Objective

In this tutorial we are going to discuss the serial communication using UART. For more info on UART/RS232 check 8051 tutorial.
LPC1768 has four inbuilt USARTs. We are going to discuss only UART0. After this tutorial you should be able to extend it to remaining three UARTS.
After understating the basics of LPC1768 UART module, We will discuss how to use the ExploreEmbedded libraries to communicate with any of the UART devices.



UART module

UART module and registers. LPC1768 has 4-UARTs numbering 0-3, similarly the pins are also named as RXD0-RXD3 and TXD0-TXD3. As the LPC1768 pins are multiplexed for multiple functionalities, first they have to be configured as UART pins.
Below table shows the multiplexed UARTs pins.

Port Pin Pin Number PINSEL_FUNC_0 PINSEL_FUNC_1 PINSEL_FUNC_2 PINSEL_FUNC_3
P0.02 98 GPIO TXD0 ADC0[7]
P0.03 99 GPIO RXD0 ADC0[6]
p2.00 75 GPIO PWM1[1] TXD1
P2.01 74 GPIO PWM1[2] RXD1
P0.10 48 GPIO TXD2 SDA2 MAT3[0]
P0.11 49 GPIO RXD2 SCL2 MAT3[1]
P4.28 82 GPIO RX_MCLK MAT2[0] TXD3
P4.29 85 GPIO TX_MCLK MAT2[1] RXD3



UART Registers

The below table shows the registers associated with LPC1768 ADC.
We are going to focus only on ADCR and ADGDR as these are sufficient for simple A/D conversion.
However once you are familer with LPC1768 ADC, you can explore the other features and the associated registers.

Register Description
RBR Contains the recently received Data
THR Contains the data to be transmitted
FCR FIFO Control Register
LCR Controls the UART frame formatting(Number of Data Bits, Stop bits)
DLL Least Significant Byte of the UART baud rate generator value.
DLM Most Significant Byte of the UART baud rate generator value.

UART Register Configuration

Now lets see how to configure the individual registers for UART communication.

FCR ( FIFO Control Register )

LPC1768 has inbuilt 16byte FIFO for Receiver/Transmitter. Thus it can store 16-bytes of data received on UART without overwriting. If the data is not read before the Queue(FIFO) is filled then the new data will be lost and the OVERRUN error bit will set.

ADCR
31:8 7:6 5:4 3 2 1 0
RESERVED RX TRIGGER RESERVED DMA MODE TX RIFO RESET RX RIFO RESET FIFO ENABLE

Bit 0 – FIFO:
This bit is used to enable/disable the FIFO for the data received/transmitted.
0--FIFO is Disabled.
1--FIFO is Enabled for both Rx and Tx.

Bit 1 – RX_FIFO:
This is used to clear the 16-byte Rx FIFO.
0--No impact.
1--CLears the 16-byte Rx FIFO and the resets the FIFO pointer.

Bit 2 – Tx_FIFO:
This is used to clear the 16-byte Tx FIFO.
0--No impact.
1--Clears the 16-byte Tx FIFO and the resets the FIFO pointer.

Bit 3 – DMA_MODE:
This is used for Enabling/Disabling DMA mode.
0--Disables the DMA.
1--Enables DMA only when the FIFO(bit-0) bit is SET.

Bit 7:6 – Rx_TRIGGER:
This bit is used to select the number of bytes of the receiver data to be written so as to enable the interrupt/DMA.
00-- Trigger level 0 (1 character or 0x01)
01-- Trigger level 1 (4 characters or 0x04)
10-- Trigger level 2 (8 characters or 0x08)
11-- Trigger level 3 (14 characters or 0x0E)



LCR ( Line Control Register )

This register is used for defining the UART frame format ie. Number of Data bits, STOP bits etc.

LCR
31:8 7 6 5:4 3 2 1:0
Reserved DLAB Break COntrol Parity Select Parity Enable Stop Bit Select Word Length Select

Bit 1:0 – WLS : WordLenghtSelect
These two bits are used to select the character length
00-- 5-bit character length
01-- 6-bit character length
10-- 7-bit character length
11-- 8-bit character length

Bit 2 – Stop Bit Selection:
This bit is used to select the number(1/2) of stop bits
0-- 1 Stop bit
1-- 2 Stop Bits

Bit 3 – Parity Enable:
This bit is used to Enable or Disable the Parity generation and checking.
0-- Disable parity generation and checking.
1-- Enable parity generation and checking.

Bit 5:4 – Parity Selection:
These two bits will be used to select the type of parity.
00-- Odd parity. Number of 1s in the transmitted character and the attached parity bit will be odd.
01-- Even Parity. Number of 1s in the transmitted character and the attached parity bit will be even.
10-- Forced "1" stick parity.
11-- Forced "0" stick parity

Bit 6 – Break Control
0-- Disable break transmission.
1-- Enable break transmission. Output pin UARTn TXD is forced to logic 0


Bit 8 – DLAB: Divisor Latch Access Bit
This bit is used to enable the access to divisor latch.
0-- Disable access to divisor latch
0-- Enable access to divisor latch



LSR (Line Status Register)

The is a read-only register that provides status information of the UART TX and RX blocks.

LSR
31:8 7 6 5 4 3 2 1 0
Reserved RXFE TEMT THRE BI FE PE OE RDR

Bit 0 – RDR: Receive Data Ready
This bit will be set when there is a received data in RBR register. This bit will be automatically cleared when RBR is empty.
0-- The UARTn receiver FIFO is empty.
1-- The UARTn receiver FIFO is not empty.

Bit 1 – OE: Overrun Error
The overrun error condition is set when the UART Rx FIFO is full and a new character is received. In this case, the UARTn RBR FIFO will not be overwritten and the character in the UARTn RSR will be lost.
0-- No overrun
1-- Buffer over run

Bit 2 – PE: Parity Error
This bit is set when the receiver detects a error in the Parity.
0-- No Parity Error
1-- Parity Error

Bit 3 – FE: Framing Error
This bit is set when there is error in the STOP bit(LOGIC 0)
0-- No Framing Error
1-- Framing Error

Bit 4 – BI: Break Interrupt
This bit is set when the RXDn is held in the spacing state (all zeroes) for one full character transmission
0-- No Break interrupt
1-- Break Interrupt detected.

Bit 5 – THRE: Transmitter Holding Register Empty
THRE is set immediately upon detection of an empty THR. It is automatically cleared when the THR is written.
0-- THR register is Empty
1-- THR has valid data to be transmitted

Bit 6 – TEMT: Transmitter Empty
TEMT is set when both UnTHR and UnTSR are empty; TEMT is cleared when any of them contain valid data.
0-- THR and/or the TSR contains valid data.
1-- THR and the TSR are empty.


Bit 7 – RXFE: Error in Rx FIFO
This bit is set when the received data is affected by Framing Error/Parity Error/Break Error.
0-- RBR contains no UARTn RX errors.
1-- RBR contains at least one RX error.



TER (Transmitter Enable register)

This register is used to Enable/Disable the transmission

TER
31:8 7 6-0
Reserved TXEN Reserved


Bit 7 – TXEN: Trsnamitter Enable
When this bit is 1, the data written to the THR is output on the TXD pin.
If this bit is cleared to 0 while a character is being sent, the transmission of that character is completed, but no further characters are sent until this bit is set again.
In other words, a 0 in this bit blocks the transfer of characters.

  • Note: By default this bit will be set after Reset.


Some other registers

Though there are some more registers, we are restricting ourselves to use these registers only as this will be more convenient.

Apart from ADC Global Data register there are more 8 ADC Data registers (one Data register per ADC channel). DONE and OVERRUN bits for each channel can be monitored separately from the bits present in ADC Status register.

One can use the A/D Global Data Register to read all data from the ADC else use the A/D Channel Data Registers. It is important to use one method consistently because the DONE and OVERRUN flags can otherwise get out of synch between the AD0GDR and the A/D Channel Data Registers, potentially causing erroneous interrupts or DMA activity.

Schematic

Schematic



Steps for Configuring UART0

Below are the steps for configuring the UART0.

  1. Step1: Configure the GPIO pin for UART0 function using PINSEL register.
  2. Step2: Configure the FCR for enabling the FIXO and Reste both the Rx/Tx FIFO.
  3. Step3: Configure LCR for 8-data bits, 1 Stop bit, Disable Parity and Enable DLAB.
  4. Step4: Get the PCLK from PCLKSELx register 7-6 bits.
  5. Step5: Calculate the DLM,DLL vaues for required baudrate from PCLK.
  6. Step6: Updtae the DLM,DLL with the calculated values.
  7. Step6: Finally clear DLAB to disable the access to DLM,DLL.

After this the UART will be ready to Transmit/Receive Data at the specified baudrate.

Code sniffet:

void uart_init(uint32_t baudrate)
{
    uint32_t var_UartPclk_u32,var_Pclk_u32,var_RegValue_u32;
 
	LPC_PINCON->PINSEL0 &= ~0x000000F0;
	LPC_PINCON->PINSEL0 |= 0x00000050;			// Enable TxD0 P0.2 and p0.3 
 
        LPC_UART0->FCR = (1<<SBIT_FIFO) | (1<<SBIT_RxFIFO) | (1<<Tx_FIFO); // Enable FIFO and reset Rx/Tx FIFO buffers	
	LPC_UART0->LCR = (0x03<<SBIT_WordLenght) | (1<<SBIT_DLAB); // 8bit data, 1Stop bit, No parity
 
 
	/** Baud Rate Calculation :
	   PCLKSELx registers contains the PCLK info for all the clock dependent peripherals.
	   Bit6,Bit7 contains the Uart Clock(ie.UART_PCLK) information.
	   The UART_PCLK and the actual Peripheral Clock(PCLK) is calculated as below.
	   (Refer data sheet for more info)
 
	   UART_PCLK    PCLK
	     0x00       SystemFreq/4        
		 0x01       SystemFreq
		 0x02       SystemFreq/2
		 0x03       SystemFreq/8   
	 **/
 
	var_UartPclk_u32 = (LPC_SC->PCLKSEL0 >> 6) & 0x03;
 
	switch( var_UartPclk_u32 )
	{
	      case 0x00:
			var_Pclk_u32 = SystemFrequency/4;
			break;
		  case 0x01:
			var_Pclk_u32 = SystemFrequency;
			break; 
		  case 0x02:
			var_Pclk_u32 = SystemFrequency/2;
			break; 
		  case 0x03:
			var_Pclk_u32 = SystemFrequency/8;
			break;
	}
 
 
        var_RegValue_u32 = ( var_Pclk_u32 / (16 * baudrate )); 
	LPC_UART0->DLL =  var_RegValue_u32 & 0xFF;
	LPC_UART0->DLM = (var_RegValue_u32 >> 0x08) & 0xFF;
 
        util_BitClear(LPC_UART0->LCR,(M_DlabBitPosition_U8));  // Clear DLAB after setting DLL,DLM
}


Steps for transmitting a char

  1. Step1: Wait till the previous char is transmitted ie. till THRE becomes high.
  2. Step2: Load the new char to be transmitted into THR.

Code snippet

void uart_TxChar(char ch)
{
  while(util_IsBitCleared(LPC_UART0->LSR,SBIT_THRE));
  LPC_UART0->THR=ch;
}

Steps for Receiving a char

  1. Step1: Wait till the a char is received ie. till RDR becomes high.
  2. Step2: Copy the received data from receive buffer(RBR).

Code snippet

char uart_RxChar(void)
{
  while(util_IsBitCleared(LPC_UART0->LSR,SBIT_RDR));
  ch = LPC_UART0->RBR;
return ch;
}


Code

Below is the code for transmitting and receiving chars at 9600 baud

#include <lpc17xx.h>
#include "stdutils.h"
 
#define SBIT_WordLenght    0x00u
#define SBIT_DLAB          0x07u
#define SBIT_FIFO          0x00u
#define SBIT_RxFIFO        0x01u
#define SBIT_TxFIFO        0x02u
 
#define SBIT_RDR           0x00u
#define SBIT_THRE          0x05u
 
 
 
/* Function to initialize the UART0 at specifief baud rate */
void uart_init(uint32_t baudrate)
{
    uint32_t var_UartPclk_u32,var_Pclk_u32,var_RegValue_u32;
 
    LPC_PINCON->PINSEL0 &= ~0x000000F0;
    LPC_PINCON->PINSEL0 |= 0x00000050;            // Enable TxD0 P0.2 and p0.3 
 
    LPC_UART0->FCR = (1<<SBIT_FIFO) | (1<<SBIT_RxFIFO) | (1<<SBIT_TxFIFO); // Enable FIFO and reset Rx/Tx FIFO buffers    
    LPC_UART0->LCR = (0x03<<SBIT_WordLenght) | (1<<SBIT_DLAB); // 8bit data, 1Stop bit, No parity
 
 
    /** Baud Rate Calculation :
       PCLKSELx registers contains the PCLK info for all the clock dependent peripherals.
       Bit6,Bit7 contains the Uart Clock(ie.UART_PCLK) information.
       The UART_PCLK and the actual Peripheral Clock(PCLK) is calculated as below.
       (Refer data sheet for more info)
 
       UART_PCLK    PCLK
         0x00       SystemFreq/4        
         0x01       SystemFreq
         0x02       SystemFreq/2
         0x03       SystemFreq/8   
     **/
 
    var_UartPclk_u32 = (LPC_SC->PCLKSEL0 >> 6) & 0x03;
 
    switch( var_UartPclk_u32 )
    {
          case 0x00:
            var_Pclk_u32 = SystemFrequency/4;
            break;
          case 0x01:
            var_Pclk_u32 = SystemFrequency;
            break; 
          case 0x02:
            var_Pclk_u32 = SystemFrequency/2;
            break; 
          case 0x03:
            var_Pclk_u32 = SystemFrequency/8;
            break;
    }
 
 
        var_RegValue_u32 = ( var_Pclk_u32 / (16 * baudrate )); 
    LPC_UART0->DLL =  var_RegValue_u32 & 0xFF;
    LPC_UART0->DLM = (var_RegValue_u32 >> 0x08) & 0xFF;
 
        util_BitClear(LPC_UART0->LCR,(SBIT_DLAB));  // Clear DLAB after setting DLL,DLM
}
 
 
/* Function to transmit a char */
void uart_TxChar(char ch)
{
    while(util_IsBitCleared(LPC_UART0->LSR,SBIT_THRE)); // Wait for Previous transmission
    LPC_UART0->THR=ch;                        // Load the data to be transmitted
}
 
 
/* Function to Receive a char */
char uart_RxChar()
{
 char ch;
 
     while(util_IsBitCleared(LPC_UART0->LSR,SBIT_RDR));  // Wait till the data is received
    ch = LPC_UART0->RBR;                              // Read received data    
 
 return ch;
}
 
 
 
void main()
{
   char ch,a[]="\n\rExploreEmbedded";
   int i;
 
   SystemInit();
   uart_init(9600);  // Initialize the UART0 for 9600 baud rate
 
   uart_TxChar('h'); //Transmit "hello" char by char
   uart_TxChar('e');
   uart_TxChar('l');
   uart_TxChar('l');
   uart_TxChar('o');
 
 
   for(i=0;a[i];i++)  //transmit a predefined string
    uart_TxChar(a[i]);
 
 
    while(1)
    {
      //Finally receive a char and transmit it infinitely
      ch = uart_RxChar(); 
      uart_TxChar(ch);
    }       
}

Using Explore Embedded Libraries

In the above tutorial we discussed how to configure and use the inbuilt LPC1768 ADC.
Now we will see how to use the exploreEmbededd ADC libraries and interface POT,LDR and Temperature Sensor(LM35).
For this you have to include the adc.c/adc.h files. As the result will be displayed on the LCD, lcd.c/lcd.h also needs to be included.
Refer the LCD tutorial for interfacing the 2x16 lcd.

 
#include<lpc17xx.h>
#include "lcd.h"    //User defined LCD library which contains the lcd routines
#include "delay.h"  //User defined library which contains the delay routines
#include "adc.h"
 
 
void main()
{
   uint16_t pot_value,ldr_value, temp_raw, temp_final;
   float voltage;
    SystemInit();                              //Clock and PLL configuration
 
   /* Setup/Map the controller pins for LCD operation 
               RS   RW   EN    D0    D1    D2   D3     D4   D5    D6    D7*/
    LCD_SetUp(P2_0,P2_1,P2_2,P1_20,P1_21,P1_22,P1_23,P1_24,P1_25,P1_26,P1_27);
 
 
    LCD_Init(2,16);      /* Specify the LCD type(2x16) for initialization*/
    ADC_Init();          /* Initialize the ADC */
    while(1)
    {
        pot_value  = ADC_GetAdcValue(0); /* Read pot value connect to AD0(P0_23) */
        ldr_value  = ADC_GetAdcValue(1); /* Read LDR value connect to AD1(P0_24) */
        temp_raw   = ADC_GetAdcValue(2); /* Read Temp value connect to AD2(P0_25) */
 
     /*Converting the raw adc value to equivalent temperature with 3.3v as ADC reference using 12bit resolution.
            Step size of ADC= (3.3v/2^12)= 3.3/4096 = 0.0008056640625 = 0.0806mv
            For every degree celcius the Lm35 provides 10mv voltage change.
            1 degree celcius = 10mv = 10mv/0.0806mv = 12.41 uinits            
             Hence the Raw ADC value can be divided by 12.41 to get equivalent temp*/        
 
         temp_final = temp_raw/12.41;
 
        /* Vin = (Adc_value * REF)/ 2^12 */
        voltage = (pot_value * 3.3)/ 4096.0;
 
        LCD_GoToLine(0);
        LCD_Printf("P:%4d %f",pot_value,voltage);
        LCD_Printf("\nL:%4d T:%4d",ldr_value,temp_final);       
    }
}