For radio receiver, there are a few output signal formats. The traditional and also most common type of RX signal is the PWM and basically PWM requires 1 cable per channel. PPM is now getting more and more popular, because it can handle all 8 channels in 1 signal wire.
Find out more detail on radio receiver signal types.
You can buy a commercially ready PWM to PPM converter (which also does SBUS output as well). But for those who enjoy tinkering and DIY, here is a fun project for you.
Al Prettybong on Multicopter International Group shared with me how he made a PWM to PPM converter using an Arduino Pro Mini, and I thought I should share this with everyone.
I haven’t tested this code yet, but Al told me there is NO changes to the code, just copy and upload it to your Arduino and it will work.
Here is the main sketch.
// ------------------------------------------------------------------------------------------------------------------------------------------------------------ // 8 Channel PWM to 1 channel PPM converter for RC receivers, using Arduino // // // ..and has been hacked code to: // only support Atmel328 chips ( as found on Arduino Duemilanove or Arduino Uno ) chips // not support any "error" mode/s, just 8 PWM-IN channels TO one single PPM OUT // not support any LED indicators m just PWM-IN, and PPM-OUT // Integrated the one library that is used to the sketch, for easy user experience. // made it Arduino IDE compatible, so it uses standard bootloader and Serial uploader, like all realy Arduino/s. // make compile-time option to either "hold last good PPM value" or "hold default value/s" in case of // no actual input signal for each channel. see FAILHOLD and FAILCENTRE in .h file // . // ------------------------------------------------------------------------------------------------------------------------------------------------------------ // PREPROCESSOR DIRECTIVES // ------------------------------------------------------------------------------------------------------------------------------------------------------------ #include "Arduino.h" #include "ppm_encoder.h" #include <util/delay.h> #include <avr/io.h> #define ERROR_THRESHOLD 2 // Number of servo input errors before alerting #define ERROR_DETECTION_WINDOW 3000 * LOOP_TIMER_10MS // Detection window for error detection (default to 30s) #define ERROR_CONDITION_DELAY 500 * LOOP_TIMER_10MS // Servo error condition LED delay (LED blinking duration) #define PASSTHROUGH_MODE_ENABLED // Comment this line to remove CH8 radio passthrough mode support (hardware failsafe for Arduplane) #define PASSTHROUGH_CHANNEL 8 * 2 // Channel for passthrough mode selection #define PASSTHROUGH_CHANNEL_OFF_US ONE_US * 1600 - PPM_PRE_PULSE // Passthrough off threshold #define PASSTHROUGH_CHANNEL_ON_US ONE_US * 1800 - PPM_PRE_PULSE // Passthrough on threshold #define THROTTLE_CHANNEL 3 * 2 // Throttle Channel #define THROTTLE_CHANNEL_LED_TOGGLE_US ONE_US * 1200 - PPM_PRE_PULSE // Throttle Channel Led toggle threshold #define LED_LOW_BLINKING_RATE 125 * LOOP_TIMER_10MS // Led blink rate for low throttle position (half period) // Timers #define TIMER0_10MS 156 // Timer0 ticks for 10 ms duration #define TIMER1_10MS 20000 // Timer1 ticks for 10 ms duration #define TIMER2_100MS 1562 // Timer2 ticks for 100 ms duration #define LOOP_TIMER_10MS 10 // Loop timer ticks for 10 ms duration // LED Code #define SPACE_SHORT_DURATION 40 * LOOP_TIMER_10MS // Space after short symbol #define SPACE_LONG_DURATION 75 * LOOP_TIMER_10MS // Space after long symbol #define SYMBOL_SHORT_DURATION 20 * LOOP_TIMER_10MS // Short symbol duration #define SYMBOL_LONG_DURATION 100 * LOOP_TIMER_10MS // Long symbol duration #define INTER_CODE_DURATION 150 * LOOP_TIMER_10MS // Inter code duration #define INTER_CODE 0 // Symbols value for coding #define SHORT_SYMBOL 1 #define LONG_SYMBOL 2 #define SHORT_SPACE 3 #define LONG_SPACE 4 #define LOOP 5 // ------------------------------------------------------------------------------------------------------------------------------------------------------------ // PPM ENCODER INIT AND AUXILIARY TASKS // ------------------------------------------------------------------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------------------------------------------------------------------------------------ // LOCAL VARIABLES // ------------------------------------------------------------------------------------------------------------------------------------------------------------ bool localinit = true; // We are inside init sequence bool mux_passthrough = false; // Mux passthrough mode status Flag : passthrough is off uint16_t led_acceleration; // Led acceleration based on throttle stick position bool servo_error_condition = false; // Servo signal error condition static uint16_t servo_error_detection_timer=0; // Servo error detection timer static uint16_t servo_error_condition_timer=0; // Servo error condition timer static uint16_t blink_led_timer = 0; // Blink led timer #ifdef PASSTHROUGH_MODE_ENABLED static uint8_t mux_timer = 0; // Mux timer static uint8_t mux_counter = 0; // Mux counter static int8_t mux_check = 0; static uint16_t mux_ppm = 500; #endif static uint16_t led_code_timer = 0; // Blink Code Timer static uint8_t led_code_symbol = 0; // Blink Code current symbol // ------------------------------------------------------------------------------------------------------------------------------------------------------------ // LOCAL FUNCTIONS // ------------------------------------------------------------------------------------------------------------------------------------------------------------ // ------------------------------------------------------------------------------ // Led blinking (non blocking) function // ------------------------------------------------------------------------------ uint8_t blink_led ( uint16_t half_period ) // ( half_period max = 65 s ) { blink_led_timer++; if ( blink_led_timer < half_period ) // If half period has not been reached { return 0; // Exit timer function and return 0 } else // half period reached - LED Toggle { PPM_PORT ^= ( 1 << PB0 ); // Toggle status LED blink_led_timer = 0; // Blink led timer reset return 1; // half period reached - Exit timer function and return 1 } } // ------------------------------------------------------------------------------ // Led code (non blocking) function // ------------------------------------------------------------------------------ void blink_code_led ( uint8_t code ) { const uint8_t coding[2][14] = { // PPM_PASSTROUGH_MODE { INTER_CODE, LONG_SYMBOL, LONG_SPACE, SHORT_SYMBOL, SHORT_SPACE, SHORT_SYMBOL, LOOP }, // JETI_MODE { INTER_CODE, LONG_SYMBOL, LONG_SPACE, SHORT_SYMBOL, SHORT_SPACE, SHORT_SYMBOL, SHORT_SPACE, SHORT_SYMBOL,LOOP } }; led_code_timer++; switch ( coding [ code - 2 ] [ led_code_symbol ] ) { case INTER_CODE: if ( led_code_timer < ( INTER_CODE_DURATION ) ) return; else PPM_PORT |= ( 1 << PB0 ); // Enable status LED break; case LONG_SYMBOL: // Long symbol if ( led_code_timer < ( SYMBOL_LONG_DURATION ) ) return; else PPM_PORT &= ~( 1 << PB0 ); // Disable status LED break; case SHORT_SYMBOL: // Short symbol if ( led_code_timer < ( SYMBOL_SHORT_DURATION ) ) return; else PPM_PORT &= ~( 1 << PB0 ); // Disable status LED break; case SHORT_SPACE: // Short space if ( led_code_timer < ( SPACE_SHORT_DURATION ) ) return; else PPM_PORT |= ( 1 << PB0 ); // Enable status LED break; case LONG_SPACE: // Long space if ( led_code_timer < ( SPACE_LONG_DURATION ) ) return; else PPM_PORT |= ( 1 << PB0 ); // Enable status LED break; case LOOP: // Loop to code start led_code_symbol = 0; return; break; } led_code_timer = 0; // Code led timer reset led_code_symbol++; // Next symbol return; // LED code function return } // ------------------------------------------------------------------------------ // ppm reading helper - interrupt safe and non blocking function // ------------------------------------------------------------------------------ uint16_t ppm_read( uint8_t channel ) { uint16_t ppm_tmp = ppm[ channel ]; while( ppm_tmp != ppm[ channel ] ) ppm_tmp = ppm[ channel ]; return ppm_tmp; } // ------------------------------------------------------------------------------------------------------------------------------------------------------------ // INITIALISATION CODE // ------------------------------------------------------------------------------------------------------------------------------------------------------------ void setup() { // ------------------------------------------------------------------------------ // Reset Source checkings // ------------------------------------------------------------------------------ if (MCUSR & 1) // Power-on Reset { MCUSR=0; // Clear MCU Status register // custom code here } else if (MCUSR & 2) // External Reset { MCUSR=0; // Clear MCU Status register // custom code here } else if (MCUSR & 4) // Brown-Out Reset { MCUSR=0; // Clear MCU Status register brownout_reset=true; } else // Watchdog Reset { MCUSR=0; // Clear MCU Status register // custom code here } // ------------------------------------------------------------------------------ // Servo input and PPM generator init // ------------------------------------------------------------------------------ ppm_encoder_init(); // ------------------------------------------------------------------------------ // Outputs init // ------------------------------------------------------------------------------ PPM_DDR |= ( 1 << PB0 ); // Set LED pin (PB0) to output PPM_DDR |= ( 1 << PB1 ); // Set MUX pin (PB1) to output PPM_DDR |= ( 1 << PPM_OUTPUT_PIN ); // Set PPM pin (PPM_OUTPUT_PIN, OC1B) to output // ------------------------------------------------------------------------------ // Timer0 init (normal mode) used for LED control and custom code // ------------------------------------------------------------------------------ TCCR0A = 0x00; // Clock source: System Clock TCCR0B = 0x05; // Set 1024x prescaler - Clock value: 15.625 kHz - 16 ms max time TCNT0 = 0x00; OCR0A = 0x00; // OC0x outputs: Disconnected OCR0B = 0x00; TIMSK0 = 0x00; // Timer 1 interrupt disable // ------------------------------------------------------------------------------ // Enable global interrupt // ------------------------------------------------------------------------------ sei(); // Enable Global interrupt flag // ------------------------------------------------------------------------------ // Disable radio passthrough (mux chip A/B control) // ------------------------------------------------------------------------------ PPM_PORT |= ( 1 << PB1 ); // Set PIN B1 to disable Radio passthrough (mux) } void loop() { // ------------------------------------------------------------------------------------------------------------------------------------------------------------ // AUXILIARY TASKS // ------------------------------------------------------------------------------------------------------------------------------------------------------------ PWM_LOOP: // SERVO_PWM_MODE while( 1 ) { _delay_us (950); // Slow down while loop } // PWM Loop end } // main lopo function end
And then create a new tab in your Arduino IDE and copy this, name it “ppm_encoder.h”, and copy the following code in the tab.
// ------------------------------------------------------------- #ifndef _PPM_ENCODER_H_ #define _PPM_ENCODER_H_ #include <avr/io.h> // ------------------------------------------------------------- #include <avr/interrupt.h> #include <avr/wdt.h> #include <util/delay.h> // ------------------------------------------------------------- // SERVO INPUT FILTERS // ------------------------------------------------------------- // Using both filters is not recommended and may reduce servo input resolution // #define _AVERAGE_FILTER_ // Average filter to smooth servo input capture jitter // #define _JITTER_FILTER_ // Cut filter to remove 0,5us servo input capture jitter // ------------------------------------------------------------- #ifndef F_CPU #define F_CPU 16000000UL #endif #ifndef true #define true 1 #endif #ifndef false #define false 0 #endif //#ifndef bool //#define bool boolean //#endif // 328 does not define PBX but defines an equivalent as PORTBX, comment these lines out if you already have a PB2 defined. #define PB2 PORTB2 #define PB1 PORTB1 #define PB0 PORTB0 // ------------------------------------------------------------- // SERVO INPUT MODE - !EXPERIMENTAL! // ------------------------------------------------------------- #define SERVO_PWM_MODE 1 // Normal 8 channel servo (pwm) input // Servo input mode (jumper (default), pwm, ppm, jeti or spektrum) volatile uint8_t servo_input_mode = SERVO_PWM_MODE; // ------------------------------------------------------------- // Number of Timer1 ticks in one microsecond #define ONE_US F_CPU / 8 / 1000 / 1000 // 400us PPM pre pulse #define PPM_PRE_PULSE ONE_US * 400 // ------------------------------------------------------------- // SERVO LIMIT VALUES // ------------------------------------------------------------- // Servo minimum position #define PPM_SERVO_MIN ONE_US * 900 - PPM_PRE_PULSE // Servo center position #define PPM_SERVO_CENTER ONE_US * 1500 - PPM_PRE_PULSE // Servo maximum position #define PPM_SERVO_MAX ONE_US * 2100 - PPM_PRE_PULSE // Throttle default at power on #define PPM_THROTTLE_DEFAULT ONE_US * 1100 - PPM_PRE_PULSE // Throttle during failsafe #define PPM_THROTTLE_FAILSAFE ONE_US * 900 - PPM_PRE_PULSE // CH5 power on values (mode selection channel) //#define PPM_CH5_MODE_4 ONE_US * 1555 - PPM_PRE_PULSE // ------------------------------------------------------------- // Number of servo input channels #define SERVO_CHANNELS 8 // PPM period 18.5ms - 26.5ms (54hz - 37Hz) #define PPM_PERIOD ONE_US * ( 22500 - ( 8 * 1500 ) ) // Size of ppm[..] data array ( servo channels * 2 + 2) #define PPM_ARRAY_MAX 18 // Data array for storing ppm (8 channels) pulse widths. volatile uint16_t ppm[ PPM_ARRAY_MAX ] = { PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 1 PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 2 PPM_PRE_PULSE, PPM_THROTTLE_DEFAULT, // Channel 3 (throttle) PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 4 PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 5 PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 6 PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 7 PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 8 PPM_PRE_PULSE, PPM_PERIOD }; // ------------------------------------------------------------- // SERVO FAILSAFE VALUES // ------------------------------------------------------------- const uint16_t failsafe_ppm[ PPM_ARRAY_MAX ] = { PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 1 PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 2 PPM_PRE_PULSE, PPM_THROTTLE_FAILSAFE, // Channel 3 (throttle) PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 4 PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 5 PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 6 PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 7 PPM_PRE_PULSE, PPM_SERVO_CENTER, // Channel 8 PPM_PRE_PULSE, PPM_PERIOD }; // ------------------------------------------------------------- // AVR parameters for ArduPilot MEGA v1.4 PPM Encoder (ATmega328P) #if defined (__AVR_ATmega328P__) || defined (__AVR_ATmega328__) #define SERVO_DDR DDRD #define SERVO_PORT PORTD #define SERVO_INPUT PIND // PCIE2 PC Interrupt enable 2 is for Arduino Pins (D0-D7), also called PORTD. #define SERVO_INT_VECTOR PCINT2_vect #define SERVO_INT_MASK PCMSK2 #define SERVO_INT_CLEAR_FLAG PCIF2 #define SERVO_INT_ENABLE PCIE2 #define SERVO_TIMER_CNT TCNT1 #define PPM_DDR DDRB #define PPM_PORT PORTB #define PPM_OUTPUT_PIN PB2 #define PPM_INT_VECTOR TIMER1_COMPB_vect #define PPM_COMPARE OCR1B #define PPM_COMPARE_FLAG COM1B0 #define PPM_COMPARE_ENABLE OCIE1B #else #error NO SUPPORTED DEVICE FOUND! ( ATmega328/p) #endif // Used to indicate invalid SERVO input signals //volatile uint8_t servo_input_errors = 0; // Used to indicate missing SERVO input signals volatile bool servo_input_missing = true; // Used to indicate if PPM generator is active volatile bool ppm_generator_active = false; // Used to indicate a brownout restart volatile bool brownout_reset = false; // ------------------------------------------------------------------------------ // PPM GENERATOR START - TOGGLE ON COMPARE INTERRUPT ENABLE // ------------------------------------------------------------------------------ // this starts OUTGOING PPM stream on PPM_PORT (PORTB, Arduino D8-D13) at PPM_OUTPUT_PIN (PB2, arduino pin D10) void ppm_start( void ) { // Prevent reenabling an already active PPM generator if( ppm_generator_active ) return; // Store interrupt status and register flags uint8_t SREG_tmp = SREG; // Stop interrupts cli(); // Make sure initial output state is low PPM_PORT &= ~(1 << PPM_OUTPUT_PIN); // Wait for output pin to settle //_delay_us( 1 ); // Set initial compare toggle to maximum (32ms) to give other parts of the system time to start SERVO_TIMER_CNT = 0; PPM_COMPARE = 0xFFFF; // Set toggle on compare output TCCR1A = (1 << PPM_COMPARE_FLAG); // Set TIMER1 8x prescaler TCCR1B = ( 1 << CS11 ); // Enable output compare interrupt TIMSK1 |= (1 << PPM_COMPARE_ENABLE); // Indicate that PPM generator is active ppm_generator_active = true; // Restore interrupt status and register flags SREG = SREG_tmp; } // ------------------------------------------------------------------------------ // PPM GENERATOR STOP - TOGGLE ON COMPARE INTERRUPT DISABLE // ------------------------------------------------------------------------------ void ppm_stop( void ) { // Store interrupt status and register flags uint8_t SREG_tmp = SREG; // Stop interrupts cli(); // Disable output compare interrupt TIMSK1 &= ~(1 << PPM_COMPARE_ENABLE); // Reset TIMER1 registers TCCR1A = 0; TCCR1B = 0; // Indicate that PPM generator is not active ppm_generator_active = false; // Restore interrupt status and register flags SREG = SREG_tmp; } // ------------------------------------------------------------------------------ // Watchdog Interrupt (interrupt only mode, no reset) // ------------------------------------------------------------------------------ ISR( WDT_vect ) // If watchdog is triggered then enable missing signal flag and copy power on or failsafe positions { // Use failsafe values if PPM generator is active or if chip has been reset from a brown-out if ( ppm_generator_active || brownout_reset ) { // Copy failsafe values to ppm[..] for ( uint8_t i = 0; i < PPM_ARRAY_MAX; i++ ) { ppm[ i ] = failsafe_ppm[ i ]; } } // Set missing receiver signal flag servo_input_missing = true; // Reset servo input error flag //servo_input_errors = 0; } // ------------------------------------------------------------------------------ // ------------------------------------------------------------------------------ // SERVO/PPM INPUT - PIN CHANGE INTERRUPT, for any Arduino pin D0 -> D7 // ------------------------------------------------------------------------------ ISR( SERVO_INT_VECTOR ) { // Servo pulse start timing static uint16_t servo_start[ SERVO_CHANNELS ] = { 0, 0, 0, 0, 0, 0, 0, 0 }; // Missing throttle signal failsafe static uint8_t throttle_timeout = 0; // Servo input pin storage static uint8_t servo_pins_old = 0; // Used to store current servo input pins uint8_t servo_pins; // Read current servo pulse change time uint16_t servo_time = SERVO_TIMER_CNT; // ------------------------------------------------------------------------------ // SERVO PWM MODE // ------------------------------------------------------------------------------ CHECK_PINS_START: // Start of servo input check // Store current servo input pins servo_pins = SERVO_INPUT; // Calculate servo input pin change mask uint8_t servo_change = servo_pins ^ servo_pins_old; // Set initial servo pin and channel uint8_t servo_pin = 1; uint8_t servo_channel = 0; CHECK_PINS_LOOP: // Input servo pin check loop // Check for pin change on current servo channel if( servo_change & servo_pin ) { // if (( servo_pin == 1 ) && ( ppm_generator_active = false) ) ppm_start(); // if (( servo_pin == 8 ) && ( ppm_generator_active = true) ) ppm_stop(); // High (raising edge) if( servo_pins & servo_pin ) { servo_start[ servo_channel ] = servo_time; } else { // Get servo pulse width uint16_t servo_width = servo_time - servo_start[ servo_channel ] - PPM_PRE_PULSE; // Calculate servo channel position in ppm[..] uint8_t _ppm_channel = ( servo_channel << 1 ) + 1; // Check that servo pulse signal is valid before sending to ppm encoder if( servo_width > PPM_SERVO_MAX ) goto CHECK_PINS_ERROR; if( servo_width < PPM_SERVO_MIN ) goto CHECK_PINS_ERROR; goto CHECK_PINS_NOERROR; CHECK_PINS_ERROR: // on width input error, use defailt/failsave value, OR previous value // choose the error handling type here! #define FAILCENTRE 1 #ifdef FAILCENTRE servo_width = failsafe_ppm[ _ppm_channel ]; // failsafe defaults, most channels centred, throttle lowered. #endif #ifdef FAILHOLD servo_width = ppm[ _ppm_channel ]; // all channels hold their previous position! #endif CHECK_PINS_NOERROR: //Reset throttle failsafe timeout if( _ppm_channel == 5 ) throttle_timeout = 0; #ifdef _AVERAGE_FILTER_ // Average filter to smooth input jitter servo_width += ppm[ _ppm_channel ]; servo_width >>= 1; #endif #ifdef _JITTER_FILTER_ // 0.5us cut filter to remove input jitter int16_t ppm_tmp = ppm[ _ppm_channel ] - servo_width; if( ppm_tmp == 1 ) goto CHECK_PINS_NEXT; if( ppm_tmp == -1 ) goto CHECK_PINS_NEXT; #endif // Update ppm[..] ppm[ _ppm_channel ] = servo_width; } } CHECK_PINS_NEXT: // Select next servo pin servo_pin <<= 1; // Select next servo channel servo_channel++; // Check channel and process if needed if( servo_channel < SERVO_CHANNELS ) goto CHECK_PINS_LOOP; goto CHECK_PINS_DONE; // All servo input pins has now been processed CHECK_PINS_DONE: // Reset Watchdog Timer wdt_reset(); // Set servo input missing flag false to indicate that we have received servo input signals servo_input_missing = false; // Store current servo input pins for next check servo_pins_old = servo_pins; // Start PPM generator if not already running if( ppm_generator_active == false ) ppm_start(); // Throttle failsafe if( throttle_timeout++ >= 128 ) { // Reset throttle timeout throttle_timeout = 0; // Set throttle failsafe value ppm[ 5 ] = PPM_THROTTLE_FAILSAFE; } //Has servo input changed while processing pins, if so we need to re-check pins if( servo_pins != SERVO_INPUT ) goto CHECK_PINS_START; // Clear interrupt event from already processed pin changes PCIFR |= (1 << SERVO_INT_CLEAR_FLAG); } // ------------------------------------------------------------------------------ // ------------------------------------------------------------------------------ // PPM OUTPUT - TIMER1 COMPARE INTERRUPT // ------------------------------------------------------------------------------ ISR( PPM_INT_VECTOR ) { // Current active ppm channel static uint8_t ppm_channel = PPM_ARRAY_MAX - 1; // Update timing for next compare toggle PPM_COMPARE += ppm[ ppm_channel ]; // Select the next ppm channel if( ++ppm_channel >= PPM_ARRAY_MAX ) { ppm_channel = 0; } } // ------------------------------------------------------------------------------ // ------------------------------------------------------------------------------ // PPM READ - INTERRUPT SAFE PPM SERVO CHANNEL READ // ------------------------------------------------------------------------------ /* uint16_t ppm_read_channel( uint8_t channel ) { // Limit channel to valid value uint8_t _channel = channel; if( _channel == 0 ) _channel = 1; if( _channel > SERVO_CHANNELS ) _channel = SERVO_CHANNELS; // Calculate ppm[..] position uint8_t ppm_index = ( _channel << 1 ) + 1; // Read ppm[..] in a non blocking interrupt safe manner uint16_t ppm_tmp = ppm[ ppm_index ]; while( ppm_tmp != ppm[ ppm_index ] ) ppm_tmp = ppm[ ppm_index ]; // Return as normal servo value return ppm_tmp + PPM_PRE_PULSE; } */ // ------------------------------------------------------------------------------ // ------------------------------------------------------------------------------ // PPM ENCODER INIT // ------------------------------------------------------------------------------ void ppm_encoder_init( void ) { // SERVO/PPM INPUT PINS // ------------------------------------------------------------------------------ // Set all servo input pins to inputs SERVO_DDR = 0; // Activate pullups on all input pins SERVO_PORT |= 0xFF; // SERVO/PPM INPUT - PIN CHANGE INTERRUPT // ------------------------------------------------------------------------------ if( servo_input_mode == SERVO_PWM_MODE ) { // Set servo input interrupt pin mask to all 8 servo input channels SERVO_INT_MASK = 0xFF; } // Enable servo input interrupt PCICR |= (1 << SERVO_INT_ENABLE); // PPM OUTPUT PIN // ------------------------------------------------------------------------------ // Set PPM pin to output PPM_DDR |= (1 << PPM_OUTPUT_PIN); // ------------------------------------------------------------------------------ // Enable watchdog interrupt mode // ------------------------------------------------------------------------------ // Disable watchdog wdt_disable(); // Reset watchdog timer wdt_reset(); // Start timed watchdog setup sequence WDTCSR |= (1<<WDCE) | (1<<WDE ); // Set 250 ms watchdog timeout and enable interrupt WDTCSR = (1<<WDIE) | (1<<WDP2); } // ——————————————————————————
The connection is really simple.
5V and GND on receiver is connected to “RAW” and GND pins on the Arduino board. Ch1 to Ch8 is connected D0 to D7 on the Arduino. (if you are using receiver that has fewer channels, you don’t have to worry about the rest of the pins on the Arduino)
For a more detail connection diagram, check out the top picture in this article.
He removed all the servo pins on this receiver, and soldered direct the arduino pwm to ppm converter. He said this has been running successfully for about 8 months, and i did the same conversion on an 8 channel receiver also has failsafe built in to the pwm ppm converter. Failsafe channel can be set up in the code.
There are 3 wires that will be connected to the FC, 5V, GND and PPM (Green).
And finally he put heatshrink over this unit, and now this cheap PWM RX has turned into a powerful PPM RX 🙂 He put clear heatshrink in the middle so he could see the status LEDs.
I haven’t done this project myself yet, but if you have any questions about this project, please join Multicopter International, and ask Al himself.
This article is written by Oscar at his Blog.