43.5 Computation Operation

The ADC module hardware is equipped with post-conversion computation features. These features provide post-processing functions such as digital filtering/averaging and threshold comparison. Based on computation results, the module can be configured to take additional samples or stop conversions and an interrupt may be asserted.

Figure 43-6. Computational Features Simplified Block Diagram

The operation of the ADC computational features is controlled by the MD bits.

The module can be operated in one of five modes:

Basic: This is a Legacy mode. In this mode, ADC conversion occurs on single (DSEN = 0) or double (DSEN = 1) samples. ADIF is set after each conversion is complete. ADCHxIF is set according to the Calculation mode.
Accumulate: With each trigger, the ADC conversion result is added to the accumulator and CNT increments. ADIF is set after each conversion. ADCHxIF is set according to the Calculation mode.
Average: With each trigger, the ADC conversion result is added to the accumulator. When the RPT number of samples have been accumulated, a threshold test is performed. Upon the next trigger, the accumulator is cleared. For the subsequent tests, additional RPT samples are required to be accumulated.
Burst Average: At the trigger, the accumulator is cleared. The ADC conversion results are then collected repetitively until RPT samples are accumulated and finally the threshold is tested.
Low-Pass Filter (LPF): With each trigger, the ADC conversion result is sent through a filter. When RPT samples have occurred, a threshold test is performed. Every trigger after that the ADC conversion result is sent through the filter and another threshold test is performed.

The five modes are summarized in the following table.

Table 43-2. Computation Modes
Mode	MD	Register Clear Event	Value after Cycle⁽¹⁾ Completion		Threshold Operations			Value at ADCHmIF Interrupt
Mode	MD	ADACC and CNT	ADACC	ADCNT	Retrigger	Threshold Test	Interrupt	AOV	ADFLTR	ADCNT
Basic	0	ACLR = `1`	Unchanged	Unchanged	No	Every Sample	If threshold=true	N/A	N/A	count
Accumulate	1	ACLR = `1`	S1 + ADACC or (S2-S1)⁽²⁾ + ADACC	If (ADCNT=0xFF): ADCNT, otherwise: ADCNT+1	No	Every Sample	If threshold=true	ADACC Overflow	ADACC/2^CRS	count
Average	2	ACLR = `1` or ADCNT≥ADRPT at GO set or retrigger	S1 + ADACC or (S2-S1) + ADACC	If (ADCNT=0xFF): ADCNT, otherwise: ADCNT+1	No	If ADCNT≥ADRPT	If threshold=true	ADACC Overflow	ADACC/2^CRS	count
Burst Average	3	ACLR = `1` or at GO set or retrigger	Each repetition: same as Average End with sum of all samples	Each repetition: same as Average End with ADCNT=ADRPT	Repeat while ADCNT<ADRPT	If ADCNT≥ADRPT	If threshold=true	ADACC Overflow	ADACC/2^CRS	ADRPT
Low-pass Filter	4	ACLR = `1`	S1+ADACC-ADACC/ 2^CRS or (S2-S1)+ADACC-ADACC/2^CRS	If (ADCNT=0xFF): ADCNT, otherwise: ADCNT+1	No	If ADCNT≥ADRPT	If threshold=true	ADACC Overflow	ADACC/2^CRS (Filtered Value)	count
Note: When DSEN = `0` then Cycle means one conversion. When DSEN = `1` then Cycle means two conversions. S1 and S2 are abbreviations for Sample 1 and Sample 2, respectively. When DSEN = `0`, S1 = ADRES; When DSEN = `1`, S1 = ADPREV and S2 = ADRES.