MCBSTM32EXL Keil, MCBSTM32EXL Datasheet - Page 280

MCBSTM32EXL

Manufacturer Part Number

MCBSTM32EXL

Description

BOARD EVALUATION FOR STM32F103ZE

Manufacturer

Keil

Datasheets

1.MCBSTM32EXL.pdf (995 pages)

2.MCBSTM32EXL.pdf (1 pages)

Specifications of MCBSTM32EXL

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Advanced-control timers (TIM1&TIM8)

Note:

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must insert a delay (dummy instruction) before reading it correctly. This is because you write

the asynchronous signal and read the synchronous signal.

When a break occurs (selected level on the break input):

●

The break inputs is acting on level. Thus, the MOE cannot be set while the break input is

active (neither automatically nor by software). In the meantime, the status flag BIF cannot be

cleared.

The break can be generated by the BRK input which has a programmable polarity and an

enable bit BKE in the TIMx_BDTR Register.

In addition to the break input and the output management, a write protection has been

implemented inside the break circuit to safeguard the application. It allows you to freeze the

configuration of several parameters (dead-time duration, OCx/OCxN polarities and state

when disabled, OCxM configurations, break enable and polarity). You can choose from 3

levels of protection selected by the LOCK bits in the TIMx_BDTR register. Refer to

Section 13.4.18: TIM1&TIM8 break and dead-time register (TIMx_BDTR) on page

LOCK bits can be written only once after an MCU reset.

The

Figure 88

The MOE bit is cleared asynchronously, putting the outputs in inactive state, idle state

or in reset state (selected by the OSSI bit). This feature functions even if the MCU

oscillator is off.

Each output channel is driven with the level programmed in the OISx bit in the

TIMx_CR2 register as soon as MOE=0. If OSSI=0 then the timer releases the enable

output else the enable output remains high.

When complementary outputs are used:

–

The break status flag (BIF bit in the TIMx_SR register) is set. An interrupt can be

generated if the BIE bit in the TIMx_DIER register is set. A DMA request can be sent if

the BDE bit in the TIMx_DIER register is set.

If the AOE bit in the TIMx_BDTR register is set, the MOE bit is automatically set again

at the next update event UEV. This can be used to perform a regulation, for instance.

Else, MOE remains low until you write it to ‘1’ again. In this case, it can be used for

security and you can connect the break input to an alarm from power drivers, thermal

sensors or any security components.

The outputs are first put in reset state inactive state (depending on the polarity).

This is done asynchronously so that it works even if no clock is provided to the

timer.

If the timer clock is still present, then the dead-time generator is reactivated in

order to drive the outputs with the level programmed in the OISx and OISxN bits

after a dead-time. Even in this case, OCx and OCxN cannot be driven to their

active level together. Note that because of the resynchronization on MOE, the

dead-time duration is a bit longer than usual (around 2 ck_tim clock cycles).

If OSSI=0 then the timer releases the enable outputs else the enable outputs

remain or become high as soon as one of the CCxE or CCxNE bits is high.

shows an example of behavior of the outputs in response to a break.

Doc ID 13902 Rev 9

314. The

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MCBSTM32EXL Keil, MCBSTM32EXL Datasheet - Page 280

MCBSTM32EXL

Specifications of MCBSTM32EXL

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