A data transfer frame between the device and the
host controller begins at the falling edge of the CONVST/CS pin
and ends when the device starts conversion at the subsequent rising edge. The host
controller can initiate a data transfer frame by bringing the
CONVST/CS signal low (as shown in Figure 7-25) after the end of the CONV phase, as described in the Section 7.4.2.3 section.
For a typical data transfer frame F:
- The host controller pulls
CONVST/CS low to initiate a data transfer frame. On
the falling edge of the CONVST/CS signal:
- RVS goes low,
indicating the beginning of the data transfer frame.
- The internal SCLK
counter is reset to 0.
- The device takes
control of the data bus. As illustrated in Figure 7-25, the contents of the output data word are loaded into the 32-bit
output shift register (OSR).
- The internal
configuration register is reset to 0000h, corresponding to a NOP
command.
- During the frame, the host controller provides clocks on the SCLK pin:
- On each SCLK capture edge, the SCLK counter is incremented and the data bit received on the SDI pin is shifted into the LSB of the input shift register.
- On each launch edge of the output clock (SCLK in this case), the MSB of the output shift register data is shifted out on the selected SDO-x pins.
- The status of the RVS pin depends on the output
protocol selection (see the Section 7.5.4.2 section).
- The host controller pulls the
CONVST/CS pin high to end the data transfer frame.
On the rising edge of CONVST/CS:
- The SDO-x pins go to
tri-state.
- As illustrated in
Figure 7-25, the contents of the input shift register are transferred to the
command processor for decoding and further action.
- RVS output goes low,
indicating the beginning of conversion.
After pulling CONVST/CS high,
the host controller must monitor for a low-to-high transition on the RVS pin or wait
for the tconv_max time (see the Section 6.6 table) to elapse before initiating a new data transfer
frame.
At the end of the data transfer frame F:
- If the SCLK counter = 32, then the device treats the frame F as an optimal data transfer frame for any read or write operation. At the end of an optimal data transfer frame, the command processor treats the 32-bit contents of the input shift register as a valid command word.
- If the SCLK counter is < 32, then the device treats the frame F as a short data transfer frame.
- The data write operation to the device in invalid and the device treats this frame as an NOP command.
- The output data bits transferred during a short frame on the SDO-x pins are still valid data. The host controller can use the short data transfer frame to read only the required number of MSB bits from the 32-bit output shift register.
- If the SCLK counter is > 32, then the device
treats the frame F as a long data transfer frame. At the end of a
long data transfer frame, the command processor treats the 32-bit contents
of the input shift register as a valid command word. There is no restriction
on the maximum number of clocks that can be provided within any data
transfer frame F. However, when the host controller provides a long data
transfer frame, the last 32 bits shifted into the device prior to the
CONVST/CS rising edge must constitute the desired
command.