Manchester Code Library

The mikroC PRO for PIC32 provides a library for handling Manchester coded signals. The Manchester code is a code in which data and clock signals are combined to form a single self-synchronizing data stream; each encoded bit contains a transition at the midpoint of a bit period, the direction of transition determines whether the bit is 0 or 1; the second half is the true bit value and the first half is the complement of the true bit value (as shown in the figure below).

Manchester signal format

Important :

The Manchester receive routines are blocking calls (Man_Receive_Init and Man_Synchro). This means that MCU will wait until the task has been performed (e.g. byte is received, synchronization achieved, etc).
Manchester code library implements time-based activities, so interrupts need to be disabled when using it.

External dependencies of Manchester Code Library

The following variables must be defined in all projects using Manchester Code Library:	Description:	Example:
`extern sfr atomic sbit MANRXPIN;`	Receive line.	`sbit MANRXPIN at RF0_bit;`
`extern sfr atomic sbit MANTXPIN;`	Transmit line.	`sbit MANTXPIN at LATF1_bit;`
`extern sfr atomic sbit MANRXPIN_Direction;`	Direction of the Receive pin.	`sbit MANRXPIN_Direction at TRISF0_bit;`
`extern sfr atomic sbit MANTXPIN_Direction;`	Direction of the Transmit pin.	`sbit MANTXPIN_Direction at TRISF1_bit;`

The following routines are for the internal use by compiler only:

Manchester_0
Manchester_1
Manchester_Out

Man_Receive_Init

Prototype	unsigned int Man_Receive_Init();
Description	The function configures Receiver pin. After that, the function performs synchronization procedure in order to retrieve baud rate out of the incoming signal.
Parameters	None.
Returns	`0` - if initialization and synchronization were successful. `1` - upon unsuccessful synchronization. `255` - upon user abort.
Requires	Global variables : `MANRXPIN` : Receive line `MANRXPIN_Direction` : Direction of the receive pin must be defined before using this function.
Example	' Initialize Receiver sbit MANRXPIN at RF0_bit; sbit MANRXPIN_Direction at TRISF0s_bit; ... if (Man_Receive_Init() == 0) { ... }
Notes	In case of multiple persistent errors on reception, the user should call this routine once again or Man_Synchro routine to enable synchronization.

Man_Receive

Prototype	unsigned char Man_Receive(unsigned int *error);
Description	The function extracts one byte from incoming signal.
Parameters	`error:` error flag. If signal format does not match the expected, the `error` flag will be set to non-zero.
Returns	A byte read from the incoming signal.
Requires	To use this function, the user must prepare the MCU for receiving. See Man_Receive_Init routines.
Example	unsigned int data = 0, error = 0; ... data = Man_Receive(&error); if (error) { / error handling / }
Notes	None.

Man_Send_Init

Prototype	void Man_Send_Init();
Description	The function configures Transmitter pin.
Parameters	None.
Returns	Nothing.
Requires	Global variables : `MANTXPIN` : Transmit line `MANTXPIN_Direction` : Direction of the transmit pin must be defined before using this function.
Example	// Initialize Transmitter: sbit MANTXPIN at LATF1_bit; sbit MANTXPIN_Direction at TRISF1_bit; ... Man_Send_Init();
Notes	None.

Man_Send

Prototype	void Man_Send(unsigned char tr_data);
Description	Sends one byte.
Parameters	`tr_data:` data to be sent
Returns	Nothing.
Requires	To use this function, the user must prepare the MCU for sending. See Man_Send_Init routine.
Example	unsigned int msg; ... Man_Send(msg);
Notes	Baud rate used is 500 bps.

Man_Synchro

Prototype	unsigned int Man_Synchro();
Description	Measures half of the manchester bit length with 10us resolution.
Parameters	None.
Returns	`0` - if synchronization was not successful. Half of the manchester bit length, given in multiples of 10us - upon successful synchronization.
Requires	To use this function, you must first prepare the MCU for receiving. See Man_Receive_Init.
Example	unsigned int man__half_bit_len; ... man__half_bit_len = Man_Synchro();
Notes	None.

Man_Break

Prototype	void Man_Break();
Description	Man_Receive is blocking routine and it can block the program flow. Call this routine from interrupt to unblock the program execution. This mechanism is similar to WDT.
Parameters	None.
Returns	Nothing.
Requires	Nothing.
Example	char data1, error, counter = 0; void Timer1Int() org IVT_ADDR_T1INTERRUPT { if (counter >= 20) { Man_Break(); counter = 0; // reset counter } else counter++; // increment counter T1IF_bit = 0; // Clear Timer1 overflow interrupt flag } void main() { ... if (Man_Receive_Init() == 0) { ... } ... // try Man_Receive with blocking prevention mechanism IPC0 = IPC0 \| 0x1000; // Interrupt priority level = 1 T1IE_bit= 1; // Enable Timer1 interrupts T1CON = 0x8030; // Timer1 ON, internal clock FCY, prescaler 1:256 data1 = Man_Receive(&error); T1IE_bit= 0; // Disable Timer1 interrupts }
Notes	Interrupts should be disabled before using Manchester routines again (see note at the top of this page).

Library Example

The following code is code for the Manchester receiver, it shows how to use the Manchester Library for receiving data:

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// LCD module connections
sbit LCD_RS at LATB2_bit;
sbit LCD_EN at LATB3_bit;

sbit LCD_D4 at LATB4_bit;
sbit LCD_D5 at LATB5_bit;
sbit LCD_D6 at LATB6_bit;
sbit LCD_D7 at LATB7_bit;

sbit LCD_RS_Direction at TRISB2_bit;
sbit LCD_EN_Direction at TRISB3_bit;

sbit LCD_D4_Direction at TRISB4_bit;
sbit LCD_D5_Direction at TRISB5_bit;
sbit LCD_D6_Direction at TRISB6_bit;
sbit LCD_D7_Direction at TRISB7_bit;
// End LCD module connections

// Manchester module connections
sbit MANRXPIN at RF0_bit;
sbit MANRXPIN_Direction at TRISF0_bit;
sbit MANTXPIN at LATF1_bit;
sbit MANTXPIN_Direction at TRISF1_bit;
// End Manchester module connections

unsigned int error;
char ErrorCount, chr_counter, byte_rcvd;

void main() {

  ErrorCount = 0;
  chr_counter = 0;
  CHECON = 0x32;
  AD1PCFG = 0xFFFF;                               // Configure AN pins as digital I/O
  TRISB = 0;
  LATB = 0;

  Lcd_Init();                                     // Initialize LCD
  Lcd_Cmd(_LCD_CLEAR);                            // Clear LCD display

  Man_Receive_Init();                             // Initialize Receiver

  while (1) {                                     // Endless loop

      Lcd_Cmd(_LCD_FIRST_ROW);                    // Move cursor to the 1st row

      while (1) {                                 // Wait for the "start" byte
        byte_rcvd = Man_Receive(&error);          // Attempt byte receive
        if (byte_rcvd == 0x0B)                    // "Start" byte, see Transmitter example
          break;                                  // We got the starting sequence
        if (error)                                // Exit so we do not loop forever
          break;
        }

      do
        {
          byte_rcvd = Man_Receive(&error);        // Attempt byte receive
          if (error) {                            // If error occured
            Lcd_Chr_CP('?');                      // Write question mark on LCD
            ErrorCount++;                         // Update error counter
            if (ErrorCount > 20) {                // In case of multiple errors
              Man_Synchro();                      // Try to synchronize again
              //Man_Receive_Init();               // Alternative, try to Initialize Receiver again
              ErrorCount = 0;                     // Reset error counter
              }
            }

          else {                                  // No error occured
            if (byte_rcvd != 0x0E) {              // If "End" byte was received(see Transmitter example)
                                                  // do not write anymore received byte on LCD
              Lcd_Chr_CP(byte_rcvd);              // else write character on LCD
              chr_counter++;                      // Counts how many chars have been written on LCD
              if (chr_counter == 25) {            // If there were more then 25 characters
                                                  // synchronization is off
                Lcd_Cmd(_LCD_CLEAR);              // Clear the LCD of garbled communication
                Man_Synchro();                    // Try to synchronize again
              }
            }
            else
              chr_counter = 0;                    // reset chr_counter
          }

          Delay_ms(25);
        }
      while (byte_rcvd != 0x0E);                  // If "End" byte was received exit do loop
   }
}

The following code is code for the Manchester transmitter, it shows how to use the Manchester Library for transmitting data:

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// Manchester module connections
sbit MANRXPIN at RF0_bit;
sbit MANRXPIN_Direction at TRISF0_bit;
sbit MANTXPIN at LATF1_bit;
sbit MANTXPIN_Direction at TRISF1_bit;
// End Manchester module connections

char index, character;
char s1[] = "mikroElektronika";

void main() {
  CHECON = 0x32;
  AD1PCFG = 0xFFFF;                 // Configure AN pins as digital I/O
  TRISB = 0;
  LATB = 0;

  Man_Send_Init();                 // Initialize transmitter

  while (1) {                      // Endless loop
    Man_Send(0x0B);                // Send "start" byte
    Delay_ms(100);                 // Wait for a while

    character = s1[0];             // Take first char from string
    index = 0;                     // Initialize index variable
    while (character) {            // String ends with zero
      Man_Send(character);         // Send character
      Delay_ms(90);                // Wait for a while
      index++;                     // Increment index variable
      character = s1[index];       // Take next char from string
    }
    Man_Send(0x0E);                // Send "end" byte
    Delay_ms(1000);
  }
}

Connection Example

Simple Transmitter connection

Simple Receiver connection

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