Difference between revisions of "PIC18F4520: Serial Digital-to-Analog Conversion"
Line 1: | Line 1: | ||
Since PIC microcontrollers do not offer analog outputs, a Digital-to-Analog converter (DAC) must be used to obtain an analog signal. An eight bit digital number can be converted to analog by using eight of the output pins from the PIC MCU to a separate DAC chip, however if more than one conversion is neccessary, this will quickly use up many of the available output pins from the PIC microcontroller, and require extensive wiring. Luckily, there is an easier and more effective way of doing this using <math>I^2C</math> communication. <math>I^2C</math> utilizes two lines to communicate, usually called ''SCL'' and ''SDA'' (a clock line and a data line). A "master" produces an <math>I^2C</math> signal which is sent to the "slave" to work with. Many slaves can be controlled by one master, as long as no slave addresses are used more than once (the number of possible slave addresses is limited by the specific chip being used as a slave). Communication begins with a start condition (the clock line being held high while the data line is dropped low) and ends with a stop condition (clock line held high while the data line is brought from low to high). |
Since PIC microcontrollers do not offer analog outputs, a Digital-to-Analog converter (DAC) must be used to obtain an analog signal. An eight bit digital number can be converted to analog by using eight of the output pins from the PIC MCU to a separate DAC chip, however if more than one conversion is neccessary, this will quickly use up many of the available output pins from the PIC microcontroller, and require extensive wiring. Luckily, there is an easier and more effective way of doing this using <math>I^2C</math> communication. <math>I^2C</math> utilizes two lines to communicate, usually called ''SCL'' and ''SDA'' (a clock line and a data line). A "master" produces an <math>I^2C</math> signal which is sent to the "slave" to work with. Many slaves can be controlled by one master, as long as no slave addresses are used more than once (the number of possible slave addresses is limited by the specific chip being used as a slave). If the slave chip has two programmable address bits, then four slaves can be controlled by one master. If there are three address bits, then eight slaves can be controlled by one master. Communication begins with a start condition (the clock line being held high while the data line is dropped low) and ends with a stop condition (clock line held high while the data line is brought from low to high). |
||
<br><br> |
<br><br> |
||
[[Image:startstopcond.jpg|center]] |
[[Image:startstopcond.jpg|center]] |
Revision as of 09:04, 2 July 2007
Since PIC microcontrollers do not offer analog outputs, a Digital-to-Analog converter (DAC) must be used to obtain an analog signal. An eight bit digital number can be converted to analog by using eight of the output pins from the PIC MCU to a separate DAC chip, however if more than one conversion is neccessary, this will quickly use up many of the available output pins from the PIC microcontroller, and require extensive wiring. Luckily, there is an easier and more effective way of doing this using communication. utilizes two lines to communicate, usually called SCL and SDA (a clock line and a data line). A "master" produces an signal which is sent to the "slave" to work with. Many slaves can be controlled by one master, as long as no slave addresses are used more than once (the number of possible slave addresses is limited by the specific chip being used as a slave). If the slave chip has two programmable address bits, then four slaves can be controlled by one master. If there are three address bits, then eight slaves can be controlled by one master. Communication begins with a start condition (the clock line being held high while the data line is dropped low) and ends with a stop condition (clock line held high while the data line is brought from low to high).
Between the start and stop conditions are different bytes of information. These will differ with each application and each device you are communicating with, although many will have some sort of addressing byte, a command byte, and then information bytes. After every byte sent, the slave will send back an acknowledge bit, prompting the master to send the next byte of information.
C Programming
The basic building blocks of programming for communication are shown below.
Function | Description |
---|---|
i2c_start() | Sends a start condition |
i2c_write() | Writes a data byte to the slave |
i2c_stop() | Sends a stop condition |
Using these three functions, one can program whatever information is required to the slave device.