Difference between revisions of "Example i2c test"

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This procedure provides an overview of how to compile and run the <code>i2c_test</code> C example project. This is an example test interface for reading/writing to the Linux <code>I²C</code> device interface. It is only relevant if the <code>I²C</code> device interface is enabled and an external <code>I²C</code> device is connected to the bus. It assumes familiarity with the C programming language and is intended to be used by experienced programmers who are looking to learn the EMAC SDK.
 
This procedure provides an overview of how to compile and run the <code>i2c_test</code> C example project. This is an example test interface for reading/writing to the Linux <code>I²C</code> device interface. It is only relevant if the <code>I²C</code> device interface is enabled and an external <code>I²C</code> device is connected to the bus. It assumes familiarity with the C programming language and is intended to be used by experienced programmers who are looking to learn the EMAC SDK.
  
For more information about the protocol see the following page:http://en.wikipedia.org/wiki/I²C
+
For more information about the protocol see the following page: http://en.wikipedia.org/wiki/I²C
  
 
The <code>i2c_test</code> project builds one executable: <code>i2c_test</code>.
 
The <code>i2c_test</code> project builds one executable: <code>i2c_test</code>.

Revision as of 17:40, 5 February 2014

TODO: {{#todo:Review (11.14.13-13:25->JG+);(11.14.13-15:45->MD-);(01.30.14-16:20->BS+);(01.30.14-18:30->MD-)|Brian Serrano|oe 4,oe 5,md,Review,bs}}


This is a guide to the i2c_test example project included in the EMAC OE SDK.

I²C is a two wire serial interface used to connect to a variety of sensor and I/O devices. The interface uses only two bi-directional open-drain I/Os, Serial Data Line (SDA) and Serial Clock (SCL), to communicate to devices based on an address encoded within the data transmission. SDA is a data signal which sends and receives serially transmitted data. SCL is a clock signal which is used to determine when to latch data from the SDA line.

This procedure provides an overview of how to compile and run the i2c_test C example project. This is an example test interface for reading/writing to the Linux I²C device interface. It is only relevant if the I²C device interface is enabled and an external I²C device is connected to the bus. It assumes familiarity with the C programming language and is intended to be used by experienced programmers who are looking to learn the EMAC SDK.

For more information about the protocol see the following page: http://en.wikipedia.org/wiki/I²C

The i2c_test project builds one executable: i2c_test.

Opening, Building, and Uploading the Project Files

For information on opening the project from within Eclipse, please see, Importing the EMAC OE SDK Projects with Eclipse. Then, follow Using the EMAC OE SDK Projects with Eclipse for information on how to build, upload, and execute the example.

Alternatively, the Makefile can be used with the make command from the command-line to build and upload the example. For more information on this method, please see, Using EMAC OE SDK Example Projects.

Usage and Behavior

Hardware Requirements

The i2c_test C example project will run on any EMAC carrier board which has an I²C interface (see also the EMAC I²C Programming page).

Using i2c_test

The i2c_test program is executed from the console. It takes no parameters.

root@emac-oe~:$ ./i2c_test

A menu will appear in the terminal:

Select a function to test:
    a: Set slave address
    b: Write byte to register
    c: Write 2 bytes to register
    d: Read byte from register
    e: Read 2 bytes from register
    q: Quit

Select a function (a,b,c,d,e) to test or q to quit. You will be prompted for read, write and register values as appropriate. Test results will be displayed in the terminal.

Test Options

  • Set Slave Address
    Press the A key to select the Set slave address function, then press Enter.

    Select a function to test:
        a: Set slave address
        b: Write byte to register
        c: Write 2 bytes to register
        d: Read byte from register
        e: Read 2 bytes from register
        q: Quit
    >> a
    
    
    Enter the slave address (in hex): 48
    
    Calling i2c_set_slave(3, 0x48)
    i2c_set_slave reports success
    

    The slave address receives the clock and responds when addressed by the master.

    This function is to set the slave address of the I²C device. This only need to be done once to initialize the address and then each time that a new device is addressed.

  • Write byte to register
    Press the B key to select the Write byte to register function, then press Enter

    Select a function to test:
        a: Set slave address
        b: Write byte to register
        c: Write 2 bytes to register
        d: Read byte from register
        e: Read 2 bytes from register
        q: Quit
    >> b
    
    Enter a byte to write (in hex): aa
    Enter a register value to write (in hex): 01
    
    Calling i2c_write_cmd(3, 0x1, 0xAA)
    i2c_write_cmd reports success
    

    This function uses the Linux write system call to write one byte to the selected register on the I²C device.

  • Write 2 bytes to register
    Press the C key to select the Write 2 bytes to register function, then press Enter.

    Select a function to test:
        a: Set slave address
        b: Write byte to register
        c: Write 2 bytes to register
        d: Read byte from register
        e: Read 2 bytes from register
        q: Quit
    >> c
    
    Enter a 2 byte number to write (in hex): aabb
    Enter a register value to write (in hex): 01
    
    Calling i2c_write_cmd2(3, 0x1, 0xAABB)
    i2c_write_cmd2 reports success
    

    This function uses the same system call as the previous option, but writes 2 bytes to a register instead of just one.

  • Read byte from register
    Press the D key to select the Read byte from register function, then press Enter.

    Select a function to test:
        a: Set slave address    
        b: Write byte to register    
        c: Write 2 bytes to register    
        d: Read byte from register    
        e: Read 2 bytes from register    
        q: Quit
    >> d
    
    Enter a register value to read from (in hex): bb
    
    Calling i2c_read_reg(3, (__u8 *)&val, 0xBB)
    i2c_read_reg reports success
    Read value 0xB
    

    This function uses the Linux read system call to read a byte to the selected register on the I²C device.

  • Read 2 bytes from register
    Press the E key to select the Read 2 bytes from register function, then press Enter.

    Select a function to test:
        a: Set slave address        
        b: Write byte to register        
        c: Write 2 bytes to register        
        d: Read byte from register        
        e: Read 2 bytes from register        
        q: Quit
    >> e
    
    Enter a register value to read from (in hex): bbcc
    
    Calling i2c_read_reg2(3, &val, 0xBBCC)
    i2c_read_reg2 reports success
    Read value 0xB0B
    

    This function uses the same system call as the previous option, but shifts to the right.

    The i2c_test example writes a byte to a selected register. The register then reads the byte, shifts the byte 8 bits to the right and then reads the address to the selected register on the I²C device.

    • Quit

    Press the Q key to quit out of the i2c_test example, then press Enter.

    Select a function to test:    
        a: Set slave address            
        b: Write byte to register            
        c: Write 2 bytes to register            
        d: Read byte from register            
        e: Read 2 bytes from register            
        q: Quit
    >> q
    Quiting...
    

    This function quits you out of the i2c_test example on the I²C device.

Summary

The i2c_test C example project writes and reads bytes to a selected register on the I²C device.