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signed int16 ta, to; |
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signed int16 ta, to; |
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int8 safety_counter; |
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int8 safety_counter; |
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|
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|
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output_low(HEATING); // Heating off |
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output_low(HEATING); // Heating off |
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setup_wdt(WDT_2304MS); // Setup Watch Dog |
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setup_wdt(WDT_2304MS); // Setup Watch Dog |
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setup_adc_ports(NO_ANALOGS); |
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setup_adc_ports(NO_ANALOGS); |
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setup_adc(ADC_OFF); |
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setup_adc(ADC_OFF); |
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setup_timer_0(RTCC_INTERNAL|RTCC_DIV_1); |
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setup_timer_0(RTCC_INTERNAL|RTCC_DIV_1); |
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setup_timer_1(T1_DISABLED); |
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setup_timer_1(T1_DISABLED); |
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setup_timer_2(T2_DISABLED,0,1); |
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setup_timer_2(T2_DISABLED,0,1); |
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setup_comparator(NC_NC_NC_NC); |
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setup_comparator(NC_NC_NC_NC); |
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setup_vref(FALSE); |
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setup_vref(FALSE); |
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// setup_oscillator(OSC_4MHZ|OSC_INTRC,+2); // Pokud je nutna kalibrace RCosc |
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// setup_oscillator(OSC_4MHZ|OSC_INTRC,+2); // Pokud je nutna kalibrace RCosc |
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setup_oscillator(OSC_4MHZ|OSC_INTRC); |
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setup_oscillator(OSC_8MHZ|OSC_INTRC); |
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|
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|
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delay_ms(1000); |
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delay_ms(1000); |
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restart_wdt(); |
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restart_wdt(); |
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printf("\n\r* Mrakomer %s (C) 2007 KAKL *\n\r",VER); // Welcome message |
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printf("\n\r* Mrakomer %s (C) 2007 KAKL *\n\r",VER); // Welcome message |
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printf("* %s *\n\r",REV); |
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printf("* %s *\n\r",REV); |
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printf("<#sequence> <ambient [1/100 C]> <sky [1/100 C]> "); |
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printf("<#sequence> <ambient [1/100 C]> <sky [1/100 C]> "); |
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printf("<heating [s]> <dome [s]>\n\r\n\r"); |
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printf("<heating [s]> <dome [s]>\n\r\n\r"); |
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tempa=ReadTemp(SA, RAM_Tamb); // Dummy read |
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tempa=ReadTemp(SA, RAM_Tamb); // Dummy read |
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temp=ReadTemp(SA, RAM_Tobj1); |
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temp=ReadTemp(SA, RAM_Tobj1); |
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|
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|
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seq=0; |
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seq=0; |
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heat=0; |
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heat=0; |
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open=0; |
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open=0; |
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|
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|
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// enable_interrupts(GLOBAL); |
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// enable_interrupts(GLOBAL); |
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// enable_interrupts(INT_RDA); |
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// enable_interrupts(INT_RDA); |
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|
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//---WDT |
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//---WDT |
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restart_wdt(); |
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restart_wdt(); |
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|
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while(TRUE) |
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while(TRUE) |
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{ |
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{ |
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while(kbhit()) getc(); // Flush USART buffer |
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while(kbhit()) getc(); // Flush USART buffer |
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CREN=0; CREN=1; // Reinitialise USART |
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CREN=0; CREN=1; // Reinitialise USART |
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|
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safety_counter=0; |
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safety_counter=0; |
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|
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do |
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do |
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{ |
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{ |
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if (safety_counter<SAFETY_COUNT) safety_counter++; |
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if (safety_counter<SAFETY_COUNT) safety_counter++; |
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delay(RESPONSE_DELAY); |
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delay(RESPONSE_DELAY); |
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if (safety_counter>=SAFETY_COUNT) |
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if (safety_counter>=SAFETY_COUNT) |
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{ |
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{ |
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if (heat>0) |
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if (heat>0) |
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{ |
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{ |
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output_high(HEATING); |
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output_high(HEATING); |
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heat--; |
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heat--; |
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} |
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} |
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else |
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else |
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{ |
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{ |
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output_low(HEATING); |
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output_low(HEATING); |
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} |
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} |
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if (open>0) open--; |
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if (open>0) open--; |
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safety_counter=0; |
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safety_counter=0; |
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//---WDT |
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//---WDT |
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restart_wdt(); |
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restart_wdt(); |
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} |
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} |
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} while (!kbhit()); |
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} while (!kbhit()); |
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|
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|
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//---WDT |
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//---WDT |
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restart_wdt(); |
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restart_wdt(); |
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{ |
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{ |
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char ch; |
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char ch; |
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|
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ch=getc(); |
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ch=getc(); |
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|
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switch (ch) |
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switch (ch) |
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{ |
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{ |
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case 'h': |
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case 'h': |
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heat=MAXHEAT; // Need heating |
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heat=MAXHEAT; // Need heating |
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break; |
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break; |
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|
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|
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case 'c': |
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case 'c': |
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heat=0; // Need colder |
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heat=0; // Need colder |
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break; |
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break; |
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|
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|
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case 'o': |
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case 'o': |
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open=MAXOPEN; // Open the dome |
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open=MAXOPEN; // Open the dome |
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break; |
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break; |
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|
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|
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case 'l': |
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case 'l': |
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open=0; // Lock the dome |
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open=0; // Lock the dome |
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break; |
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break; |
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} |
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} |
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} |
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} |
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|
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|
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seq++; // Increment the number of measurement |
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seq++; // Increment the number of measurement |
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|
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|
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tempa=ReadTemp(SA, RAM_Tamb); // Read temperatures from sensor |
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tempa=ReadTemp(SA, RAM_Tamb); // Read temperatures from sensor |
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temp=ReadTemp(SA, RAM_Tobj1); |
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temp=ReadTemp(SA, RAM_Tobj1); |
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|
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ta=tempa*2-27315; // °K -> °C |
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ta=tempa*2-27315; // °K -> °C |
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to=temp*2-27315; |
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to=temp*2-27315; |
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|
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{ // printf |
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{ // printf |
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char output[10]; // Output buffer |
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char output[10]; // Output buffer |
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int8 j; // Counter |
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int8 j; // Counter |
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|
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|
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delay(SEND_DELAY); |
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delay(SEND_DELAY); |
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sprintf(output,"#%Lu ", seq); |
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sprintf(output,"#%Lu ", seq); |
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j=0; while(output[j]!=0) { delay(SEND_DELAY); putc(output[j++]); } |
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j=0; while(output[j]!=0) { delay(SEND_DELAY); putc(output[j++]); } |
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sprintf(output,"%Ld ", ta); |
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sprintf(output,"%Ld ", ta); |
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j=0; while(output[j]!=0) { delay(SEND_DELAY); putc(output[j++]); } |
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j=0; while(output[j]!=0) { delay(SEND_DELAY); putc(output[j++]); } |
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sprintf(output,"%Ld ", to); |
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sprintf(output,"%Ld ", to); |
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j=0; while(output[j]!=0) { delay(SEND_DELAY); putc(output[j++]); } |
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j=0; while(output[j]!=0) { delay(SEND_DELAY); putc(output[j++]); } |
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sprintf(output,"%u", heat); |
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sprintf(output,"%u ", heat); |
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j=0; while(output[j]!=0) { delay(SEND_DELAY); putc(output[j++]); } |
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j=0; while(output[j]!=0) { delay(SEND_DELAY); putc(output[j++]); } |
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sprintf(output,"%u\n\r\0", open); |
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sprintf(output,"%u\n\r\0", open); |
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j=0; while(output[j]!=0) { delay(SEND_DELAY); putc(output[j++]); } |
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j=0; while(output[j]!=0) { delay(SEND_DELAY); putc(output[j++]); } |
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} |
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} |
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|
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|
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delay(MEASURE_DELAY); // Delay to a next measurement |
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delay(MEASURE_DELAY); // Delay to a next measurement |
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//---WDT |
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//---WDT |
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restart_wdt(); |
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restart_wdt(); |
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} |
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} |
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} |
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} |
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