Tuesday, 1 March 2016

Raspberry Pi on Windows-gkarthik

needing:


Raspberry Pi
SD card with at least 4 GB capacity
PC or Notebook with SD card slot
Download latest Raspbian image: http://www.raspberrypi.org/downloads/
Download and install Win32Diskimager: http://sourceforge.net/projects/win32diskimager/
Download and install Putty (SSH client): http://www.putty.org/

Writing Raspbian image to SD card

Open Win32Diskimager, select the earlier downloaded Raspbian image ("Image File") and the drive ("Device") where you have put the SD card into.
Setup Win32Diskimager for Raspbian SD card setup
Once this is done press "Write" to write the image file.
Write Raspbian image to SD card
Wait till the SD card is completely written. This can take several minutes.

Starting the Raspberry Pi

Now we can put the SD card into the Raspberry Pi's SD card slot
Howto insert SD card into Raspberry Pi - step 1
Howto insert SD card into Raspberry Pi - step 2
Once this is done, we can prepare the Raspberry Pi for it's first boot. So we the LAN cable and connect the power supply (micro USB).
Connect Raspberry Pi to LAN and power

Setup Raspberry Pi after first startup

To be able to connect to the Raspberry Pi via Putty (or any other SSH client) we need to know the IP address of the Raspberry Pi. I assume the Raspberry Pi is connected to your network with a DHCP server on your router. In this case you might get the IP address from admin web interface of your router.
With the IP address you can now connect to your Raspberry Pi with Putty.
Putty settings for Raspberry Pi connection
Once you have entered the IP address, just click open. Putty will complain about some wrong/missing keys, just ignore it and continue. After that, you will be asked to login.
Putty Raspberry Pi login
Default user name is "pi", default password is "raspberry".
Putty Raspberry Pi login
Now we start the raspi-config tool where some basic things can be configured.
Start raspi-config
To make sure that Raspbian will utilize the full SD card size, select "Expand Filesystem"
raspi-config expand filesystem
All other options in raspi-config have to be set according to your needs.
Once you have finished raspi-config, we will now update the Linux system by executing the command "sudo apt-get update && sudo apt-get dist-upgrade".
Raspbian update

serial communication pic microcontroller

RS232 is a standard for a serial communication interface which allows to send and receive data via at least three wires. With the RS232 interface it is possible to setup a connection between a microcontroller and a PC (via PC's COM port) or between two microcontrollers.
The RS232 interface can be used for many purposes like sending commands from a PC to a microcontroller, send debug information from a micontroller to a terminal, download new firmware to the microcontroller and many other things.
In this tutorial I will show how to link a PIC microcontroller to a standard PC. On the PC we will use a termial program to send and receive data. Data sent by the microcontroller will be shown in the terminal window and any key pressed inside the terminal will send the corresponding key code to the microcontroller. We will use this simple configuration to test and understand the RS232 communication.
Note that modern PCs don't have a serial port so you need to get a USB to serial converter. They are available at low cost.

Block Diagram

The following block diagram shows the whole setup:
RS232 Communication with PIC Microcontroller Block Diagram
For serial communication the line used to transmit data is called TX and the line used to receive data is called RX. The level converter is required to translate the voltage level of the microntroller to RS232 voltage level. The microntroller operates at TTL level (0V = logic 0, +5V logic 1) whereas RS232 uses around +/-12V. A very famous RS232 level converter is the MAX232 chip.

Schematic

RS232 Communication with PIC Microcontroller Schematic
The PIC is running at 10MHz. This will be important later when we configure the baudrate for the serial communication.
Ther RS232 level converter uses the famous MAX232 chip, but any other MAX232 compatible chip will also work. It just requires 4 capacitors to do its job. These external capacitors are required for the charge pump inside the chip which generates the required voltage levels.
The connections on the DB9 connector between pins 1,4,6 and 7,8 are required to satisfy the RS232 hardware handshake signals which we will not use here.
I have developed a RS232 module which allows direct connection to the microcontroller. It consists of a DB9 Female connector, a MAX232 compatible RS232 level converter and the capacitors. You can find the RS232 module here.

RS232 Cable

To connect the above circuit to the PC we need a RS232 cable. The below picture shows the necessary connections.
RS232 Cable for connection of Microcontroller with PC
 my software coding:

RS232 communication with CCS C compiler

The CCS C compiler provides a very simple way to do serial communication via RS232. It hides all the register settings for the user. Only the some parameters have to be provided, the rest is done by the compiler. By the way, the CCS C compiler also allows to do RS232 communication via general I/O pins, i.e. software based RS232 communication instead of using the built-in UART. That is a really great feature of the CCS C compiler.
Here the code lines which are required to setup the UART for RS232 communication.
#use delay(clock=40000000)
#use rs232(baud=57600,parity=N,xmit=PIN_C6,rcv=PIN_C7,bits=8)
As you can see, it is very simple!
The #use delay directive provides the compiler with the information about the clock frequency at which the PIC is running. We run the PIC at 10MHz with the 4X PLL fuse enabled, hence it is running at 40MHz, so we have to set clock=40000000.
The #use rs232 directive provides the compiler the information about the RS232 parameters which shall be used for the communication. It is more or less self explaining:
  • baud=57600: specifies the baud rate for communication, we will use 57600 baud
  • parity=: specifies whether a parity bit shall be used or not, we will not use it, hence we disable it
  • xmit=PIN_C6: specifies the pin to be used for transmission, since we want to use the built-in UART we have to use pin RC6
  • rcv=PIN_C7: specifies the pin to be used for receiption, since we want to use the built-in UART we have to use pin RC7
  • bits=8: specifies the number of bits per transmitted data
 
To transmit data the following functions can be used:
int value = 1;
putc('A');                              /* transmit a character via RS232 */
puts("Test-String");                    /* transmit a string via RS232 */
printf("Transmit a value: %d", value);  /* send formatted string via RS232 */
To receive data the following functions can be used:
char ch;
char string[32];
ch = getc();                        /* receives a single character via RS232 */
gets(string);                       /* receives a string via RS232, reads */
/* characters into the string until RETURN */
/* character (13) is encountered */
Here a simple demo program for the CCS C compiler. Project download link. To run the demo, the HEX file needs to be flashed into the PIC, e.g. with PICPgm Programmer.
/*****************************************************************************/
/* RS232 communication demo wiht CCS C compiler                              */
/*****************************************************************************/
#include <18F2620.h>
#device adc=16
#FUSES NOWDT                     //No Watch Dog Timer
#FUSES WDT128                    //Watch Dog Timer uses 1:128 Postscale
#FUSES H4                        //High speed osc with HW enabled 4X PLL
#FUSES NOBROWNOUT                //No brownout reset
#FUSES LVP                       //Low voltage prgming
#FUSES NOXINST                   //Extended mode disabled (Legacy mode)
#use delay(clock=40000000)
#use rs232(baud=57600,parity=N,xmit=PIN_C6,rcv=PIN_C7,bits=8)
void main()
{
int value = 85;
char ch;
char string[64];
puts("**********************************");
puts("  RS232 demo with CCS C compiler  ");
puts("**********************************");
/* start a new line (CR + LF) */
putc('\n');
putc('\r');
/* output variable in decimal format */
printf("Decimal variable output: %d\n\r", value);
/* output variable in hex format */
printf("Hex variable output: %x\n\r", value);
/* echo demo: PIC receives data and sends it back. */
/*            If ENTER key is received, this demo exits. */
puts("Type on the keyboard, PIC will echo back the characters:");
while (1)
{
/* read a single character */
ch = getc();
/* echo back the received character */
putc(ch);
}
}

RS232 communication with HI-TECH C compiler

To be done ...
 

PC connection


Now, since we have the required hardware and firmware, we can connect the hardware to the PC.
To be able to see the data transmitted from the Microcontroller and to send data to the Microcontroller we have to run a terminal program on the PC. There are a lot of terminal programs available. I will show here how to use HyperTerminal which is included in Microsoft Windows.

HyperTerminal Setup

If you are using Windows XP start HyperTerminal. You can find it in the Communication Folder: Start Menu->All Programs->Accessories->Communication.
 
On startup it will ask for a connection name. Just enter a text which will identify the connection, e.g. use "RS232 Demo". In the next dialog select the COM port where the PIC is connected to.
HyperTerminal Connection Name HyperTerminal Port Selection
 
In the following dialog we have to set the connection properties. Needless to say, the properties have to match the settings we are using in the PIC.
HyperTerminal Connection Porperties
 
Once this is done, just reset the PIC and the demo output shal be visible.
HyperTerminal Demo
 
 thank you.....by gkarthik