SWRZ118 February 2022 CC1311P3
ADC samples can be delayed by 2 or 14 clock cycles (24 MHz) when XOSC_HF is turned on or off, resulting in sample jitter
Revision B
There is no dedicated clock source selection for the ADC clock. The clock is derived from either XOSC_HF or RCOSC_HF, but defaults to XOSC_HF-derived clock whenever this is turned on.
When the ADC clock source is switched from RCOSC_HF to XOSC_HF-derived clock, the clock will stop for 2 cycles (24 MHz).
When the ADC clock source is switched from XOSC_HF-derived clock to RCOSC_HF-derived clock, the clock will stop for additionally 12 clock cycles, as the RCOSC_HF-derived clock is not ready when switch is done.
SCLK_HF switches from RCOSC_HF to XOSC_HF at different times compared to ADC clock. This leads to sample jitter.
Use asynchronous sampling
To use the ADC in asynchronous mode by using the ADCBuf driver:
ADCBuf_Params params;
ADCBufCC26X2_ParamsExtension paramsExtension;
ADCBuf_Params_init(¶ms);
ADCBufCC26X2_ParamsExtension_init(¶msExtension);
paramsExtension.samplingMode = ADCBufCC26X2_SAMPING_MODE_ASYNCHRONOUS;
params.custom = ¶msExtension;
To use the ADC in asynchronous mode by using DriverLib API:
Call AUXADCEnableAsync()
to enable the ADC, instead of AUXADCEnableSync()
Example:
AUXADCEnableAsync(AUXADC_REF_FIXED, AUXADC_TRIGGER_GPT0A);
Please note the difference between the asynchronous and synchronous ADC modes:
Ensure that XOSC_HF is not turned on or off while the ADC is used.