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// Change the following to change the clock frequency
#define CRYSTAL_FREQ 16000000
// Change the following to change between 16 or 20 column display
#define DISPLAY_COLS 20
// Speed units are "1" (nautical knots), "2" (metric kph), or "3" (statute mph)
#define SPEED_UNITS 1
/****************************************************************************
GPS18.c
This program receives NMEA-0183 data from a GPS and displays it.
Meant for large display version still in 16F876.
Three buttons
Automicaly resets if main loop stops (not the best solution, still don't know why it's stopping)
Next: don't display GPS screens unless GPS is active
detect display needing reset
preset data eeprom for first-time operation
don't display init stuff if reseting from main loop
+5 +5+5
| | |
20 15 2
---------- ----------
~SerIn -----18-| |-24-----11-|DB4 A Vdd |
| |-25-----12-|DB5 |
ADC0 ------2-| |-26-----13-|DB6 |
ADC1 ------3-| 16F876 |-27-----14-|DB7 Vo| 3--
ADC2 ------5-| | | LCD | |
| |-14------6-|EN | |
XTAL--9-| |-15------4-|R/S | |
XTAL-10-| |-28-FET-16-|K | |
| | | RW Vss | |
BUTTON 1---21-| | ---------- |
BUTTON 2---22-| | 1 5 |
BUTTON 3---23-| | | | |
| | Gnd Gnd |
| | |
| |-11----------R/C-----------
| |
| |
----------
8 19
| |
Gnd Gnd
***************************************************************************/
#case
#include <16F876.h>
#include <jonsinc.h>
#device = *=16 ADC=10 /* allow RAM addresses over 255 */
#if ( ( CRYSTAL_FREQ < 4000000) || ( CRYSTAL_FREQ > 20000000 ) )
#error "CRYSTAL FREQ" not defined to between 8000000 and 20000000
#endif
#if ( ( DISPLAY_COLS != 16 ) && ( DISPLAY_COLS != 20 ) )
#error "DISPLAY COLS" not defined to 16 or 20
#endif
// RMC_TIME = 1 per clock megahertz, rounded
#define RMC_TIME CRYSTAL_FREQ/1000000
#define LCD_D0 PIN_B3
#define LCD_D1 PIN_B4
#define LCD_D2 PIN_B5
#define LCD_D3 PIN_B6
#define LCD_EN PIN_C3
#define LCD_RS PIN_C4
#define RX_IN PIN_C7
#define BUTTON_1 PIN_B0
#define BUTTON_2 PIN_B1
#define BUTTON_3 PIN_B2
#define LCD_BACKLITE PIN_B7
#define LINE_1 0x00
#define LINE_2 0x40
#if DISPLAY_COLS == 20
#define LINE_3 0x14
#define LINE_4 0x54
#endif
#if DISPLAY_COLS == 16
#define LINE_3 0x10
#define LINE_4 0x50
#endif
#define CLEAR_DISP 0x01
#define EOF 0x00
#define COMMA ','
#define CR 13
#define SPACE ' '
#define PERIOD '.'
#define DEGREE 0xdf
#define DOLLAR '$'
#define NULL 0
#define GPRMC_CODE 75
#define GPRMB_CODE 74
#define RX_BUFFER_SIZE 70
#define POSITION_SCREEN 1
#define WAYPOINT_SCREEN 2
#define BATTERY_SCREEN 3
#define HIDDEN_RMC 5
#define WARNING_MSG 0
#define NODATA_MSG 1
#define ACTIVITY_SYMBOL 0xFF
#define MAX_VOLTS 15
#define EEPROM_CONTRAST 0
#define EEPROM_INITIAL 1
/* Set the following define to "YES" to display XOR'ed GPS sentence code */
/* such as GPRMC and the display will read out the value of 74. */
#define GET_GPS_CODE NO
#separate void Display ( void );
#separate void LCD_Init ( void );
#separate void LCD_SetPosition ( unsigned int cX );
#separate void LCD_PutChar ( unsigned int cX );
#separate void LCD_PutCmd ( unsigned int cX );
#separate void LCD_PulseEnable ( void );
#separate void LCD_SetData ( unsigned int cX );
#separate void SkipField ( char cCnt );
#separate char GetField ( void );
#separate void InitRxBuffer ( char cCode );
#separate char GetRxChar ( void );
#separate void DisplayLatLon ( void );
#separate void DisplayWaypoint ( void );
#separate void DisplayLatitude ( char cLine );
#separate void DisplayLongitude ( char cLine );
#separate void DisplayHeading ( char cLine );
#separate void DisplaySpeed ( char cLine );
#separate void DisplaySteer ( char cLine, char cX );
#separate void DisplayWaypointName ( char cLine, char cX );
#separate void DisplayDistance ( char cLine, char cX );
#separate void DisplayBearing ( char cLine, char cX );
#separate void GetUtcAndMagVar ( void );
#separate long TrueToMag ( long iH );
#separate long FieldFiveToLong ( void );
#separate void DisplayAnalog ( void );
#separate void DisplayScaledVoltage ( long iV, char cScale );
#separate void DisplayArrival ( char cLine );
#separate void DisplayMessage ( char cMsgNum );
#separate void DisplayTemplateLatLon ( void );
#separate void DisplayTemplateWaypoint ( void );
#separate void DisplayTemplateAnalog ( void );
#separate void Delay5mS ( char cCnt );
#fuses HS, NOPROTECT, PUT, NOWDT, BROWNOUT, NOLVP, NOCPD
#use standard_io ( A )
#use standard_io ( B )
#use standard_io ( C )
#use delay ( clock = CRYSTAL_FREQ )
#use rs232 ( baud=4800, xmit=PIN_C6, rcv=PIN_C7, ERRORS ) // XMIT must be assigned to enable hardward USART
#priority RDA, RTCC, EXT
static char cC [ 10 ]; // local buffer
static char cTimeOut;
static char cRxBuffer [ RX_BUFFER_SIZE ]; // Fifo
static char cRxByteCnt; // Number of bytes in the recv fifo
static char *cRxBufferWritePtr; // Pointers for the Rx buffer
static char *cRxBufferReadPtr;
static char cRxIsrState, cRxMsgTypeReceived, cRxMsgTypeDesired;
static char cRxMsgReady, cReceiveFlag;
static long iVar, iLastRange, iTimeOut;
static char cVarDir, cScreenChanged, cAdcDone;
static char cButtonPressed, cSkip, cButtonCount;
static char cScreen, cSavedScreen, cRmcTimer1, cRmcTimer2;
static char cToFrom [ 5 ], cIndicator, cIllumination, cRxErrorFlag;
static char cDone, cContrast;
/*******************************************************************/
#int_ad
void AdcInterrupt ( void )
{
/* Gets here when ADC is done conversion, sets flag */
cAdcDone = YES;
}
#int_timer1
void Timer1Interrupt ( void )
{
/* Periodic RMC data timer, gets here every 204mS */
/* This routine forces RMC to run every 10 minutes to update */
/* magnetic variation */
if ( cRmcTimer1-- == 0 )
{
cRmcTimer1 = 255; // 52 seconds @ 10.240MHz
if ( cRmcTimer2-- == 0 )
{
cRmcTimer2 = RMC_TIME; // triggers every 10 minutes
cSavedScreen = cScreen; // save current screen type
cScreen = HIDDEN_RMC; // force RMC to run
}
}
}
#int_rtcc
void Timer0Interrupt ( void )
{
// Gets here every 16.4mS at 8MHz, 8.2mS at 16MHz
// Handles data timeout and switch debounce.
// DATA TIMEOUT TIMER
if ( cTimeOut != 0 )
{
cTimeOut--;
}
// This timer is preset by the normal operating loop, unless the operating
// loop stops looping, at which point iTimeOut finally decrements to zero
// and resets CPU.
if ( iTimeOut != 0 )
{
iTimeOut--;
}
else
{
reset_cpu(); // force reset
}
if ( input ( BUTTON_2 ) == LOW ) // if button still pressed
{
cScreen = WAYPOINT_SCREEN;
cSkip = YES; // skip out of anything in process
cScreenChanged = YES; // repaint complete screen
}
if ( input ( BUTTON_3 ) == LOW ) // if button still pressed
{
cScreen = BATTERY_SCREEN;
cSkip = YES; // skip out of anything in process
cScreenChanged = YES; // repaint complete screen
}
// SWITCH DEBOUNCE
if ( input ( BUTTON_1 ) == LOW ) // if button still pressed
{
if ( cButtonCount < 255 ) // hold at 255
{
cButtonCount++; // otherwise increment
}
}
else // if button is unpressed
{
if ( cButtonCount > 2 ) // filter out glitches
{
//If button press is greater than 3.3 seconds, cold reset
if ( cButtonCount == 255 )
{
reset_cpu();
}
if ( ( cButtonCount > 57 ) && ( cButtonCount < 255 ) )
{
if ( cScreen != HIDDEN_RMC ) // if not in the middle of getting magnetic variation
{
// cIllumination ^= ON;
output_bit ( LCD_BACKLITE, cIllumination ^= ON );
}
}
// If button press is less than 0.5 second
if ( cButtonCount <= 57 )
{
if ( cScreen != HIDDEN_RMC ) // if not in the middle of getting magnetic variation
{
//if ( cScreen++ >= BATTERY_SCREEN ) // increment to next screen
{
cScreen = POSITION_SCREEN; // wrap
}
cSkip = YES; // skip out of anything in process
cScreenChanged = YES; // repaint complete screen
}
}
}
cButtonCount = 0; // restart
}
}
#int_rda
void SerialInterrupt ( void )
{
/*
Reads incoming data from the USART and puts in in a rolling buffer
( but in this application, it should never roll.)
If the buffer is full, this routine just discards the received byte.
Not checking the LRC byte at the end of the NMEA-0183 sentence.
*/
char cChar;
if ( rs232_errors & 0x04 ) // get framing error bit from Rx status reg
{
cRxErrorFlag = ON;
}
cChar = getchar(); // get char from UART, clear any errors
if ( cRxByteCnt == RX_BUFFER_SIZE ) // is recv fifo full ???
{
goto done;
}
switch ( cRxIsrState )
{
case 0:
{
if ( cChar == DOLLAR ) // if start of NMEA0183 message
{
cRxByteCnt = 0; // reset byte count
cReceiveFlag = OFF; // default to off
cRxMsgTypeReceived = NULL; // set hashed value to null
cRxIsrState++; // next state
}
break;
}
case 1: // five type characters to obtain
case 2:
case 3:
case 4:
case 5:
{
cRxMsgTypeReceived ^= cChar; // hash in msg type
if ( cRxIsrState++ == 5 ) // if time to check message type
{
if ( cRxMsgTypeReceived == cRxMsgTypeDesired ) // if good
{
cReceiveFlag = YES; // enable receiving
cRxBufferWritePtr = cRxBuffer; // reset to beginning of buffer
}
else // don't want this message
{
cRxIsrState = 0; // reset to look for next msg
}
}
break;
}
case 6:
{
/* Case 6 skips the comma character following msg type */
cRxIsrState++;
break;
}
default: // remainder of characters
{
if ( cReceiveFlag == YES ) // if this message is wanted
{
*cRxBufferWritePtr = cChar; // put char in fifo
cRxBufferWritePtr++; // increment pointer
if ( cRxBufferWritePtr == ( cRxBuffer + RX_BUFFER_SIZE ) ) // pointer past end ?
{
cRxBufferWritePtr = cRxBuffer; // set pointer to start of fifo
}
cRxByteCnt++; // Increment byte count
if ( cChar == CR )
{
cRxMsgReady = YES; // signal that message is ready
cReceiveFlag = NO; // no more receive
}
}
}
}
done:;
}
/*******************************************************************/
void main ( void )
{
char cX;
iTimeOut = 65535; // default to very long to get by init
/* INITIALIZE */
output_float ( RX_IN ); // ensure Rx input is HiZ
output_float ( BUTTON_1 ); // ensure switch input is HiZ
output_float ( BUTTON_2 ); // ensure switch input is HiZ
output_float ( BUTTON_3 ); // ensure switch input is HiZ
output_low ( LCD_BACKLITE ); // turn off backlighting
port_b_pullups ( ON ); // enable pullups on switches
// GET SAVED SETTINGS
cContrast = read_eeprom ( EEPROM_CONTRAST ); // get stored value
// PWM is for display contrast
setup_ccp2 ( CCP_PWM ); // set for PWM mode
//The cycle time will be (1/clock)*4*t2div*(period+1)
// 1/8000000 * 4 * 1 * 128 = 51.2uS = 19.5KHz
setup_timer_2 ( T2_DIV_BY_1, 255, 1 ); // set PWM period
// duty cycle = value*(1/clock)*t2div
// 10 * 1/8000000 * 1 = 1.2uS
set_pwm2_duty ( cContrast ); // set contrast duty cycle
// SETUP TIMER 0
// Need 8-bit Timer0 to roll over every 13mS, approximately.
// Roll time = 256 * 1 / ( clock_freq / prescaler setting / 4 )
#if CRYSTAL_FREQ >= 15000000
setup_counters ( RTCC_INTERNAL, RTCC_DIV_256 ); // ~13mS timer wrap
#elif CRYSTAL_FREQ >= 8000000
setup_counters ( RTCC_INTERNAL, RTCC_DIV_128 ); // ~13mS timer wrap
#elif CRYSTAL_FREQ < 8000000
setup_counters ( RTCC_INTERNAL, RTCC_DIV_64 ); // ~13mS timer wrap
#endif
// Timer 1 roll time = 65536 * 1 / ( clock_freq / prescaler setting / 4 )
setup_timer_1 ( T1_INTERNAL | T1_DIV_BY_8 ); // 16-bit timer
setup_adc_ports ( RA0_RA1_RA3_ANALOG ); /* these three statements set up the ADC */
setup_adc ( ADC_CLOCK_INTERNAL );
cIllumination = OFF;
LCD_Init(); // set up LCD for 4-wire bus, etc.
/* INIT MESSAGE */
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( LINE_1 + 0 );
printf ( LCD_PutChar, " Northern Light " ); // welcome screen
LCD_SetPosition ( LINE_2 + 2 );
printf ( LCD_PutChar, "Monitor/Repeater" );
LCD_SetPosition ( LINE_3 + 3 );
printf ( LCD_PutChar, "v18 06/21/03" );
LCD_SetPosition ( LINE_4 + 5 );
printf ( LCD_PutChar, "c Jon Fick" );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( LINE_1 + 0);
printf ( LCD_PutChar, " Northern Light " ); // welcome screen
LCD_SetPosition ( LINE_2 + 2 );
printf ( LCD_PutChar, "GPS Repeater" );
LCD_SetPosition ( LINE_3 + 1 );
printf ( LCD_PutChar, "v18 06/21/03" );
LCD_SetPosition ( LINE_4 + 3 );
printf ( LCD_PutChar, "c Jon Fick" );
#endif
delay_ms ( 1000 );
/* INSTRUCTION MESSAGE */
LCD_PutCmd ( CLEAR_DISP );
LCD_SetPosition ( LINE_1 + 0 );
printf ( LCD_PutChar, "BUTTONS:" );
LCD_SetPosition ( LINE_2 + 0 );
printf ( LCD_PutChar, "<-- Lat/Lon" );
LCD_SetPosition ( LINE_3 + 0 );
printf ( LCD_PutChar, "<-- Waypoint" );
LCD_SetPosition ( LINE_4 + 0 );
printf ( LCD_PutChar, "<-- Battery" );
delay_ms ( 2000 );
/* SETUP MODE */
if ( input ( BUTTON_1 ) == LOW ) // if button is pressed
{
LCD_PutCmd ( CLEAR_DISP );
LCD_SetPosition ( LINE_1 + 0 );
printf ( LCD_PutChar, "Set contrast:" );
LCD_SetPosition ( LINE_2 + 0 );
printf ( LCD_PutChar, "<-- More" );
LCD_SetPosition ( LINE_3 + 0 );
printf ( LCD_PutChar, "<-- DONE" );
LCD_SetPosition ( LINE_4 + 0 );
printf ( LCD_PutChar, "<-- Less" );
while ( input ( BUTTON_1 ) == LOW ); // wait for switch to be released after entering SETUP mode
cContrast = 120; // start at full contrast
cDone = NO;
while ( cDone == NO )
{
set_pwm2_duty ( cContrast ); // update contrast
if ( input ( BUTTON_1 ) == LOW )
{
if ( cContrast > 0 )
{
cContrast--; // more
}
}
if ( input ( BUTTON_2 ) == LOW )
{
cDone = YES; // done
}
if ( input ( BUTTON_3 ) == LOW )
{
if ( cContrast < 255 )
{
cContrast++; // less
}
}
delay_ms ( 30 ); // autorepeat
}
write_eeprom ( EEPROM_CONTRAST, cContrast ); // save CONTRAST to EEPROM
LCD_PutCmd ( CLEAR_DISP );
LCD_SetPosition ( LINE_2 + 0 );
printf ( LCD_PutChar, "<- Press initial" );
LCD_SetPosition ( LINE_3 + 0 );
printf ( LCD_PutChar, " bootup screen" );
while ( input ( BUTTON_1 ) == LOW ); // wait until button not pressed
cX = POSITION_SCREEN;
while ( TRUE )
{
LCD_SetPosition ( LINE_4 + 3 );
switch ( cX )
{
case POSITION_SCREEN:
{
printf ( LCD_PutChar, "POSITION " );
break;
}
case WAYPOINT_SCREEN:
{
printf ( LCD_PutChar, "WAYPOINT " );
break;
}
case BATTERY_SCREEN:
{
printf ( LCD_PutChar, "BATTERY " );
break;
}
}
delay_ms ( 750 );
if ( input ( BUTTON_1 ) == LOW ) // if button is pressed
{
write_eeprom ( EEPROM_INITIAL, cX ); // save screen number to EEPROM
break;
}
if ( cX++ == BATTERY_SCREEN )
{
cX = POSITION_SCREEN;
}
}
LCD_PutCmd ( CLEAR_DISP );
}
/* This IF/ENDIF is a tool for getting the $GP... codes */
/* that are used in the switch/case in the main loop. */
#if ( GET_GPS_CODE == YES )
printf ( LCD_PutChar, "%u", 'G'^'P'^'R'^'M'^'B');
while ( TRUE );
#endif
/* INTERRUPTS */
ext_int_edge ( H_TO_L ); // set falling edge ext interrupt
enable_interrupts ( INT_TIMER1 ); // enable Timer1 interrupt
enable_interrupts ( INT_RDA ); // enable serial interrupt
enable_interrupts ( INT_RTCC ); // enable Timer0 interrupt
enable_interrupts ( INT_AD ); // enable ADC interrupt
enable_interrupts ( GLOBAL ); // enable all interrupts
/* VARIABLES */
iVar = NULL; // default, no variation yet
cVarDir = SPACE; // default, no variation yet
cRmcTimer1 = 255; // initialize to 52 seconds
cRmcTimer2 = RMC_TIME; // trigger forced RMC after 10 minutes
cScreen = HIDDEN_RMC; // default screen, get magnetic variation first
cSavedScreen = read_eeprom ( EEPROM_INITIAL ); // restore initial screen
iLastRange = 65535; // make max by default
strcpy ( cToFrom, " " ); // blank by default
cScreenChanged = YES;
cIndicator = 0;
cButtonCount = 0;
cButtonPressed = NO;
cRxErrorFlag = OFF;
/* MAIN LOOP */
while ( TRUE )
{
cTimeOut = 188; // 231 * 0.013mS = 3 seconds
switch ( cScreen )
{
case HIDDEN_RMC:
{
InitRxBuffer( GPRMC_CODE ); // set code and turn on serial interrupt
while ( ( cRxMsgReady == NO ) && ( cTimeOut != 0 ) );
disable_interrupts ( INT_RDA ); // ignore rest of messages
if ( cTimeOut != 0 ) // if not timed out
{
GetUtcAndMagVar(); // get and store the magnetic variation
}
cScreen = cSavedScreen; // revert to previous screen
break;
}
case POSITION_SCREEN:
{
if ( cScreenChanged == YES )
{
disable_interrupts ( INT_RDA );
cScreenChanged = NO;
cSkip = NO;
LCD_PutCmd ( CLEAR_DISP );
DisplayTemplateLatLon();
enable_interrupts ( INT_RDA );
}
InitRxBuffer( GPRMC_CODE ); // set code and turn on serial interrupt
while ( ( cRxMsgReady == NO ) && ( cTimeOut != 0 ) && ( cScreenChanged != YES ) );
disable_interrupts ( INT_RDA ); // ignore rest of messages
if ( cScreenChanged == NO )
{
if ( cTimeOut != 0 )
{
DisplayLatLon();
}
else
{
DisplayMessage ( NODATA_MSG );
}
}
cRxErrorFlag = OFF;
break;
}
case WAYPOINT_SCREEN:
{
if ( cScreenChanged == YES )
{
disable_interrupts ( INT_RDA );
cScreenChanged = NO;
cSkip = NO;
LCD_PutCmd ( CLEAR_DISP );
DisplayTemplateWaypoint();
enable_interrupts ( INT_RDA );
}
cSkip = NO;
InitRxBuffer( GPRMB_CODE ); // set code and turn on serial interrupt
while ( ( cRxMsgReady == NO ) && ( cTimeOut != 0 ) && ( cScreenChanged != YES ) );
disable_interrupts ( INT_RDA ); // ignore rest of messages
if ( cScreenChanged == NO )
{
if ( cTimeOut != 0 )
{
DisplayWaypoint();
}
else
{
DisplayMessage ( NODATA_MSG );
}
}
break;
}
case BATTERY_SCREEN:
{
if ( cScreenChanged == YES )
{
disable_interrupts ( INT_RDA );
cScreenChanged = NO;
cSkip = NO;
LCD_PutCmd ( CLEAR_DISP );
DisplayTemplateAnalog();
}
DisplayAnalog();
break;
}
}
// Preset timeout counter each loop; RTCC interrupt decrements, resets if zero is reached
iTimeOut = 2000; // ~ 30 seconds
/* Flashing activity indicator in lower right of screen. */
cIndicator ^= 1;
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( LINE_4 + 19 );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( LINE_4 + 15 );
#endif
if ( cIndicator == 1 )
{
printf ( LCD_PutChar, "%c", ACTIVITY_SYMBOL );
}
else
{
printf ( LCD_PutChar, " " );
}
}
}
#separate void DisplayTemplateLatLon ( void )
{
LCD_SetPosition ( LINE_1 );
printf ( LCD_PutChar, "LAT" );
LCD_SetPosition ( LINE_2 );
printf ( LCD_PutChar, "LON" );
LCD_SetPosition ( LINE_3 );
#if ( DISPLAY_COLS == 20 )
printf ( LCD_PutChar, "SPEED" );
LCD_SetPosition ( LINE_4 );
printf ( LCD_PutChar, "HEADING" );
#elif ( DISPLAY_COLS == 16 )
printf ( LCD_PutChar, "SPD" );
LCD_SetPosition ( LINE_4 );
printf ( LCD_PutChar, "HDG" );
#endif
}
#separate void DisplayTemplateWaypoint ( void )
{
LCD_SetPosition ( LINE_1 );
#if ( DISPLAY_COLS == 20 )
printf ( LCD_PutChar, "WAYPOINT" );
#elif ( DISPLAY_COLS == 16 )
printf ( LCD_PutChar, "WAYPT" );
#endif
LCD_SetPosition ( LINE_2 );
printf ( LCD_PutChar, "STEER" );
LCD_SetPosition ( LINE_3 );
printf ( LCD_PutChar, "DIST" );
LCD_SetPosition ( LINE_4 );
printf ( LCD_PutChar, "BEARING" );
}
#separate void DisplayTemplateAnalog ( void )
{
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( LINE_1 + 3 );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( LINE_1 + 1 );
#endif
printf ( LCD_PutChar, "BATTERY STATUS" );
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( LINE_2 );
printf ( LCD_PutChar, "Primary" );
LCD_SetPosition ( LINE_3 );
printf ( LCD_PutChar, "Secondary" );
LCD_SetPosition ( LINE_4 );
printf ( LCD_PutChar, "Refrigerator" );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( LINE_2 );
printf ( LCD_PutChar, "Main#1 " );
LCD_SetPosition ( LINE_3 );
printf ( LCD_PutChar, "Main#2 " );
LCD_SetPosition ( LINE_4 );
printf ( LCD_PutChar, "Refrig " );
#endif
}
#separate void DisplayLatLon ( void )
{
SkipField ( 1 ); // skip UTC
GetField(); // A = OK, V = warning
if ( ( cC [ 0 ] == 'A' ) && ( !cSkip ) )
{
GetField(); // LAT
if ( !cSkip )
{
DisplayLatitude ( LINE_1 );
}
GetField(); // LON
if ( !cSkip )
{
DisplayLongitude ( LINE_2 );
}
GetField(); // SPEED
if ( !cSkip )
{
DisplaySpeed ( LINE_3 );
}
GetField(); // HEADING
if ( !cSkip )
{
DisplayHeading ( LINE_4 );
}
}
else
{
DisplayMessage( WARNING_MSG );
}
}
#separate void DisplayWaypoint ( void )
{
char cX;
GetField(); // A = OK, V = warning
if ( ( cC [ 0 ] == 'A' ) && ( !cSkip ) )
{
cX = GetField(); // XTE
if ( !cSkip )
{
DisplaySteer ( LINE_2, cX );
}
SkipField ( 1 ); // skip origin WP ID
GetField(); // DEST WP ID
if ( !cSkip )
{
DisplayWaypointName ( LINE_1, cX );
}
SkipField ( 4 ); // skip LAT, NS, LON, EW
cX = GetField(); // RANGE
if ( !cSkip )
{
DisplayDistance ( LINE_3, cX );
}
cX = GetField(); // BEARING
if ( !cSkip )
{
DisplayBearing ( LINE_4, cX );
}
SkipField ( 1 ); // skip SPEED TO DEST
GetField(); // ARRIVAL FLAG
if ( !cSkip )
{
DisplayArrival ( LINE_1 ); // overwrite RANGE if arrived
}
}
else
{
DisplayMessage( WARNING_MSG );
}
}
#separate void DisplayAnalog ( void )
{
long iX;
char cCnt;
set_adc_channel ( 0 ); // set channel
delay_us ( 100 ); // wait aquisition time
cAdcDone = NO;
if ( !cSkip )
{
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( LINE_2 + 13 );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( LINE_2 + 8 );
#endif
DisplayScaledVoltage ( read_adc(), MAX_VOLTS );
printf ( LCD_PutChar, " V " );
}
set_adc_channel ( 1 );
delay_us ( 100 );
cAdcDone = NO;
if ( !cSkip )
{
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( LINE_3 + 13 );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( LINE_3 + 8 );
#endif
DisplayScaledVoltage ( read_adc(), MAX_VOLTS );
printf ( LCD_PutChar, " V " );
}
set_adc_channel ( 3 );
delay_us ( 100 );
cAdcDone = NO;
if ( !cSkip )
{
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( LINE_4 + 13 );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( LINE_4 + 8 );
#endif
DisplayScaledVoltage ( read_adc(), MAX_VOLTS );
printf ( LCD_PutChar, " V " );
}
Delay5mS ( 100 ); // slow loop down a bit
}
#separate void GetUtcAndMagVar ( void )
{
/*
This is a non-display version of the RMC sentence
to get the A/V warning, the magnetic variation, and the
magnetic direction.
*/
GetField(); // get UTC
GetField(); // A = OK, V = warning
if ( cC [ 0 ] == 'A' )
{
SkipField ( 7 ); // skip fields
GetField(); // MAGNETIC VARIATION
iVar = FieldFiveToLong(); // save to global variable, used in other sentences
GetField(); // EW
cVarDir = cC [ 0 ]; // save direction
}
else
{
iVar = NULL; // invalid
cVarDir = SPACE;
}
}
/******************************************************************/
#separate void DisplayScaledVoltage ( long iV, char cScale )
{
float fX;
/*
0 to 5V input at pin 2 results in 0 - 1023. This routine
scales it to something else.
*/
while ( cAdcDone == NO ); // wait for completion by ADC interrupt
if ( iV == 1023 )
{
printf ( LCD_PutChar, "O/L" ); /* print it to the screen */
}
else
{
fX = ( ( float ) iV ) / 1023 * ( float ) cScale; // scale to proper range, 1023 leaves room for out-of-range
printf ( LCD_PutChar, "%2.1f", fX ); /* print it to the screen */
}
}
#separate void DisplayArrival ( char cLine )
{
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( cLine + 11 );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( cLine + 9 );
#endif
if ( cC [ 0 ] == 'A' )
{
printf ( LCD_PutChar, "Arrived" );
}
else
{
printf ( LCD_PutChar, " " );
}
}
#separate void DisplayWaypointName ( char cLine, char cX )
{
/* Displays waypoint name, pads field with blanks */
char cChar, cI;
LCD_SetPosition ( cLine );
if ( cX != 0 )
{
printf ( LCD_PutChar, "\"" );
for ( cI = 0; cI < 6; cI++ )
{
cChar = cC [ cI ];
if ( cChar == EOF )
{
break;
}
printf ( LCD_PutChar, "%c", cChar );
}
printf ( LCD_PutChar, "\"" );
// Blank remainder of field
cChar = SPACE;
for ( ; cI < 6; cI++ )
{
printf ( LCD_PutChar, "%c", cChar );
}
}
else
{
printf ( LCD_PutChar, "- none -" );
}
}
#separate void DisplaySteer ( char cLine, char cX )
{
/*
Displays A.BC literals, appends 'L' or 'R'.
If less than 1.0, displays feet rather than nm.
Doesn't display distance if on track.
*/
long iX;
char cCnt;
if ( cX != 0 )
{
if ( ( cC [ 0 ] != '0' ) || ( cC [ 2 ] != '0' ) || ( cC [ 3 ] != '0' ) ) // if not 0.00
{
LCD_SetPosition ( cLine + 14 );
#if ( DISPLAY_COLS == 20 )
printf ( LCD_PutChar, " " ); // blank possible characters
LCD_SetPosition ( cLine + 11 );
#elif ( DISPLAY_COLS == 16 )
printf ( LCD_PutChar, " " ); // blank possible characters
LCD_SetPosition ( cLine + 8);
#endif
if ( cC [ 0 ] == '0' ) // if less than 1.0 nm, display as feet
{
iX = ( 528 * ( long ) ( cC [ 2 ] - 0x30 ) ) + ( 52 * ( long ) ( cC [ 3 ] - 0x30 ) );
printf ( LCD_PutChar, "%luft ", iX );
}
else // if 1.0 nm or greater, display as nautical miles
{
printf ( LCD_PutChar, "%c%c%c%cmi ", cC [ 0 ], cC [ 1 ], cC [ 2 ] , cC [ 3 ] );
}
GetField(); // L or R
LCD_SetPosition ( cLine + 6 );
if ( cC [ 0 ] == 'L' )
{
#if ( DISPLAY_COLS == 20 )
printf ( LCD_PutChar, "PORT " );
#elif ( DISPLAY_COLS == 16 )
printf ( LCD_PutChar, "L" );
#endif
}
else
{
#if ( DISPLAY_COLS == 20 )
printf ( LCD_PutChar, "STBD " );
#elif ( DISPLAY_COLS == 16 )
printf ( LCD_PutChar, "R" );
#endif
}
}
else // if 0.00
{
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( cLine + 11 );
printf ( LCD_PutChar, "On track " );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( cLine + 6 );
printf ( LCD_PutChar, " On track" );
#endif
GetField(); // dummy L or R
}
}
else
{
LCD_SetPosition ( cLine + 6 );
printf ( LCD_PutChar, " " );
}
}
#separate void DisplayDistance ( char cLine, char cX )
{
/* Format: ABC.D nautical miles */
char cChar, cI;
long iThisRange;
if ( cX != 0 ) // if waypoint data to display
{
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( cLine + 11 );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( cLine + 8 );
#endif
cI = 0;
for ( cI = 0; cI < 2; cI++ ) // find first non-zero
{
cChar = cC [ cI ];
if ( cChar != '0' )
{
break;
}
}
for ( ; cI < 5; cI++ ) // display from there on
{
printf ( LCD_PutChar, "%c", cC [ cI ] );
}
printf ( LCD_PutChar, "nm " ); // pad with blanks
/*
The least significant character from the GPS is 0.1 nm.
Multiply whole thing by 10 and make it type long.
Discern if increasing (FROM) or decreasing (TO).
*/
iThisRange = 1000 * ( long ) ( cC [ 0 ] - 0x30 );
iThisRange += 100 * ( long ) ( cC [ 1 ] - 0x30 );
iThisRange += 10 * ( long ) ( cC [ 2 ] - 0x30 );
iThisRange += ( long ) ( cC [ 4 ] - 0x30 );
if ( iThisRange < iLastRange )
{
#if ( DISPLAY_COLS == 20 )
strcpy ( cToFrom, "TO " );
#elif ( DISPLAY_COLS == 16 )
strcpy ( cToFrom, "TO" );
#endif
}
if ( iThisRange > iLastRange )
{
#if ( DISPLAY_COLS == 20 )
strcpy ( cToFrom, "FROM" );
#elif ( DISPLAY_COLS == 16 )
strcpy ( cToFrom, "FM" );
#endif
}
iLastRange = iThisRange; // save this range to compare next time
LCD_SetPosition ( cLine + 5 );
printf ( LCD_PutChar, cToFrom );
}
else
{
LCD_SetPosition ( cLine + 5 );
#if ( DISPLAY_COLS == 20 )
printf ( LCD_PutChar, " " );
#elif ( DISPLAY_COLS == 16 )
printf ( LCD_PutChar, " " );
#endif
}
}
#separate void DisplayBearing ( char cLine, char cX )
{
/*
Compass variation comes from RMC sentence. If RMC has not run yet
then "T" is displayed after bearing.
*/
long iHdg;
char cTrueIndicator;
if ( cX != 0 ) // if waypoint data to display
{
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( cLine + 11 );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( cLine + 8 );
#endif
iHdg = FieldFiveToLong();
iHdg = TrueToMag ( iHdg ); // factor variation into heading
if ( ( iVar == NULL ) || ( cVarDir == SPACE ) )
{
cTrueIndicator = 'T';
}
else
{
cTrueIndicator = ' ';
}
printf ( LCD_PutChar, "%lu%c%c ", iHdg, DEGREE, cTrueIndicator ); // pad with blanks
}
else
{
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( cLine + 11 );
printf ( LCD_PutChar, " " );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( cLine + 8 );
printf ( LCD_PutChar, " " );
#endif
}
}
#separate void DisplayLatitude ( char cLine )
{
/* Displays latitude ABCD.EF as AB CD.EF, appends 'N' or 'S' */
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( cLine + 8 );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( cLine + 5 );
#endif
if ( cC [ 0 ] == '0' )
{
cC [ 0 ] = SPACE;
}
printf ( LCD_PutChar, "%c%c%c", cC [ 0 ], cC [ 1 ], DEGREE );
printf ( LCD_PutChar, "%c%c%c%c%c%c", cC [ 2 ], cC [ 3 ], cC [ 4 ], cC [ 5 ], cC [ 6 ], cC [ 7 ] );
GetField(); // NS
printf ( LCD_PutChar, " %c", cC [ 0 ] );
}
#separate void DisplayLongitude ( char cLine )
{
/* Displays longitude ABCDE.FG as ABC DE.FG, appends 'E' or 'W' */
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( cLine + 7 );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( cLine + 4 );
#endif
if ( cC [ 0 ] == '0' )
{
cC [ 0 ] = SPACE;
}
if ( cC [ 1 ] == '0' )
{
cC [ 1 ] = SPACE;
}
printf ( LCD_PutChar, "%c%c%c%c", cC [ 0 ], cC [ 1 ], cC [ 2 ], DEGREE );
printf ( LCD_PutChar, "%c%c%c%c%c%c", cC [ 3 ], cC [ 4 ], cC [ 5 ], cC [ 6 ], cC [ 7 ], cC [ 8 ] );
GetField(); // EW
printf ( LCD_PutChar, " %c", cC [ 0 ] );
}
#separate void DisplaySpeed ( char cLine )
{
float fX;
// Format ABC.D
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( cLine + 8 );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( cLine + 5 );
#endif
fX = 100 * ( cC [ 0 ] - 0x30 );
fX += 10 * ( cC [ 1 ] - 0x30 );
fX += 1 * ( cC [ 2 ] - 0x30 );
fX += 0.1 * ( cC [ 4 ] - 0x30 );
#if SPEED_UNITS == 2
fX *= 1.852; // convert knots to km/h
#endif
#if SPEED_UNITS == 3
fX *= 1.151; // convert knots to mi/h
#endif
printf ( LCD_PutChar, "%3.1f ", fX ); // print it to the screen
#if SPEED_UNITS == 1
printf ( LCD_PutChar, "kts " ); // print it to the screen
#endif
#if SPEED_UNITS == 2
printf ( LCD_PutChar, "kph " ); // print it to the screen
#endif
#if SPEED_UNITS == 3
printf ( LCD_PutChar, "mph " ); // print it to the screen
#endif
}
#separate void DisplayHeading ( char cLine )
{
long iHdg;
#if ( DISPLAY_COLS == 20 )
LCD_SetPosition ( cLine + 8 );
#elif ( DISPLAY_COLS == 16 )
LCD_SetPosition ( cLine + 5 );
#endif
iHdg = FieldFiveToLong();
SkipField ( 1 ); // skip fix date
GetField(); // MAGNETIC VARIATION
iVar = FieldFiveToLong(); // save to global variable, used in other sentences
GetField(); // EW
cVarDir = cC [ 0 ]; // save direction
iHdg = TrueToMag ( iHdg ); // factor variation into heading
printf ( LCD_PutChar, "%lu%c ", iHdg, DEGREE ); // pad with blanks
}
#separate long FieldFiveToLong ( void )
{
/* Converts ABC.D to long, rounds decimal up or down */
long iX;
iX = 100 * ( long ) ( cC [ 0 ] - 0x30 );
iX += 10 * ( long ) ( cC [ 1 ] - 0x30 );
iX += ( long ) ( cC [ 2 ] - 0x30 );
if ( ( cC [ 3 ] == PERIOD ) && ( cC [ 4 ] >= '5' ) )
{
iX++; // round up
}
return ( iX );
}
#separate long TrueToMag ( long iH )
{
/* Magnetic variation information comes from the RMC sentence */
if ( cVarDir == 'W' )
{
iH += iVar;
}
else
{
if ( iH >= iVar )
{
iH -= iVar; // OK as-is
}
else
{
iH = iH + 360 - iVar; // correct for below zero
}
}
if ( iH >= 360 )
{
iH -= 360;
}
return ( iH );
}
#separate void DisplayMessage ( char cMsgNum )
{
LCD_PutCmd ( CLEAR_DISP );
LCD_SetPosition ( LINE_2 );
switch ( cMsgNum )
{
case WARNING_MSG:
{
#if ( DISPLAY_COLS == 20 )
printf ( LCD_PutChar, " GPS warning " );
#elif ( DISPLAY_COLS == 16 )
printf ( LCD_PutChar, " GPS warning" );
#endif
break;
}
case NODATA_MSG:
{
if ( cRxErrorFlag == OFF ) // is it a framing error problem ?
{
#if ( DISPLAY_COLS == 20 )
printf ( LCD_PutChar, " No data from GPS" );
#elif ( DISPLAY_COLS == 16 )
printf ( LCD_PutChar, "No data from GPS" );
#endif
}
else
{
#if ( DISPLAY_COLS == 20 )
printf ( LCD_PutChar, " Baud error" );
#elif ( DISPLAY_COLS == 16 )
printf ( LCD_PutChar, " Baud error" );
#endif
cRxErrorFlag = OFF;
}
break;
}
}
Delay5mS ( 255 ); // delay 1.25 seconds
iVar = NULL;
cVarDir = SPACE; // signal "no magnetic variation" yet
cScreenChanged = YES;
}
#separate void Delay5mS ( char cCnt )
{
char cX;
/* This variable-count 5mS delay is interruptable by a button press */
for ( cX = 0; cX < cCnt; cX++ )
{
if ( cScreenChanged == YES )
{
break;
}
delay_ms ( 5 );
}
}
#separate char GetField ( void )
{
char cX, cIndex;
cX = NULL;
cIndex = 0;
while ( !cSkip )
{
cX = GetRxChar();
if ( ( cX == COMMA ) || ( cX == CR ) )
{
break;
}
cC [ cIndex++ ] = cX;
}
cC [ cIndex ] = EOF;
return ( cIndex ); // return number of characters in field
}
#separate void SkipField ( char cCnt )
{
char cX;
for ( cX = 0; cX < cCnt; cX++ )
{
while ( GetRxChar() != COMMA );
}
}
/* RS232 FUNCTIONS ================================================== */
#separate void InitRxBuffer ( char cCode )
{
disable_interrupts ( INT_RDA );
cRxBufferWritePtr = cRxBuffer; // point to beginning of buffer
cRxBufferReadPtr = cRxBuffer;
cRxByteCnt = 0;
cRxIsrState = 0;
cRxMsgReady = NO;
cRxMsgTypeDesired = cCode;
enable_interrupts ( INT_RDA );
}
#separate char GetRxChar ( void )
{
// Get the next available byte in the recv fifo.
// Call this function ONLY if the recv fifo contains data.
char cValue;
cValue = 0;
if ( cRxByteCnt > 0 ) // For safety, check if there is any data
{
cValue = *cRxBufferReadPtr++; // Read byte from fifo
if ( cRxBufferReadPtr == ( cRxBuffer + RX_BUFFER_SIZE ) ) // Did tail ptr wrap ?
{
cRxBufferReadPtr = cRxBuffer; // If so, reset it to start of buffer
}
cRxByteCnt--; // Decrement byte count
}
return ( cValue );
}
/* LCD FUNCTIONS ================================= */
#separate void LCD_Init ( void )
{
LCD_SetData ( 0x00 );
delay_ms ( 200 ); /* wait enough time after Vdd rise */
output_low ( LCD_RS );
LCD_SetData ( 0x03 ); /* init with specific nibbles to start 4-bit mode */
LCD_PulseEnable();
LCD_PulseEnable();
LCD_PulseEnable();
LCD_SetData ( 0x02 ); /* set 4-bit interface */
LCD_PulseEnable(); /* send dual nibbles hereafter, MSN first */
LCD_PutCmd ( 0x2C ); /* function set (all lines, 5x7 characters) */
LCD_PutCmd ( 0x0C ); /* display ON, cursor off, no blink */
LCD_PutCmd ( 0x01 ); /* clear display */
LCD_PutCmd ( 0x06 ); /* entry mode set, increment & scroll left */
}
#separate void LCD_SetPosition ( unsigned int cX )
{
/* this subroutine works specifically for 4-bit Port A */
LCD_SetData ( swap ( cX ) | 0x08 );
LCD_PulseEnable();
LCD_SetData ( swap ( cX ) );
LCD_PulseEnable();
}
#separate void LCD_PutChar ( unsigned int cX )
{
/* this subroutine works specifically for 4-bit Port A */
if ( !cSkip )
{
output_high ( LCD_RS );
LCD_SetData ( swap ( cX ) ); /* send high nibble */
LCD_PulseEnable();
LCD_SetData ( swap ( cX ) ); /* send low nibble */
LCD_PulseEnable();
output_low ( LCD_RS );
}
}
#separate void LCD_PutCmd ( unsigned int cX )
{
/* this subroutine works specifically for 4-bit Port A */
LCD_SetData ( swap ( cX ) ); /* send high nibble */
LCD_PulseEnable();
LCD_SetData ( swap ( cX ) ); /* send low nibble */
LCD_PulseEnable();
}
#separate void LCD_PulseEnable ( void )
{
output_high ( LCD_EN );
delay_us ( 3 ); // was 10
output_low ( LCD_EN );
delay_ms ( 3 ); // was 5
}
#separate void LCD_SetData ( unsigned int cX )
{
output_bit ( LCD_D0, cX & 0x01 );
output_bit ( LCD_D1, cX & 0x02 );
output_bit ( LCD_D2, cX & 0x04 );
output_bit ( LCD_D3, cX & 0x08 );
}