Difference between revisions of "Waveform Generation with AD9833, and SPI"

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With a small variation in the values of the five transfers, all of the frequency and phase registers can be written to and output from the VOUT pin of the AD9833.
With a small variation in the values of the five transfers, all of the frequency and phase registers can be written to and output from the VOUT pin of the AD9833.
==References==
*[http://www.analog.com/static/imported-files/Data_Sheets/AD9833.pdf AD9833 Datasheet, Analog Devices]

Revision as of 19:13, 9 December 2008

AD9833Connsmall.jpg

The AD9833 is a programmable waveform generator capable of creating sine, triangular, or square wave outputs in a frequency range of 0 to 12.5 MHz. It has two 28-bit frequency registers and two 12-bit phase registers that can be written to and output from the VOUT pin. This chip is perfectly suited for use with the PIC 18F4520, as it uses SPI communication for its setup and control. A connection diagram for the AD9833 is given to the right. The MCLK pin is tied directly to the oscillator of the PIC, and the three SPI communication lines are connected to three I/O pins on the PIC (in this case pins A1, A2, and A3).


In order to establish communication between the PIC and the AD9833, we need to set up the SPI for the pins we wish to use. The following code should be included in your program.

#use spi(DO = PIN_A3, CLK = PIN_A2, ENABLE = PIN_A1, BITS = 16, MASTER, ENABLE_ACTIVE = 0, MSB_FIRST, IDLE = 1)


The first three arguments determine which three pins we will be using: DO is the "SDATA" pin of the AD9833, CLK is the "SCLK" pin, and ENABLE is the "FSYNC" pin. The next argument states that the max number of bits in one transfer is 16. The next argument specifies that the PIC is the master and the AD9833 is the slave. The AD9833's FSYNC pin is active low, and it accepts the most significant bit (MSB) of each transfer first. The SCLK pin is also specified to be kept high when not in use. After this initial setup, the SPI communication is quite straightforward. We simply use the function spi_xfer() whenever we want to send information via SPI to the AD9833.


Now that we can talk to the waveform generator, we need to know what it needs to be told to produce what we want. Each of the 16 bits transferred has a meaning, and these meanings are described in the Table below. Note that the if a frequency register is being written to (first two bits = 01 or 10), the last 14 bits are the value of the write, and do not have the same meaning as specified in the table. Similarly, if a phase register is being written to (first two bits = 11), the last 12 bits are the value of the write. Only if the control register is being written to (first two bits = 00) are most of the meanings specified in the table applicable.

Bit Significance
D15,D14(MSB) 10 = FREQ1 write, 01 = FREQ0 write, 11 = PHASE write, 00 = control write
D13 If D15,D14 = 00, 0 = individual LSB and MSB FREQ write, 1 = both LSB and MSB FREQ writes consecutively
If D15,D14 = 11, 0 = PHASE0 write, 1 = PHASE1 write
D12 0 = writing LSB independently, 1 = writing MSB independently
D11 0 = output FREQ0, 1 = output FREQ1
D10 0 = output PHASE0, 1 = output PHASE1
D9 Reserved. Must be 0.
D8 0 = RESET disabled, 1 = RESET enabled
D7 0 = internal clock is enabled, 1 = internal clock is disabled
D6 0 = onboard DAC is active for sine and triangle wave output, 1 = put DAC to sleep for square wave output
D5 0 = output depends on D1, 1 = output is a square wave
D4 Reserved. Must be 0.
D3 0 = square wave of half frequency output, 1 = square wave output
D2 Reserved. Must be 0.
D1 If D5 = 1, D1 = 0. Otherwise 0 = sine output, 1 = triangle output
D0 Reserved. Must be 0.


Obviously this is a lot of information to pass to the waveform generator, but this setup can be performed with only a few SPI transfers. This is nearly all you need to know to set the AD9833, but there are two more critical relationships:





In other words, the output frequency and phase shift are not the values of the frequency or phase registers. They are related by the above equations, so the values you send to the registers need to be modified from the actual frequency and phase shift. For instance, if we sent 200 to the FREQ register and 100 to the PHASE register, and we were using a 20 MHz MCLK, we would output a 14.9 Hz wave with a phase shift of 0.15 radians.
In order to setup or update the AD9833 you first need to reset it, then transfer the frequency and phase information, then "unreset" it. For example, if we wanted to output a 20 kHz square wave with no phase shift, we would send the following:

spi_xfer(0b0010000101101000);

This resets the AD9833 (D8), tells it that we will be using the next two transfers to input both LSB and MSB (D13) of the FREQ0 register (D11), the internal clock is enabled (D7), the DAC has been put to sleep (D6), the output is to be a square wave (D5), and the square wave frequency is not to be divided by two (D3).

spi_xfer(0b0101100010010011);
spi_xfer(0b0100000000010000);

These transfers are writing to the value of the FREQ0 register (D15-D14), with the last 14 bits of each transfer representing first the LSB, then the MSB of the value. This writes a value of 0000000001000001100010010011 (268435 decimal) to the FREQ0 register. If we use the formula above, we see this corresponds to an output frequency of 20 kHz.

spi_xfer(0b1100000000000000);

This transfer is writing to the PHASE0 register (D15,D14,D13) and is writing a twelve bit value of zero (D11-D0).

spi_xfer(0b0000000001101000);

This transfer "unresets" the AD9833 (D8).

With a small variation in the values of the five transfers, all of the frequency and phase registers can be written to and output from the VOUT pin of the AD9833.

References