Membuat Display 4 baris 7 segment menggunakan MAX7221

Teory dasar bisa dibaca di https://pccontrol.wordpress.com/2011/09/15/pemrograman-display-7-segment-dengan-spi-max7221-max7219/

pada contoh ini menggunakan 7 segment  kecil < 1 inch dgn tegangan 5v.jika Anda ingin menggunakan 7 segmen dgn tegangan lebih dari 5 v ( 7 segment ukuran yg besar i inch,2 inch 3 inch dst) maka tinggalditambahkan penguat daya misal dgn transistor atau ic ULN2083 atau lainnya.

4baris7segment

koneksi

max7221serial

Kode program C dengan codevision

 

/*****************************************************
CodeWizardAVR V1.24.
Chip type : ATmega16
Clock frequency : 11.059200 MHz
*****************************************************/
// Standard Input/Output functions
#include <stdio.h>
#include <delay.h>
#include <spi.h>
#include <mega16.h>
//=========================

// SPI
#define PIN_SCK PORTB.7
#define PIN_MOSI PORTB.5
#define PIN_SS PORTB.4

#define ON 1
#define OFF 0

#define MAX7219_LOADa1 PORTB.4=1 //chip enable 1
#define MAX7219_LOADa0 PORTB.4=0 //chip enable 0
#define MAX7219_LOADb1 PORTB.3=1 //chip enable 1
#define MAX7219_LOADb0 PORTB.3=0 //chip enable 0
#define MAX7219_LOADc1 PORTB.2=1 //chip enable 1
#define MAX7219_LOADc0 PORTB.2=0 //chip enable 0
#define MAX7219_LOADd1 PORTB.1=1 //chip enable 1
#define MAX7219_LOADd0 PORTB.1=0 //chip enable 0

#define MAX7219_MODE_DECODE 0x09
#define MAX7219_MODE_INTENSITY 0x0A
#define MAX7219_MODE_SCAN_LIMIT 0x0B
#define MAX7219_MODE_POWER 0x0C
#define MAX7219_MODE_TEST 0x0F
#define MAX7219_MODE_NOOP 0x00

#define MAX7219_DIGIT0 0x01
#define MAX7219_DIGIT1 0x02
#define MAX7219_DIGIT2 0x03
#define MAX7219_DIGIT3 0x04
#define MAX7219_DIGIT4 0x05
#define MAX7219_CHAR_BLANK 0xF
#define MAX7219_CHAR_NEGATIVE 0xA
//================================
#define RXB8 1
#define TXB8 0
#define UPE 2
#define OVR 3
#define FE 4
#define UDRE 5
#define RXC 7

#define FRAMING_ERROR (1<<FE)
#define PARITY_ERROR (1<<UPE)
#define DATA_OVERRUN (1<<OVR)
#define DATA_REGISTER_EMPTY (1<<UDRE)
#define RX_COMPLETE (1<<RXC)

//void MAX7219_displayNumber(volatile long number);
void MAX7219_displayNumber(long number,char baris);
void MAX7219_clearDisplay(char baris);
//void MAX7219_writeData(char data_register, char data);
void MAX7219_writeData(char data_register, char data, char baris);
void spiSendByte (char databyte);

// USART Receiver buffer
#define RX_BUFFER_SIZE 8
char rx_buffer[RX_BUFFER_SIZE];

#if RX_BUFFER_SIZE<256
unsigned char rx_wr_index,rx_rd_index,rx_counter;
#else
unsigned int rx_wr_index,rx_rd_index,rx_counter;
#endif

// This flag is set on USART Receiver buffer overflow
bit rx_buffer_overflow;

// USART Receiver interrupt service routine
interrupt [USART_RXC] void usart_rx_isr(void)
{
char status,data;
status=UCSRA;
data=UDR;
if ((status & (FRAMING_ERROR | PARITY_ERROR | DATA_OVERRUN))==0)
{
rx_buffer[rx_wr_index]=data;
if (++rx_wr_index == RX_BUFFER_SIZE) rx_wr_index=0;
if (++rx_counter == RX_BUFFER_SIZE)
{
rx_counter=0;
rx_buffer_overflow=1;
};
};
}

#ifndef _DEBUG_TERMINAL_IO_
// Get a character from the USART Receiver buffer
#define _ALTERNATE_GETCHAR_
#pragma used+
char getchar(void)
{
char data;
while (rx_counter==0);
data=rx_buffer[rx_rd_index];
if (++rx_rd_index == RX_BUFFER_SIZE) rx_rd_index=0;
#asm(“cli”)
–rx_counter;
#asm(“sei”)
return data;
}
#pragma used-
#endif

// Declare your global variables here
char digitsInUse = 5;
void main(void)
{
// Declare your local variables here

int a,b,c,d,i;
// Input/Output Ports initialization
// Port A initialization
PORTA=0x00;
DDRA=0x00;

// Port B initialization
PORTB=0x00;
DDRB=0xff; // SCK MOSI CS/LOAD/SS

// Port C initialization
PORTC=0x00;
DDRC=0x00;

// Port D initialization
// Func7=In Func6=In Func5=In Func4=In Func3=In Func2=In Func1=In Func0=In
// State7=T State6=T State5=T State4=T State3=T State2=T State1=T State0=T
PORTD=0x00;
DDRD=0x00;

// USART initialization
// Communication Parameters: 8 Data, 1 Stop, No Parity
// USART Receiver: On
// USART Transmitter: Off
// USART Mode: Asynchronous
// USART Baud rate: 9600
UCSRA=0x00;
UCSRB=0x90;
UCSRC=0x86;
UBRRH=0x00;
UBRRL=0x47;

// SPI initialization
// SPI Type: Master
// SPI Clock Rate: 86.400 kHz
// SPI Clock Phase: Cycle Half
// SPI Clock Polarity: Low
// SPI Data Order: MSB First
//SPCR=0x53;
//SPSR=0x00;
// SPI Enable, Master mode
SPCR =0x53;
for(i=1;i<5;i++)
{
// Decode mode to “Font Code-B”
MAX7219_writeData(MAX7219_MODE_DECODE, 0xFF,i);
// Scan limit runs from 0.
MAX7219_writeData(MAX7219_MODE_SCAN_LIMIT, digitsInUse – 1,i);
MAX7219_writeData(MAX7219_MODE_INTENSITY, 8,i);
MAX7219_writeData(MAX7219_MODE_POWER, ON,i);
delay_ms(50);
}
//

// Global enable interrupts
#asm(“sei”)

a=12305;
b=11300;
c=11612;
d=b-c;
MAX7219_displayNumber(a,1);
MAX7219_displayNumber(b,2);
MAX7219_displayNumber(c,3);
MAX7219_displayNumber(d,4);

while (1)
{

i=i+1;

if(i==999)i=0;
};

}

//===============================================================================
//=========================
void spiSendByte (char databyte)
{
SPDR = databyte;
// Wait until transfer is complete
while (!(SPSR & (1 << 7)));
}

void MAX7219_writeData(char data_register, char data, char baris)
{
if(baris==1)
{
MAX7219_LOADa0;
// Send the register where the data will be stored
spiSendByte(data_register);
// Send the data to be stored
spiSendByte(data);
MAX7219_LOADa1;
}
if(baris==2)
{
MAX7219_LOADb0;
// Send the register where the data will be stored
spiSendByte(data_register);
// Send the data to be stored
spiSendByte(data);
MAX7219_LOADb1;
}
if(baris==3)
{
MAX7219_LOADc0;
// Send the register where the data will be stored
spiSendByte(data_register);
// Send the data to be stored
spiSendByte(data);
MAX7219_LOADc1;
}
if(baris==4)
{
MAX7219_LOADd0;
// Send the register where the data will be stored
spiSendByte(data_register);
// Send the data to be stored
spiSendByte(data);
MAX7219_LOADd1;
}

}

void MAX7219_clearDisplay(char baris)
{
char i;
i = digitsInUse;
// Loop until 0, but don’t run for zero
do {
// Set each display in use to blank
MAX7219_writeData(i, MAX7219_CHAR_BLANK,baris);
} while (–i);

}

void MAX7219_displayNumber(long number,char baris)
{
char negative = 0;
char i = 0;
if (number < 0) {
negative = 1;
number =number * -1; //rubah ke +
}
MAX7219_clearDisplay(baris);
// If number = 0, only show one zero then exit
if (number == 0) {
MAX7219_writeData(1, 0,baris);
return;
}
// Initialization to 0 required in this case,
// does not work without it. Not sure why.
// Loop until number is 0.
do {
MAX7219_writeData(++i, number % 10,baris);
// Actually divide by 10 now.
number /= 10;
} while (number);

// display the sign.
if (negative) {
MAX7219_writeData(i+1, MAX7219_CHAR_NEGATIVE,baris);
}
}

Advertisements

About pccontrol

Berisi Tutorial Menggunakan PC untuk mengontrol Peralatan dengan cara mudah & praktis untuk pemula.

Posted on 03/06/2016, in AVR, Contoh-contoh Aplikasi, Daftar isi. Bookmark the permalink. 4 Comments.

  1. bisa. hasil baca keypad disimpan di variable. data divariable di tampilkan ke matrik. jumlah data tergantung type data yg dipakai dan jumlah maksimum 1 baris 8 digit.

  2. Bagaimana caranya jika kita input datanya pakai keypad matrix pak?, displaynya berapa maksimalnya?.
    Terima kasih.

  3. Zamzam Hafidz Om

    sangat ingin membuat yg pake ic 74595 nya pak,
    terimakasih sangat membantu

Komentar ,Saran atau Pertanyaan

Fill in your details below or click an icon to log in:

WordPress.com Logo

You are commenting using your WordPress.com account. Log Out / Change )

Twitter picture

You are commenting using your Twitter account. Log Out / Change )

Facebook photo

You are commenting using your Facebook account. Log Out / Change )

Google+ photo

You are commenting using your Google+ account. Log Out / Change )

Connecting to %s

%d bloggers like this: