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// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// + www.MikroKopter.com
// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// + Software Nutzungsbedingungen (english version: see below)
// + der Fa. HiSystems GmbH, Flachsmeerstrasse 2, 26802 Moormerland - nachfolgend Lizenzgeber genannt -
// + Der Lizenzgeber räumt dem Kunden ein nicht-ausschließliches, zeitlich und räumlich* unbeschränktes Recht ein, die im den
// + Mikrocontroller verwendete Firmware für die Hardware Flight-Ctrl, Navi-Ctrl, BL-Ctrl, MK3Mag & PC-Programm MikroKopter-Tool
// + - nachfolgend Software genannt - nur für private Zwecke zu nutzen.
// + Der Einsatz dieser Software ist nur auf oder mit Produkten des Lizenzgebers zulässig.
// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// + Die vom Lizenzgeber gelieferte Software ist urheberrechtlich geschützt. Alle Rechte an der Software sowie an sonstigen im
// + Rahmen der Vertragsanbahnung und Vertragsdurchführung überlassenen Unterlagen stehen im Verhältnis der Vertragspartner ausschließlich dem Lizenzgeber zu.
// + Die in der Software enthaltenen Copyright-Vermerke, Markenzeichen, andere Rechtsvorbehalte, Seriennummern sowie
// + sonstige der Programmidentifikation dienenden Merkmale dürfen vom Kunden nicht verändert oder unkenntlich gemacht werden.
// + Der Kunde trifft angemessene Vorkehrungen für den sicheren Einsatz der Software. Er wird die Software gründlich auf deren
// + Verwendbarkeit zu dem von ihm beabsichtigten Zweck testen, bevor er diese operativ einsetzt.
// + Die Haftung des Lizenzgebers wird - soweit gesetzlich zulässig - begrenzt in Höhe des typischen und vorhersehbaren
// + Schadens. Die gesetzliche Haftung bei Personenschäden und nach dem Produkthaftungsgesetz bleibt unberührt. Dem Lizenzgeber steht jedoch der Einwand
// + des Mitverschuldens offen.
// + Der Kunde trifft angemessene Vorkehrungen für den Fall, dass die Software ganz oder teilweise nicht ordnungsgemäß arbeitet.
// + Er wird die Software gründlich auf deren Verwendbarkeit zu dem von ihm beabsichtigten Zweck testen, bevor er diese operativ einsetzt.
// + Der Kunde wird er seine Daten vor Einsatz der Software nach dem Stand der Technik sichern.
// + Der Kunde ist darüber unterrichtet, dass der Lizenzgeber seine Daten im zur Vertragsdurchführung erforderlichen Umfang
// + und auf Grundlage der Datenschutzvorschriften erhebt, speichert, verarbeitet und, sofern notwendig, an Dritte übermittelt.
// + *) Die räumliche Nutzung bezieht sich nur auf den Einsatzort, nicht auf die Reichweite der programmierten Software.
// + #### ENDE DER NUTZUNGSBEDINGUNGEN ####'
// + Hinweis: Informationen über erweiterte Nutzungsrechte (wie z.B. Nutzung für nicht-private Zwecke) sind auf Anfrage per Email an info(@)hisystems.de verfügbar.
// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// + Software LICENSING TERMS
// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// + of HiSystems GmbH, Flachsmeerstrasse 2, 26802 Moormerland, Germany - the Licensor -
// + The Licensor grants the customer a non-exclusive license to use the microcontroller firmware of the Flight-Ctrl, Navi-Ctrl, BL-Ctrl, and MK3Mag hardware
// + (the Software) exclusively for private purposes. The License is unrestricted with respect to time and territory*.
// + The Software may only be used with the Licensor's products.
// + The Software provided by the Licensor is protected by copyright. With respect to the relationship between the parties to this
// + agreement, all rights pertaining to the Software and other documents provided during the preparation and execution of this
// + agreement shall be the property of the Licensor.
// + The information contained in the Software copyright notices, trademarks, other legal reservations, serial numbers and other
// + features that can be used to identify the program may not be altered or defaced by the customer.
// + The customer shall be responsible for taking reasonable precautions
// + for the safe use of the Software. The customer shall test the Software thoroughly regarding its suitability for the
// + intended purpose before implementing it for actual operation. The Licensor's liability shall be limited to the extent of typical and
// + foreseeable damage to the extent permitted by law, notwithstanding statutory liability for bodily injury and product
// + liability. However, the Licensor shall be entitled to the defense of contributory negligence.
// + The customer will take adequate precautions in the case, that the software is not working properly. The customer will test
// + the software for his purpose before any operational usage. The customer will backup his data before using the software.
// + The customer understands that the Licensor collects, stores and processes, and, where required, forwards, customer data
// + to third parties to the extent necessary for executing the agreement, subject to applicable data protection and privacy regulations.
// + *) The territory aspect only refers to the place where the Software is used, not its programmed range.
// + #### END OF LICENSING TERMS ####
// + Note: For information on license extensions (e.g. commercial use), please contact us at info(@)hisystems.de.
// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
#include "main.h"
#define MULTIPLYER 4
volatile unsigned int CountMilliseconds
= 0;
volatile unsigned int tim_main
;
volatile unsigned char UpdateMotor
= 0;
volatile unsigned int cntKompass
= 0;
volatile unsigned int beeptime
= 0;
volatile unsigned char SendSPI
= 0, ServoActive
= 0, CalculateServoSignals
= 1;
unsigned char JustMK3MagConnected
= 0;
uint16_t RemainingPulse
= 0;
volatile int16_t ServoNickOffset
= (255 / 2) * MULTIPLYER
* 16; // initial value near center positon
volatile int16_t ServoRollOffset
= (255 / 2) * MULTIPLYER
* 16; // initial value near center positon
volatile int16_t ServoPanOffset
= (255 / 2) * MULTIPLYER
* 16; // MartinR: für Pan-Funktion
unsigned int BeepMuster
= 0xffff;
signed int NickServoValue
= 128 * MULTIPLYER
* 16;
volatile int16_t ServoNickValue
= 0;
volatile int16_t ServoRollValue
= 0;
volatile int16_t ServoPanValue
= 0; // MartinR : für PAN-Funktion
enum {
STOP
= 0,
CK
= 1,
CK8
= 2,
CK64
= 3,
CK256
= 4,
CK1024
= 5,
T0_FALLING_EDGE
= 6,
T0_RISING_EDGE
= 7
};
ISR
(TIMER0_OVF_vect
) // 9,7kHz
{
static unsigned char cnt_1ms
= 1,cnt
= 0;
unsigned char pieper_ein
= 0;
if(SendSPI
) SendSPI
--;
if(SpektrumTimer
) SpektrumTimer
--;
if(!cnt
--)
{
cnt
= 9;
CountMilliseconds
++;
cnt_1ms
++;
cnt_1ms
%= 2;
if(!cnt_1ms
) UpdateMotor
= 1;
if(!(PINC
& 0x10)) JustMK3MagConnected
= 1;
if(beeptime
)
{
if(beeptime
> 10) beeptime
-= 10; else beeptime
= 0;
if(beeptime
& BeepMuster
)
{
pieper_ein
= 1;
}
else pieper_ein
= 0;
}
else
{
pieper_ein
= 0;
BeepMuster
= 0xffff;
}
#if (defined(__AVR_ATmega1284__) || defined(__AVR_ATmega1284P__))
if(pieper_ein
) PORTC
|= (1<<7); // Speaker an PORTC.7
else PORTC
&= ~
(1<<7);
#else
if(pieper_ein
)
{
if(PlatinenVersion
== 10) PORTD
|= (1<<2); // Speaker an PORTD.2
else PORTC
|= (1<<7); // Speaker an PORTC.7
}
else
{
if(PlatinenVersion
== 10) PORTD
&= ~
(1<<2);
else PORTC
&= ~
(1<<7);
}
#endif
}
if(JustMK3MagConnected
&& !NaviDataOkay
&& Parameter_GlobalConfig
& CFG_KOMPASS_AKTIV
)
{
if(PINC
& 0x10)
{
if(++cntKompass
> 1000) JustMK3MagConnected
= 0;
}
else
{
if((cntKompass
) && (cntKompass
< 362))
{
cntKompass
+= cntKompass
/ 41;
if(cntKompass
> 10) KompassValue
= cntKompass
- 10; else KompassValue
= 0;
// KompassRichtung = ((540 + KompassValue - KompassSollWert) % 360) - 180;
}
cntKompass
= 0;
}
}
}
// -----------------------------------------------------------------------
unsigned int SetDelay
(unsigned int t
)
{
// TIMSK0 &= ~_BV(TOIE0);
return(CountMilliseconds
+ t
+ 1);
// TIMSK0 |= _BV(TOIE0);
}
// -----------------------------------------------------------------------
char CheckDelay
(unsigned int t
)
{
// TIMSK0 &= ~_BV(TOIE0);
return(((t
- CountMilliseconds
) & 0x8000) >> 9);
// TIMSK0 |= _BV(TOIE0);
}
// -----------------------------------------------------------------------
void Delay_ms
(unsigned int w
)
{
unsigned int akt
;
akt
= SetDelay
(w
);
while (!CheckDelay
(akt
));
}
void Delay_ms_Mess
(unsigned int w
)
{
unsigned int akt
;
akt
= SetDelay
(w
);
while (!CheckDelay
(akt
)) if(AdReady
) {AdReady
= 0; ANALOG_ON
;}
}
/*****************************************************/
/* Initialize Timer 2 */
/*****************************************************/
// The timer 2 is used to generate the PWM at PD7 (J7)
// to control a camera servo for nick compensation.
void TIMER2_Init
(void)
{
uint8_t sreg
= SREG
;
// disable all interrupts before reconfiguration
cli
();
PORTD
&= ~
(1<<PORTD7
); // set PD7 to low
DDRC
|= (1<<DDC6
); // set PC6 as output (Reset for HEF4017)
HEF4017Reset_ON
;
// Timer/Counter 2 Control Register A
// Timer Mode is FastPWM with timer reload at OCR2A (Bits: WGM22 = 1, WGM21 = 1, WGM20 = 1)
// PD7: Normal port operation, OC2A disconnected, (Bits: COM2A1 = 0, COM2A0 = 0)
// PD6: Normal port operation, OC2B disconnected, (Bits: COM2B1 = 0, COM2B0 = 0)
TCCR2A
&= ~
((1<<COM2A1
)|(1<<COM2A0
)|(1<<COM2B1
)|(1<<COM2B0
));
TCCR2A
|= (1<<WGM21
)|(1<<WGM20
);
// Timer/Counter 2 Control Register B
// Set clock divider for timer 2 to SYSKLOCK/32 = 20MHz / 32 = 625 kHz
// The timer increments from 0x00 to 0xFF with an update rate of 625 kHz or 1.6 us
// hence the timer overflow interrupt frequency is 625 kHz / 256 = 2.44 kHz or 0.4096 ms
// divider 32 (Bits: CS022 = 0, CS21 = 1, CS20 = 1)
TCCR2B
&= ~
((1<<FOC2A
)|(1<<FOC2B
)|(1<<CS22
));
TCCR2B
|= (1<<CS21
)|(1<<CS20
)|(1<<WGM22
);
// Initialize the Timer/Counter 2 Register
TCNT2
= 0;
// Initialize the Output Compare Register A used for PWM generation on port PD7.
OCR2A
= 255;
TCCR2A
|= (1<<COM2A1
); // set or clear at compare match depends on value of COM2A0
// Timer/Counter 2 Interrupt Mask Register
// Enable timer output compare match A Interrupt only
TIMSK2
&= ~
((1<<OCIE2B
)|(1<<TOIE2
));
TIMSK2
|= (1<<OCIE2A
);
SREG
= sreg
;
}
//----------------------------
void Timer_Init
(void)
{
tim_main
= SetDelay
(10);
TCCR0B
= CK8
;
// TCCR0A = (1<<COM0A1)|(1<<COM0B1)|3;//fast PWM
TCCR0A
= (1<<COM0A1
)|(1<<COM0B1
)|(1<<COM0B0
)|3;//fast PWM
OCR0B
= 255;
OCR0A
= 180;
TCNT0
= (unsigned char)-TIMER_RELOAD_VALUE
; // reload
//OCR1 = 0x00;
TIMSK0
|= _BV
(TOIE0
);
}
/*****************************************************/
/* Control Servo Position */
/*****************************************************/
void CalcNickServoValue
(void)
{
signed int max
, min
;
if(EE_Parameter.
ServoCompInvert & SERVO_RELATIVE
) // relative moving of the servo value
{
max
= ((unsigned int) EE_Parameter.
ServoNickMax * MULTIPLYER
* 15);
min
= ((unsigned int) EE_Parameter.
ServoNickMin * MULTIPLYER
* 20);
NickServoValue
-= ((signed char) (Parameter_ServoNickControl
- 128) / 4) * 6;
LIMIT_MIN_MAX
(NickServoValue
,min
, max
);
}
else NickServoValue
= (int16_t)Parameter_ServoNickControl
* (MULTIPLYER
*16); // direct poti control
}
void CalculateServo
(void)
{
//signed char cosinus, sinus; // MartinR : so war es
extern signed char cosinus
, sinus
; // MartinR : extern für PAN-Funktion
signed long nick
, roll
;
nick
= 0; // MartinR : StartWert bei abgeschalteten Nick/ Roll ausgleich
roll
= 0; // MartinR : StartWert bei abgeschalteten Nick/ Roll ausgleich
int tmp
; // MartinR : für PAN-Funktion // Wert : 0-24 -> 0-360 -> 15° steps
/* // MartinR: bisher
tmp = EE_Parameter.CamOrientation + ((Parameter_Servo4 - 125) * (Parameter_UserParam8 - 125)) / 400 ; //MartinR : für PAN-Funktion
if (tmp < 0) tmp = 24- (abs(tmp)) % 24 ; // MartinR :Modulo 24
else tmp = tmp % 24 ; // MartinR :Modulo 24
*/
tmp
= EE_Parameter.
CamOrientation + ((Parameter_Servo4
- 125) * (Parameter_UserParam8
- 125)) / 200 ; //MartinR : für PAN-Funktion
if (tmp
< 0) tmp
= 48- (abs(tmp
)) % 48 ; // MartinR :Modulo 48
else tmp
= tmp
% 48 ; // MartinR :Modulo 48
// cosinus = sintab[EE_Parameter.CamOrientation + 6]; // MartinR : so war es
// sinus = sintab[EE_Parameter.CamOrientation]; // MartinR : so war es
//cosinus = sintab[tmp + 6]; // MartinR : für PAN-Funktion
cosinus
+= (2*sintab
[tmp
+ 12]- cosinus
+ 1) / 2; // MartinR : für PAN-Funktion
sinus
+= (2*sintab
[tmp
] - sinus
+ 1) / 2; // MartinR : für PAN-Funktion
if(CalculateServoSignals
== 1)
{
if(EE_Parameter.
GlobalConfig3 & CFG3_SERVO_NICK_COMP_OFF
) nick
= 0;
//else nick = (cosinus * IntegralNick) / 128L - (sinus * IntegralRoll) / 128L; // MartinR: so war es
else nick
= (cosinus
* IntegralNick
) / 512L - (sinus
* IntegralRoll
) / 512L; // MartinR: bessere Auflösung
nick
-= POI_KameraNick
* 7;
nick
= ((long)Parameter_ServoNickComp
* nick
) / 512L;
// offset (Range from 0 to 255 * 3 = 765)
if(EE_Parameter.
ServoCompInvert & SERVO_RELATIVE
) ServoNickOffset
= NickServoValue
;
else ServoNickOffset
+= (NickServoValue
- ServoNickOffset
) / EE_Parameter.
ServoManualControlSpeed;
if(EE_Parameter.
ServoCompInvert & SERVO_NICK_INV
) // inverting movement of servo
{
nick
= ServoNickOffset
/ 16 + nick
;
}
else
{ // inverting movement of servo
nick
= ServoNickOffset
/ 16 - nick
;
}
if(EE_Parameter.
ServoFilterNick) ServoNickValue
= ((ServoNickValue
* EE_Parameter.
ServoFilterNick) + nick
) / (EE_Parameter.
ServoFilterNick + 1);
else ServoNickValue
= nick
;
// limit servo value to its parameter range definition
if(ServoNickValue
< ((int16_t)EE_Parameter.
ServoNickMin * MULTIPLYER
))
{
ServoNickValue
= (int16_t)EE_Parameter.
ServoNickMin * MULTIPLYER
;
}
else
if(ServoNickValue
> ((int16_t)EE_Parameter.
ServoNickMax * MULTIPLYER
))
{
ServoNickValue
= (int16_t)EE_Parameter.
ServoNickMax * MULTIPLYER
;
}
if(PlatinenVersion
< 20) CalculateServoSignals
= 0; else CalculateServoSignals
++;
}
else
{
if(EE_Parameter.
GlobalConfig3 & CFG3_SERVO_NICK_COMP_OFF
) roll
= 0;
//roll = (cosinus * IntegralRoll) / 128L + (sinus * IntegralNick) / 128L; // MartinR: so war es
else roll
= (cosinus
* IntegralRoll
) / 512L + (sinus
* IntegralNick
) / 512L; // MartinR: bessere Auflösung
roll
= ((long)Parameter_ServoRollComp
* roll
) / 512L;
ServoRollOffset
+= ((int16_t)Parameter_ServoRollControl
* (MULTIPLYER
*16) - ServoRollOffset
) / EE_Parameter.
ServoManualControlSpeed;
if(EE_Parameter.
ServoCompInvert & SERVO_ROLL_INV
)
{ // inverting movement of servo
roll
= ServoRollOffset
/ 16 + roll
;
}
else
{ // inverting movement of servo
roll
= ServoRollOffset
/ 16 - roll
;
}
if(EE_Parameter.
ServoFilterRoll) ServoRollValue
= ((ServoRollValue
* EE_Parameter.
ServoFilterRoll) + roll
) / (EE_Parameter.
ServoFilterRoll + 1);
else ServoRollValue
= roll
;
// limit servo value to its parameter range definition
if(ServoRollValue
< ((int16_t)EE_Parameter.
ServoRollMin * MULTIPLYER
))
{
ServoRollValue
= (int16_t)EE_Parameter.
ServoRollMin * MULTIPLYER
;
}
else
if(ServoRollValue
> ((int16_t)EE_Parameter.
ServoRollMax * MULTIPLYER
))
{
ServoRollValue
= (int16_t)EE_Parameter.
ServoRollMax * MULTIPLYER
;
}
// MartinR: Filterung der Pan- Funktion
ServoPanOffset
+= ((int16_t)Parameter_Servo4
* (MULTIPLYER
*16) - ServoPanOffset
) / EE_Parameter.
ServoManualControlSpeed;
ServoPanValue
= (int16_t)ServoPanOffset
/16; // offset (Range from 0 to 255 * 3 = 765)
CalculateServoSignals
= 0;
}
}
ISR
(TIMER2_COMPA_vect
)
{
// frame len 22.5 ms = 14063 * 1.6 us
// stop pulse: 0.3 ms = 188 * 1.6 us
// min servo pulse: 0.6 ms = 375 * 1.6 us
// max servo pulse: 2.4 ms = 1500 * 1.6 us
// resolution: 1500 - 375 = 1125 steps
#define IRS_RUNTIME 127
#define PPM_STOPPULSE 188
#define PPM_FRAMELEN (1757 * EE_Parameter.ServoNickRefresh)
#define MINSERVOPULSE 375
#define MAXSERVOPULSE 1500
#define SERVORANGE (MAXSERVOPULSE - MINSERVOPULSE)
static uint8_t PulseOutput
= 0;
static uint16_t ServoFrameTime
= 0;
static uint8_t ServoIndex
= 0;
if(PlatinenVersion
< 20)
{
//---------------------------
// Nick servo state machine
//---------------------------
if(!PulseOutput
) // pulse output complete
{
if(TCCR2A
& (1<<COM2A0
)) // we had a low pulse
{
TCCR2A
&= ~
(1<<COM2A0
);// make a high pulse
RemainingPulse
= MINSERVOPULSE
+ SERVORANGE
/2; // center position ~ 1.5ms
RemainingPulse
+= ServoNickValue
- (256 / 2) * MULTIPLYER
; // shift ServoNickValue to center position
// range servo pulse width
if(RemainingPulse
> MAXSERVOPULSE
) RemainingPulse
= MAXSERVOPULSE
; // upper servo pulse limit
else if(RemainingPulse
< MINSERVOPULSE
) RemainingPulse
= MINSERVOPULSE
; // lower servo pulse limit
// accumulate time for correct update rate
ServoFrameTime
= RemainingPulse
;
}
else // we had a high pulse
{
TCCR2A
|= (1<<COM2A0
); // make a low pulse
RemainingPulse
= PPM_FRAMELEN
- ServoFrameTime
;
CalculateServoSignals
= 1;
}
// set pulse output active
PulseOutput
= 1;
}
} // EOF Nick servo state machine
else
{
//-----------------------------------------------------
// PPM state machine, onboard demultiplexed by HEF4017
//-----------------------------------------------------
if(!PulseOutput
) // pulse output complete
{
if(TCCR2A
& (1<<COM2A0
)) // we had a low pulse
{
TCCR2A
&= ~
(1<<COM2A0
);// make a high pulse
if(ServoIndex
== 0) // if we are at the sync gap
{
RemainingPulse
= PPM_FRAMELEN
- ServoFrameTime
; // generate sync gap by filling time to full frame time
ServoFrameTime
= 0; // reset servo frame time
HEF4017Reset_ON
; // enable HEF4017 reset
}
else // servo channels
if(ServoIndex
> EE_Parameter.
ServoNickRefresh)
{
RemainingPulse
= 10; // end it here
}
else
{
RemainingPulse
= MINSERVOPULSE
+ SERVORANGE
/2; // center position ~ 1.5ms
switch(ServoIndex
) // map servo channels
{
case 1: // Nick Compensation Servo
RemainingPulse
+= ServoNickValue
- (256 / 2) * MULTIPLYER
; // shift ServoNickValue to center position
break;
case 2: // Roll Compensation Servo
RemainingPulse
+= ServoRollValue
- (256 / 2) * MULTIPLYER
; // shift ServoNickValue to center position
break;
case 3:
RemainingPulse
+= ((int16_t)Parameter_Servo3
* MULTIPLYER
) - (256 / 2) * MULTIPLYER
;
break;
case 4:
//RemainingPulse += ((int16_t)Parameter_Servo4 * MULTIPLYER) - (256 / 2) * MULTIPLYER; // MartinR: so war es
RemainingPulse
+= ServoPanValue
- (256 / 2) * MULTIPLYER
; // MartinR: zur Filterung der Pan-Funktion
break;
case 5:
RemainingPulse
+= ((int16_t)Parameter_Servo5
* MULTIPLYER
) - (256 / 2) * MULTIPLYER
;
break;
default: // other servo channels
RemainingPulse
+= 2 * PPM_in
[ServoIndex
]; // add channel value, factor of 2 because timer 1 increments 3.2µs
break;
}
// range servo pulse width
if(RemainingPulse
> MAXSERVOPULSE
) RemainingPulse
= MAXSERVOPULSE
; // upper servo pulse limit
else if(RemainingPulse
< MINSERVOPULSE
) RemainingPulse
= MINSERVOPULSE
; // lower servo pulse limit
// substract stop pulse width
RemainingPulse
-= PPM_STOPPULSE
;
// accumulate time for correct sync gap
ServoFrameTime
+= RemainingPulse
;
}
}
else // we had a high pulse
{
TCCR2A
|= (1<<COM2A0
); // make a low pulse
// set pulsewidth to stop pulse width
RemainingPulse
= PPM_STOPPULSE
;
// accumulate time for correct sync gap
ServoFrameTime
+= RemainingPulse
;
if((ServoActive
&& SenderOkay
) || ServoActive
== 2) HEF4017Reset_OFF
; // disable HEF4017 reset
else HEF4017Reset_ON
;
ServoIndex
++;
if(ServoIndex
> EE_Parameter.
ServoNickRefresh+1)
{
CalculateServoSignals
= 1;
ServoIndex
= 0; // reset to the sync gap
}
}
// set pulse output active
PulseOutput
= 1;
}
} // EOF PPM state machine
// General pulse output generator
if(RemainingPulse
> (255 + IRS_RUNTIME
))
{
OCR2A
= 255;
RemainingPulse
-= 255;
}
else
{
if(RemainingPulse
> 255) // this is the 2nd last part
{
if((RemainingPulse
- 255) < IRS_RUNTIME
)
{
OCR2A
= 255 - IRS_RUNTIME
;
RemainingPulse
-= 255 - IRS_RUNTIME
;
}
else // last part > ISR_RUNTIME
{
OCR2A
= 255;
RemainingPulse
-= 255;
}
}
else // this is the last part
{
OCR2A
= RemainingPulse
;
RemainingPulse
= 0;
PulseOutput
= 0; // trigger to stop pulse
}
} // EOF general pulse output generator
}