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2.3.3 Operational Highlights for the Counter-Compare Submodule
2.3.4 Count Mode Timing Waveforms
Counter-Compare (CC) Submodule
The key signals associated with the counter-compare submodule are described in
.
Table 2-5. Counter-Compare Submodule Key Signals
Signal
Description of Event
Registers Compared
CTR = CMPA
Time-base counter equal to the active counter-compare A value
TBCTR = CMPA
CTR = CMPB
Time-base counter equal to the active counter-compare B value
TBCTR = CMPB
CTR = PRD
Time-base counter equal to the active period.
TBCTR = TBPRD
Used to load active counter-compare A and B registers from the
shadow register
shadow register
CTR = ZERO
Time-base counter equal to zero.
TBCTR = 0x0000
Used to load active counter-compare A and B registers from the
shadow register
shadow register
The counter-compare submodule is responsible for generating two independent compare events based on
two compare registers:
two compare registers:
1. CTR = CMPA: Time-base counter equal to counter-compare A register (TBCTR = CMPA).
2. CTR = CMPB: Time-base counter equal to counter-compare B register (TBCTR = CMPB).
2. CTR = CMPB: Time-base counter equal to counter-compare B register (TBCTR = CMPB).
For up-count or down-count mode, each event occurs only once per cycle. For up-down-count mode each
event occurs twice per cycle if the compare value is between 0x0000-TBPRD and once per cycle if the
compare value is equal to 0x0000 or equal to TBPRD. These events are fed into the action-qualifier
submodule where they are qualified by the counter direction and converted into actions if enabled. Refer
to
event occurs twice per cycle if the compare value is between 0x0000-TBPRD and once per cycle if the
compare value is equal to 0x0000 or equal to TBPRD. These events are fed into the action-qualifier
submodule where they are qualified by the counter direction and converted into actions if enabled. Refer
to
for more details.
The counter-compare registers CMPA and CMPB each have an associated shadow register. Shadowing
provides a way to keep updates to the registers synchronized with the hardware. When shadowing is
used, updates to the active registers only occurs at strategic points. This prevents corruption or spurious
operation due to the register being asynchronously modified by software. The memory address of the
active register and the shadow register is identical. Which register is written to or read from is determined
by the CMPCTL[SHDWAMODE] and CMPCTL[SHDWBMODE] bits. These bits enable and disable the
CMPA shadow register and CMPB shadow register respectively. The behavior of the two load modes is
described below:
provides a way to keep updates to the registers synchronized with the hardware. When shadowing is
used, updates to the active registers only occurs at strategic points. This prevents corruption or spurious
operation due to the register being asynchronously modified by software. The memory address of the
active register and the shadow register is identical. Which register is written to or read from is determined
by the CMPCTL[SHDWAMODE] and CMPCTL[SHDWBMODE] bits. These bits enable and disable the
CMPA shadow register and CMPB shadow register respectively. The behavior of the two load modes is
described below:
•
Shadow Mode:
The shadow mode for the CMPA is enabled by clearing the CMPCTL[SHDWAMODE] bit and the
shadow register for CMPB is enabled by clearing the CMPCTL[SHDWBMODE] bit. Shadow mode is
enabled by default for both CMPA and CMPB.
If the shadow register is enabled then the content of the shadow register is transferred to the active
register on one of the following events:
The shadow mode for the CMPA is enabled by clearing the CMPCTL[SHDWAMODE] bit and the
shadow register for CMPB is enabled by clearing the CMPCTL[SHDWBMODE] bit. Shadow mode is
enabled by default for both CMPA and CMPB.
If the shadow register is enabled then the content of the shadow register is transferred to the active
register on one of the following events:
–
CTR = PRD: Time-base counter equal to the period (TBCTR = TBPRD).
–
CTR = Zero: Time-base counter equal to zero (TBCTR = 0x0000)
–
Both CTR = PRD and CTR = Zero
Which of these three events is specified by the CMPCTL[LOADAMODE] and CMPCTL[LOADBMODE]
register bits. Only the active register contents are used by the counter-compare submodule to generate
events to be sent to the action-qualifier.
register bits. Only the active register contents are used by the counter-compare submodule to generate
events to be sent to the action-qualifier.
•
Immediate Load Mode:
If immediate load mode is selected (i.e., TBCTL[SHADWAMODE] = 1 or TBCTL[SHADWBMODE] = 1),
then a read from or a write to the register will go directly to the active register.
If immediate load mode is selected (i.e., TBCTL[SHADWAMODE] = 1 or TBCTL[SHADWBMODE] = 1),
then a read from or a write to the register will go directly to the active register.
The counter-compare module can generate compare events in all three count modes:
•
Up-count mode: used to generate an asymmetrical PWM waveform.
•
Down-count mode: used to generate an asymmetrical PWM waveform.
34
ePWM Submodules
SPRU791D – November 2004 – Revised October 2007