Once the ePWM has been configured to provide conventional PWM of a given frequency and polarity, the HRPWM is configured by programming the HRCNFG register in that particular ePWM module's register space. This register provides the following configuration options:
Edge Mode
The MEP can be programmed to provide precise position control on the rising edge (RE), falling edge (FE) or both edges (BE) at the same time. FE and RE are used for power topologies requiring duty cycle control (CMPA or CMPB high-resolution control), while BE is used for topologies requiring phase shifting, for example, phase shifted full bridge (TBPHS or TBPRD high-resolution control).
Control Mode
The MEP is programmed to be controlled either
from the CMPAHR/CMPBHR register in case of duty
cycle control or the TBPHSHR register (phase
control). RE or FE control mode can be used with
the CMPAHR or CMPBHR register. BE control mode can
be used with the TBPHSHR register. When the MEP is
controlled from the TBPRDHR register (period
control), the duty cycle and phase can also be
controlled using their respective high-resolution
registers.
Shadow Mode
This mode provides the same shadowing (double buffering) option as in regular PWM mode. This option is valid only when operating from the CMPAHR, CMPBHR, and TBPRDHR registers and can be chosen to be the same as the regular load option for the CMPA/CMPB register. If TBPHSHR is used, then this option has no effect.
High-Resolution B Signal Control
The B signal path of an ePWM channel can generate a high-resolution output by outputting an inverted version of the high-resolution ePWMxA signal on the ePWMxB pin. A Type 2 or Type 4 HRPWM module can also enable high-resolution features on the B signal path independently of the A signal path as well.
Swap ePWMxA and ePWMxB Outputs
This mode enables the swapping of the high-resolution A and B outputs. The mode selection allows either A and B Outputs Unchanged or A Output Comes Out On B and B Output Comes Out On A.
Auto-conversion Mode
This mode is used in conjunction with the scale factor optimization (SFO) software only. For a type 4 HRPWM module, below is a description of the Auto-conversion Mode taking CMPAHR as an example. If auto-conversion is enabled, CMPAHR = fraction(PWMduty*PWMperiod)<<8. The scale factor optimization software calculates the MEP scale factor in the background code and automatically updates the HRMSTEP register with the calculated number of MEP steps per coarse step. The MEP Calibration Module then uses the values in the HRMSTEP and CMPAHR registers to automatically calculate the appropriate number of MEP steps represented by the fractional duty cycle and moves the high-resolution ePWM signal edge accordingly. If auto-conversion is disabled, the CMPAHR register behaves like a type 0 HRPWM module and CMPAHR = (fraction(PWMduty * PWMperiod) * MEP Scale Factor + 0.5)<<8). All calculations need to be performed by your code in this mode, and the HRMSTEP register is ignored. Auto-conversion for high-resolution period has the same behavior as auto-conversion for high-resolution duty cycle. Auto-conversion must always be enabled for high-resolution period mode.
Note:
If the HRPWM module is configured in UP-DOWN counter mode, the shadow mode for the HRPWM registers must be set to load on both ZERO AND PERIOD. New values from the user are loaded to the shadow registers only at CTR=ZERO, but the shadow mode of for the registers must be set to both ZERO AND PERIOD. The CTR=PRD event is used for specific internal logic inside the HRPWM module.
Auto-conversion Mode performs the calculation for CMPBHR , DBREDHR, and DBFEDHR. The scale factor optimization software calculates the MEP scale factor in the background code and automatically updates the HRMSTEP register with the calculated number of MEP steps per coarse step. The MEP Calibration Module then uses the values in the HRMSTEP and CMPBHR or DBREDHR/DBFEDHR register to automatically calculate the appropriate number of MEP steps represented by the fractional components and moves the high-resolution ePWM signal edge accordingly. If auto-conversion is disabled, CMPBHR behaves the same as CMPAHR. CMPBHR = (fraction(PWMduty * PWMperiod) * MEP Scale Factor + 0.5)<<8).
You are expected to disable protection for both ePWM1 and HRPWM when the application requires access to either of these modules.