18. General-purpose timers (TIM9 to TIM14)

18.1 TIM9 to TIM14 introduction

The TIM9 to TIM14 general-purpose timers consist of a 16-bit auto-reload counter driven by a programmable prescaler.

They may be used for a variety of purposes, including measuring the pulse lengths of input signals (input capture) or generating output waveforms (output compare, PWM).

Pulse lengths and waveform periods can be modulated from a few microseconds to several milliseconds using the timer prescaler and the RCC clock controller prescalers.

The TIM9 to TIM14 timers are completely independent, and do not share any resources. They can be synchronized together as described in Section 18.3.12 .

18.2 TIM9 to TIM14 main features

18.2.1 TIM9/TIM12 main features

The features of the TIM9 to TIM14 general-purpose timers include:

• 16-bit auto-reload upcounter
• 16-bit programmable prescaler used to divide the counter clock frequency by any factor between 1 and 65536 (can be changed “on the fly”)
• Up to 2 independent channels for:
- – Input capture
- – Output compare
- – PWM generation (edge-aligned mode)
- – One-pulse mode output
• Synchronization circuit to control the timer with external signals and to interconnect several timers together
• Interrupt generation on the following events:
- – Update: counter overflow, counter initialization (by software or internal trigger)
- – Trigger event (counter start, stop, initialization or count by internal trigger)
- – Input capture
- – Output compare

Figure 204. General-purpose timer block diagram (TIM9 and TIM12)

Figure 204. General-purpose timer block diagram (TIM9 and TIM12). The diagram shows the internal architecture of a general-purpose timer. At the top, an 'Internal clock (CK_INT)' is connected to a 'Trigger controller' and a 'Slave mode controller'. Below this, four external interrupt lines (ITR0, ITR1, ITR2, ITR3) are connected to an 'ITR' block, which outputs 'TRC' and 'TRGI' signals. 'TRGI' is connected to the 'Slave mode controller'. The 'Slave mode controller' also receives 'Reset, Enable, Count' signals and outputs 'TGI'. Below the trigger section, the 'CNT COUNTER' is shown, which is connected to an 'Auto-reload register' (with 'U' event) and a 'PSC Prescaler' (with 'CK_PSC' input and 'CK_CNT' output). The counter has two independent channels, 'TIMx_CH1' and 'TIMx_CH2'. Each channel consists of an 'Input filter & Edge detector' (receiving 'TI1' or 'TI2'), followed by 'IC1' or 'IC2' blocks with 'Prescaler' and 'CC1PS' or 'CC2PS' registers. These are connected to 'Capture/Compare 1 register' and 'Capture/Compare 2 register' respectively, which have 'CC1I' or 'CC2I' control bits. The registers are connected to 'output control' blocks (OC1REF, OC2REF) which drive the 'OC1' and 'OC2' pins. A 'Notes' box at the bottom left explains symbols: 'Reg' for preload registers, a downward arrow for 'event', and a diagonal arrow for 'interrupt'. The identifier 'ai17190' is in the bottom right corner.

18.2.2 TIM10/TIM11 and TIM13/TIM14 main features

The features of general-purpose timers TIM10/TIM11 and TIM13/TIM14 include:

• 16-bit auto-reload upcounter
• 16-bit programmable prescaler used to divide the counter clock frequency by any factor between 1 and 65536 (can be changed “on the fly”)
• independent channel for:
- – Input capture
- – Output compare
- – PWM generation (edge-aligned mode)
- – One-pulse mode output
• Interrupt generation on the following events:
- – Update: counter overflow, counter initialization (by software)
- – Input capture
- – Output compare

Figure 205. General-purpose timer block diagram (TIM10/11/13/14)

The diagram illustrates the internal architecture of a general-purpose timer (TIM10/11/13/14). At the top, an 'Internal clock (CK_INT)' is connected to a 'Trigger Controller'. The 'Trigger Controller' has an 'Enable counter' output. Below it, an 'Autoreload register' is shown with 'U' (update) and 'UI' (update interrupt) signals, and 'Stop, Clear' inputs. A 'PSC prescaler' receives 'CK_PSC' and outputs 'CK_CNT' to a 'CNT counter' (labeled '+/-'). The 'CNT counter' is connected to a 'Capture/Compare 1 register' (labeled 'CC1'). This register has 'U' (update) and 'UI' (update interrupt) signals, and 'IC1PS' (input capture prescaler) and 'OC1REF' (output compare reference) inputs. An 'Input filter & edge detector' receives 'TI1' and outputs 'TI1FP1' and 'IC1' (input capture). The 'IC1' signal is processed by a 'Prescaler' (outputting 'IC1PS') before entering the 'Capture/Compare 1 register'. The 'Capture/Compare 1 register' also outputs 'CC1' to an 'output control' block, which generates 'OC1' (output compare 1) and 'TIMx_CH1' (timer output). A 'Notes' box at the bottom right explains the symbols: 'Reg' for preload registers, a single arrow for 'event', and a double arrow for 'interrupt & DMA output'. The identifier 'ai17725c' is in the bottom right corner.

General-purpose timer block diagram (TIM10/11/13/14) showing internal clock, trigger controller, prescalers, counter, capture/compare register, and output control.

18.3 TIM9 to TIM14 functional description

18.3.1 Time-base unit

The main block of the timer is a 16-bit counter with its related auto-reload register. The counter counts up.

The counter clock can be divided by a prescaler.

The counter, the auto-reload register and the prescaler register can be written or read by software. This is true even when the counter is running.

The time-base unit includes:

• Counter register (TIMx_CNT)
• Prescaler register (TIMx_PSC)
• Auto-reload register (TIMx_ARR)

The auto-reload register is preloaded. Writing to or reading from the auto-reload register accesses the preload register. The content of the preload register are transferred into the shadow register permanently or at each update event (UEV), depending on the auto-reload preload enable bit (ARPE) in TIMx_CR1 register. The update event is sent when the counter reaches the overflow and if the UDIS bit equals 0 in the TIMx_CR1 register. It can also be generated by software. The generation of the update event is described in details for each configuration.

The counter is clocked by the prescaler output CK_CNT, which is enabled only when the counter enable bit (CEN) in TIMx_CR1 register is set (refer also to the slave mode controller description to get more details on counter enabling).

Note that the counter starts counting 1 clock cycle after setting the CEN bit in the TIMx_CR1 register.

Prescaler description

The prescaler can divide the counter clock frequency by any factor between 1 and 65536. It is based on a 16-bit counter controlled through a 16-bit register (in the TIMx_PSC register). It can be changed on the fly as this control register is buffered. The new prescaler ratio is taken into account at the next update event.

Figure 206 and Figure 207 give some examples of the counter behavior when the prescaler ratio is changed on the fly.

Figure 206. Counter timing diagram with prescaler division change from 1 to 2

Timing diagram for Figure 206 showing counter behavior when prescaler division changes from 1 to 2. The diagram includes signals for CK_PSC, CEN, Timerclock (CK_CNT), Counter register, Update event (UEV), Prescaler control register, Prescaler buffer, and Prescaler counter. The counter register values are F7, F8, F9, FA, FB, FC, 00, 01, 02, 03. The prescaler control register changes from 0 to 1. The prescaler counter counts 0, 1, 0, 1, 0, 1, 0, 1.

The diagram illustrates the timing of a timer when the prescaler division is changed from 1 to 2. The signals shown are:

CK_PSC : Prescaler clock signal, a periodic square wave.
CEN : Counter enable signal, which goes high to enable counting.
Timerclock = CK_CNT : The clock signal for the counter, which is derived from CK_PSC.
Counter register : Shows the count values: F7, F8, F9, FA, FB, FC, 00, 01, 02, 03.
Update event (UEV) : A pulse generated when the counter reaches its maximum value (FC) and rolls over to 00.
Prescaler control register : Shows the prescaler division value. It is initially 0 (division by 1) and is changed to 1 (division by 2) via a write to TIMx_PSC.
Prescaler buffer : A buffer that latches the new prescaler value from the control register.
Prescaler counter : A counter that divides the CK_PSC frequency by the value in the prescaler buffer. It counts 0, 1, 0, 1, 0, 1, 0, 1.

The change in the prescaler control register value from 0 to 1 occurs after the counter reaches FC. The new value is latched into the prescaler buffer at the next update event (UEV). Consequently, the timerclock (CK_CNT) frequency is halved after the UEV.

MS31076V2

Timing diagram for Figure 206 showing counter behavior when prescaler division changes from 1 to 2. The diagram includes signals for CK_PSC, CEN, Timerclock (CK_CNT), Counter register, Update event (UEV), Prescaler control register, Prescaler buffer, and Prescaler counter. The counter register values are F7, F8, F9, FA, FB, FC, 00, 01, 02, 03. The prescaler control register changes from 0 to 1. The prescaler counter counts 0, 1, 0, 1, 0, 1, 0, 1.

Figure 207. Counter timing diagram with prescaler division change from 1 to 4

Timing diagram for Figure 207 showing counter behavior when prescaler division changes from 1 to 4. The diagram includes signals for CK_PSC, CEN, Timerclock (CK_CNT), Counter register, Update event (UEV), Prescaler control register, Prescaler buffer, and Prescaler counter. The counter register values are F7, F8, F9, FA, FB, FC, 00, 01. The prescaler control register changes from 0 to 3. The prescaler counter counts 0, 1, 2, 3, 0, 1, 2, 3.

The diagram illustrates the timing of a timer when the prescaler division is changed from 1 to 4. The signals shown are:

CK_PSC : Prescaler clock signal, a periodic square wave.
CEN : Counter enable signal, which goes high to enable counting.
Timerclock = CK_CNT : The clock signal for the counter, which is derived from CK_PSC.
Counter register : Shows the count values: F7, F8, F9, FA, FB, FC, 00, 01.
Update event (UEV) : A pulse generated when the counter reaches its maximum value (FC) and rolls over to 00.
Prescaler control register : Shows the prescaler division value. It is initially 0 (division by 1) and is changed to 3 (division by 4) via a write to TIMx_PSC.
Prescaler buffer : A buffer that latches the new prescaler value from the control register.
Prescaler counter : A counter that divides the CK_PSC frequency by the value in the prescaler buffer. It counts 0, 1, 2, 3, 0, 1, 2, 3.

The change in the prescaler control register value from 0 to 3 occurs after the counter reaches FC. The new value is latched into the prescaler buffer at the next update event (UEV). Consequently, the timerclock (CK_CNT) frequency is divided by 4 after the UEV.

MS31077V2

Timing diagram for Figure 207 showing counter behavior when prescaler division changes from 1 to 4. The diagram includes signals for CK_PSC, CEN, Timerclock (CK_CNT), Counter register, Update event (UEV), Prescaler control register, Prescaler buffer, and Prescaler counter. The counter register values are F7, F8, F9, FA, FB, FC, 00, 01. The prescaler control register changes from 0 to 3. The prescaler counter counts 0, 1, 2, 3, 0, 1, 2, 3.

18.3.2 Counter modes

Upcounting mode

In upcounting mode, the counter counts from 0 to the auto-reload value (content of the TIMx_ARR register), then restarts from 0 and generates a counter overflow event.

Setting the UG bit in the TIMx_EGR register (by software or by using the slave mode controller on TIM9 and TIM12) also generates an update event.

The UEV event can be disabled by software by setting the UDIS bit in the TIMx_CR1 register. This is to avoid updating the shadow registers while writing new values in the preload registers. Then no update event occurs until the UDIS bit has been written to 0. However, the counter restarts from 0, as well as the counter of the prescaler (but the prescale rate does not change). In addition, if the URS bit (update request selection) in TIMx_CR1 register is set, setting the UG bit generates an update event UEV but without setting the UIF flag (thus no interrupt is sent). This is to avoid generating both update and capture interrupts when clearing the counter on the capture event.

When an update event occurs, all the registers are updated and the update flag (UIF bit in TIMx_SR register) is set (depending on the URS bit):

• The auto-reload shadow register is updated with the preload value (TIMx_ARR),
• The buffer of the prescaler is reloaded with the preload value (content of the TIMx_PSC register).

The following figures show some examples of the counter behavior for different clock frequencies when TIMx_ARR=0x36.

Figure 208. Counter timing diagram, internal clock divided by 1

The timing diagram illustrates the counter's behavior in upcounting mode. The top signal, CK_PSC, is a periodic square wave. Below it, CNT_EN is a horizontal line that goes high to enable the counter. The third signal, Timerclock = CK_CNT, is a square wave that starts when CNT_EN goes high. The fourth signal, 'Counter register', shows a sequence of values: 31, 32, 33, 34, 35, 36, 00, 01, 02, 03, 04, 05, 06, 07. The values 32 through 36 are highlighted with a shaded background. The fifth signal, 'Counter overflow', is a pulse that goes high when the counter reaches 36 and returns low when it rolls over to 00. The sixth signal, 'Update event (UEV)', is a pulse that goes high at the same time as the overflow. The bottom signal, 'Update interrupt flag (UIF)', is a pulse that goes high at the same time as the overflow and returns low before the UEV pulse ends. Vertical dashed lines mark the clock edges corresponding to the counter values. The diagram is labeled MS31078V3 in the bottom right corner.

Timing diagram for upcounting mode. The diagram shows the relationship between the prescaler clock (CK_PSC), counter enable (CNT_EN), timer clock (CK_CNT), counter register values, counter overflow, update event (UEV), and update interrupt flag (UIF).

Figure 209. Counter timing diagram, internal clock divided by 2

Timing diagram for internal clock divided by 2. It shows CK_PSC (square wave), CNT_EN (high), Timerclock = CK_CNT (half frequency of CK_PSC), Counter register values (0034, 0035, 0036, 0000, 0001, 0002, 0003), Counter overflow (pulse at 0036), Update event (UEV) (pulse at 0000), and Update interrupt flag (UIF) (high at 0000). MS31079V3

Figure 210. Counter timing diagram, internal clock divided by 4

Timing diagram for internal clock divided by 4. It shows CK_PSC (square wave), CNT_EN (high), Timerclock = CK_CNT (quarter frequency of CK_PSC), Counter register values (0035, 0036, 0000, 0001), Counter overflow (pulse at 0036), Update event (UEV) (pulse at 0000), and Update interrupt flag (UIF) (high at 0000). MS31080V3

Figure 211. Counter timing diagram, internal clock divided by N

Timing diagram for internal clock divided by N. It shows CK_PSC (square wave), Timerclock = CK_CNT (divided frequency), Counter register values (1F, 20, 00), Counter overflow (pulse at 20), Update event (UEV) (pulse at 00), and Update interrupt flag (UIF) (high at 00). MS31081V3

Figure 212. Counter timing diagram, update event when ARPE=0
(TIMx_ARR not preloaded)

Timing diagram for Figure 212 showing counter behavior when ARPE=0. It includes signals for CK_PSC, CEN, Timerclock (CK_CNT), Counter register (counting 31 to 07), Counter overflow, Update event (UEV), Update interrupt flag (UIF), and Auto-reload preload register (FF to 36).

This timing diagram illustrates the operation of a general-purpose timer when the ARPE bit is 0. The diagram shows the following signals over time:

CK_PSC : A periodic clock signal.
CEN : Counter Enable signal, shown as a high-level signal.
Timerclock = CK_CNT : The counter clock, which is a divided version of CK_PSC.
Counter register : Shows the counter values. It starts at 31, counts up through 32, 33, 34, 35, 36, 00, 01, 02, 03, 04, 05, 06, and 07. A vertical dashed line marks the update event at the transition from 36 to 00.
Counter overflow : A signal that pulses high at the update event (when the counter rolls over from 36 to 00).
Update event (UEV) : A signal that pulses high at the update event.
Update interrupt flag (UIF) : A signal that pulses high at the update event.
Auto-reload preload register : Shows the register value. It starts at FF, and an arrow labeled "Write a new value in TIMx_ARR" points to a change to 36. The register value updates to 36 at the update event.

MS31082V3

Timing diagram for Figure 212 showing counter behavior when ARPE=0. It includes signals for CK_PSC, CEN, Timerclock (CK_CNT), Counter register (counting 31 to 07), Counter overflow, Update event (UEV), Update interrupt flag (UIF), and Auto-reload preload register (FF to 36).

Figure 213. Counter timing diagram, update event when ARPE=1
(TIMx_ARR preloaded)

Timing diagram for Figure 213 showing counter behavior when ARPE=1. It includes signals for CK_PSC, CEN, Timerclock (CK_CNT), Counter register (counting F0 to 07), Counter overflow, Update event (UEV), Update interrupt flag (UIF), Auto-reload preload register (F5 to 36), and Auto-reload shadow register (F5 to 36).

This timing diagram illustrates the operation of a general-purpose timer when the ARPE bit is 1. The diagram shows the following signals over time:

CK_PSC : A periodic clock signal.
CEN : Counter Enable signal, shown as a high-level signal.
Timerclock = CK_CNT : The counter clock, which is a divided version of CK_PSC.
Counter register : Shows the counter values. It starts at F0, counts up through F1, F2, F3, F4, F5, 00, 01, 02, 03, 04, 05, 06, and 07. A vertical dashed line marks the update event at the transition from F5 to 00.
Counter overflow : A signal that pulses high at the update event (when the counter rolls over from F5 to 00).
Update event (UEV) : A signal that pulses high at the update event.
Update interrupt flag (UIF) : A signal that pulses high at the update event.
Auto-reload preload register : Shows the register value. It starts at F5, and an arrow labeled "Write a new value in TIMx_ARR" points to a change to 36. The register value updates to 36 at the update event.
Auto-reload shadow register : Shows the shadow register value. It starts at F5 and updates to 36 at the update event.

MS31083V2

Timing diagram for Figure 213 showing counter behavior when ARPE=1. It includes signals for CK_PSC, CEN, Timerclock (CK_CNT), Counter register (counting F0 to 07), Counter overflow, Update event (UEV), Update interrupt flag (UIF), Auto-reload preload register (F5 to 36), and Auto-reload shadow register (F5 to 36).

18.3.3 Clock selection

The counter clock can be provided by the following clock sources:

• Internal clock (CK_INT)
• External clock mode1 (for TIM9 and TIM12 ): external input pin (TIx)
• Internal trigger inputs (ITRx) (for TIM9 and TIM12 ): connecting the trigger output from another timer. Refer to Using one timer as prescaler for another for more details.

Internal clock source (CK_INT)

The internal clock source is the default clock source for TIM10/TIM11 and TIM13/TIM14.

For TIM9 and TIM12, the internal clock source is selected when the slave mode controller is disabled (SMS='000'). The CEN bit in the TIMx_CR1 register and the UG bit in the TIMx_EGR register are then used as control bits and can be changed only by software (except for UG which remains cleared). As soon as the CEN bit is programmed to 1, the prescaler is clocked by the internal clock CK_INT.

Figure 214 shows the behavior of the control circuit and the upcounter in normal mode, without prescaler.

Figure 214. Control circuit in normal mode, internal clock divided by 1

Timing diagram showing the relationship between internal clock, control signals (CEN, UG, CNT_INIT), counter clock, and counter register values. The diagram illustrates the sequence of events for starting the counter in normal mode with an internal clock divided by 1.

The timing diagram shows five horizontal lines representing different signals over time, separated by vertical dashed lines indicating key events:

Internal clock: A continuous square wave signal.
CEN=CNT_EN: A signal that goes high at the first dashed line, enabling the counter.
UG: A signal that goes high at the second dashed line, triggering the update of the counter register.
CNT_INIT: A signal that goes high at the second dashed line, indicating the initial count value has been loaded.
Counter clock = CK_CNT = CK_PSC: A signal that starts at the first dashed line, derived from the internal clock.
Counter register: A sequence of values: 31, 32, 33, 34, 35, 36, 00, 01, 02, 03, 04, 05, 06, 07. The values 31-36 are shown before the first dashed line. At the first dashed line, the value becomes 32. At the second dashed line, it becomes 00. Subsequent values (01-07) appear at regular intervals following the counter clock.

MS31085V2

Timing diagram showing the relationship between internal clock, control signals (CEN, UG, CNT_INIT), counter clock, and counter register values. The diagram illustrates the sequence of events for starting the counter in normal mode with an internal clock divided by 1.

External clock source mode 1(TIM9 and TIM12)

This mode is selected when SMS='111' in the TIMx_SMCR register. The counter can count at each rising or falling edge on a selected input.

Figure 215. TI2 external clock connection example

Figure 215: TI2 external clock connection example. This block diagram shows the internal logic for using the TI2 pin as an external clock source. The TI2 pin is connected to a 'Filter' block, which is controlled by the ICF[3:0] bits in the TIMx_CCMR1 register. The output of the filter goes to an 'Edge detector' block. The edge detector has two outputs: 'TI2F_Rising' and 'TI2F_Falling'. These are connected to a multiplexer (MUX) labeled 'CC2P' in the TIMx_CCER register. The MUX selects between the rising and falling edges. The selected signal is then connected to another MUX labeled 'TRGI' in the TIMx_SMCR register. This MUX has several input options: 0xx (ITRx), 100 (TI1_ED), 101 (TI1FP1), and 110 (TI2FP2). The output of this MUX is connected to the 'External clock mode 1' block, which also receives input from 'TI2F' or 'TI1F' pins. The 'External clock mode 1' block outputs the 'CK_PSC' signal. There is also an 'Internal clock mode' block that receives 'CK_INT' (internal clock) and is controlled by 'SMS[2:0]' bits in the TIMx_SMCR register. The 'CK_PSC' signal is also connected to the 'Internal clock mode' block.

For example, to configure the upcounter to count in response to a rising edge on the TI2 input, use the following procedure:

1. Configure channel 2 to detect rising edges on the TI2 input by writing CC2S = '01' in the TIMx_CCMR1 register.
2. Configure the input filter duration by writing the IC2F[3:0] bits in the TIMx_CCMR1 register (if no filter is needed, keep IC2F='0000').
3. Select the rising edge polarity by writing CC2P='0' and CC2NP='0' in the TIMx_CCER register.
4. Configure the timer in external clock mode 1 by writing SMS='111' in the TIMx_SMCR register.
5. Select TI2 as the trigger input source by writing TS='110' in the TIMx_SMCR register.
6. Enable the counter by writing CEN='1' in the TIMx_CR1 register.

Note: The capture prescaler is not used for triggering, so it does not need to be configured.

When a rising edge occurs on TI2, the counter counts once and the TIF flag is set.

The delay between the rising edge on TI2 and the actual clock of the counter is due to the resynchronization circuit on TI2 input.

Figure 216. Control circuit in external clock mode 1

Figure 216: Control circuit in external clock mode 1. This timing diagram shows the relationship between the TI2 input, CNT_EN, Counter clock (CK_CNT = CK_PSC), Counter register, and TIF flag. The TI2 input is a periodic square wave. The CNT_EN signal is a horizontal line. The Counter clock (CK_CNT = CK_PSC) is a square wave that toggles on the rising edges of the TI2 input. The Counter register shows values 34, 35, and 36, with the count increasing on each rising edge of the counter clock. The TIF flag is a horizontal line that goes high when the counter overflows (from 35 to 36) and is then cleared by writing TIF = 0.

18.3.4 Capture/compare channels

Each Capture/Compare channel is built around a capture/compare register (including a shadow register), a input stage for capture (with digital filter, multiplexing and prescaler) and an output stage (with comparator and output control).

Figure 217 to Figure 219 give an overview of one capture/compare channel.

The input stage samples the corresponding TIx input to generate a filtered signal TIxF. Then, an edge detector with polarity selection generates a signal (TIxFPx) which can be used as trigger input by the slave mode controller or as the capture command. It is prescaled before the capture register (ICxPS).

Figure 217. Capture/compare channel (example: channel 1 input stage)

Block diagram of the input stage of a capture/compare channel (Channel 1).

The diagram illustrates the input stage of a capture/compare channel. The signal flow is as follows:

An external input TI1 is processed by a Filter downcounter (controlled by ICF[3:0] from TIMx_CCMR1 ) to produce a filtered signal TI1F .
The TI1F signal is then processed by an Edge detector (controlled by CC1P/CC1NP from TIMx_CCER ) to generate two signals: TI1F_Rising and TI1F_Falling .
These signals are multiplexed (0 for Rising, 1 for Falling) to produce TI1FP1 .
The TI1FP1 signal is ANDed with TI1F_ED (from the slave mode controller) to produce the final output signal TI1F_ED .
The TI1FP1 signal is also multiplexed (0 for TI1FP1, 1 for TI2FP1 from channel 2) to produce IC1 .
The IC1 signal is then processed by a Divider (with prescaler values /1, /2, /4, /8 controlled by ICPS[1:0] from TIMx_CCMR1 ) to produce the final output signal IC1PS .
Control signals include CC1P/CC1NP and CC1E from TIMx_CCER , and ICF[3:0] , CC1S[1:0] , and ICPS[1:0] from TIMx_CCMR1 .
A TRC signal from the slave mode controller is also shown as an input to the multiplexers.

Block diagram of the input stage of a capture/compare channel (Channel 1).

The output stage generates an intermediate waveform which is then used for reference: OCxRef (active high). The polarity acts at the end of the chain.

Figure 218. Capture/compare channel 1 main circuit

Figure 218. Capture/compare channel 1 main circuit diagram. This block diagram shows the internal architecture of capture/compare channel 1. At the top, an APB Bus connects to an MCU-peripheral interface. This interface has two 8-bit paths (high and low, if 16-bit) to a Capture/compare preload register. The preload register is connected to a Capture/compare shadow register via a 'compare_transfer' signal. The shadow register is connected to a Counter and a Comparator. The Counter outputs CNT>CCR1 and CNT=CCR1 to the Comparator. The Comparator's output is connected to an Output mode controller. The Output mode controller also receives inputs from CC1S[1], CC1S[0], OC1PE, and UEV (from time base unit). The Output mode controller generates an OC1PE signal. The Counter is also connected to a Capture block, which receives inputs from IC1PS, CC1E, and CC1G (from TIM1_EGR). The Capture block generates a 'capture_transfer' signal to the shadow register. The preload register also has 'read_in_progress' and 'write_in_progress' signals. Read and write operations are controlled by Read CCR1H (S), Read CCR1L (R), write CCR1H (S), and write CCR1L (R) signals.

Figure 219. Output stage of capture/compare channel (channel 1)

Figure 219. Output stage of capture/compare channel (channel 1) diagram. This diagram shows the output stage of capture/compare channel 1. It starts with an Output mode controller that receives inputs CNT > CCR2 and CNT = CCR2. The controller outputs OC1_REF, which is connected to the master mode controller. The OC1_REF signal is also connected to a multiplexer. The multiplexer has two inputs: 0 and 1. The input 0 is connected to the OC1_REF signal. The input 1 is connected to a NOT gate, which is connected to the OC1_REF signal. The output of the multiplexer is connected to an Output enable circuit. The Output enable circuit also receives inputs from CC1P (from TIMx_CCER) and CC1E (from TIMx_CCER). The Output enable circuit generates the OC1 signal. The Output mode controller also receives inputs from OC2M[2:0] (from TIMx_CCMR1).

The capture/compare block is made of one preload register and one shadow register. Write and read always access the preload register.

In capture mode, captures are actually done in the shadow register, which is copied into the preload register.

In compare mode, the content of the preload register is copied into the shadow register which is compared to the counter.

18.3.5 Input capture mode

In Input capture mode, the Capture/Compare Registers (TIMx_CCRx) are used to latch the value of the counter after a transition detected by the corresponding ICx signal. When a capture occurs, the corresponding CCxIF flag (TIMx_SR register) is set and an interrupt or a DMA request can be sent if they are enabled. If a capture occurs while the CCxIF flag was already high, then the over-capture flag CCxOF (TIMx_SR register) is set. CCxIF can be

cleared by software by writing it to '0' or by reading the captured data stored in the TIMx_CCRx register. CCxOF is cleared when it is written with 0.

The following example shows how to capture the counter value in TIMx_CCR1 when TI1 input rises. To do this, use the following procedure:

1. Select the active input: TIMx_CCR1 must be linked to the TI1 input, so write the CC1S bits to '01' in the TIMx_CCMR1 register. As soon as CC1S becomes different from '00', the channel is configured in input mode and the TIMx_CCR1 register becomes read-only.
2. Program the appropriate input filter duration in relation with the signal connected to the timer (by programming the ICxF bits in the TIMx_CCMRx register if the input is one of the TIx inputs). Let's imagine that, when toggling, the input signal is not stable during at most 5 internal clock cycles. We must program a filter duration longer than these 5 clock cycles. We can validate a transition on TI1 when 8 consecutive samples with the new level have been detected (sampled at $f_{DTS}$ frequency). Then write IC1F bits to '0011' in the TIMx_CCMR1 register.
3. Select the edge of the active transition on the TI1 channel by programming CC1P and CC1NP bits to '00' in the TIMx_CCER register (rising edge in this case).
4. Program the input prescaler. In our example, we wish the capture to be performed at each valid transition, so the prescaler is disabled (write IC1PS bits to '00' in the TIMx_CCMR1 register).
5. Enable capture from the counter into the capture register by setting the CC1E bit in the TIMx_CCER register.
6. If needed, enable the related interrupt request by setting the CC1IE bit in the TIMx_DIER register.

When an input capture occurs:

• The TIMx_CCR1 register gets the value of the counter on the active transition.
• CC1IF flag is set (interrupt flag). CC1OF is also set if at least two consecutive captures occurred whereas the flag was not cleared.
• An interrupt is generated depending on the CC1IE bit.

In order to handle the overcapture, it is recommended to read the data before the overcapture flag. This is to avoid missing an overcapture which could happen after reading the flag and before reading the data.

Note: IC interrupt requests can be generated by software by setting the corresponding CCxG bit in the TIMx_EGR register.

18.3.6 PWM input mode (only for TIM9/12)

This mode is a particular case of input capture mode. The procedure is the same except:

• Two ICx signals are mapped on the same TIx input.
• These 2 ICx signals are active on edges with opposite polarity.
• One of the two TIxFP signals is selected as trigger input and the slave mode controller is configured in reset mode.

For example, one can measure the period (in TIMx_CCR1 register) and the duty cycle (in TIMx_CCR2 register) of the PWM applied on TI1 using the following procedure (depending on CK_INT frequency and prescaler value):

1. Select the active input for TIMx_CCR1: write the CC1S bits to '01' in the TIMx_CCMR1 register (TI1 selected).
2. Select the active polarity for TI1FP1 (used both for capture in TIMx_CCR1 and counter clear): program the CC1P and CC1NP bits to '00' (active on rising edge).
3. Select the active input for TIMx_CCR2: write the CC2S bits to '10' in the TIMx_CCMR1 register (TI1 selected).
4. Select the active polarity for TI1FP2 (used for capture in TIMx_CCR2): write the CC2P bit to '1' and the CC2NP bit to '0' (active on falling edge).
5. Select the valid trigger input: write the TS bits to '101' in the TIMx_SMCR register (TI1FP1 selected).
6. Configure the slave mode controller in reset mode: write the SMS bits to '100' in the TIMx_SMCR register.
7. Enable the captures: write the CC1E and CC2E bits to '1' in the TIMx_CCER register.

Figure 220. PWM input mode timing

Timing diagram for PWM input mode. It shows four waveforms: TI1 (input), TIMx_CNT (counter), TIMx_CCR1 (capture register 1), and TIMx_CCR2 (capture register 2). The TI1 signal is a PWM signal. The TIMx_CNT signal is a counter that increments from 0000 to 0004, then resets to 0000. The TIMx_CCR1 signal is set to 0004. The TIMx_CCR2 signal is set to 0002. The diagram illustrates the capture events: IC1 capture, IC2 capture, and reset counter at the first rising edge; IC2 capture, pulse width measurement at the first falling edge; and IC1 capture, period measurement at the second rising edge.

1. The PWM input mode can be used only with the TIMx_CH1/TIMx_CH2 signals due to the fact that only TI1FP1 and TI2FP2 are connected to the slave mode controller.

18.3.7 Forced output mode

In output mode (CCxS bits = '00' in the TIMx_CCMRx register), each output compare signal (OCxREF and then OCx) can be forced to active or inactive level directly by software, independently of any comparison between the output compare register and the counter.

To force an output compare signal (OCXREF/OCx) to its active level, one just needs to write '101' in the OCxM bits in the corresponding TIMx_CCMRx register. Thus OCXREF is forced high (OCxREF is always active high) and OCx get opposite value to CCxP polarity bit.

For example: CCxP='0' (OCx active high) => OCx is forced to high level.

The OCxREF signal can be forced low by writing the OCxM bits to '100' in the TIMx_CCMRx register.

Anyway, the comparison between the TIMx_CCRx shadow register and the counter is still performed and allows the flag to be set. Interrupt requests can be sent accordingly. This is described in the output compare mode section below.

18.3.8 Output compare mode

This function is used to control an output waveform or indicating when a period of time has elapsed.

When a match is found between the capture/compare register and the counter, the output compare function:

1. Assigns the corresponding output pin to a programmable value defined by the output compare mode (OCxM bits in the TIMx_CCMRx register) and the output polarity (CCxP bit in the TIMx_CCER register). The output pin can keep its level (OCxM='000'), be set active (OCxM='001'), be set inactive (OCxM='010') or can toggle (OCxM='011') on match.
2. Sets a flag in the interrupt status register (CCxIF bit in the TIMx_SR register).
3. Generates an interrupt if the corresponding interrupt mask is set (CCxIE bit in the TIMx_DIER register).

The TIMx_CCRx registers can be programmed with or without preload registers using the OCxPE bit in the TIMx_CCMRx register.

In output compare mode, the update event UEV has no effect on OCxREF and OCx output. The timing resolution is one count of the counter. Output compare mode can also be used to output a single pulse (in One-pulse mode).

Procedure:

1. Select the counter clock (internal, external, prescaler).
2. Write the desired data in the TIMx_ARR and TIMx_CCRx registers.
3. Set the CCxIE bit if an interrupt request is to be generated.
4. Select the output mode. For example:
- – Write OCxM = '011' to toggle OCx output pin when CNT matches CCRx
- – Write OCxPE = '0' to disable preload register
- – Write CCxP = '0' to select active high polarity
- – Write CCxE = '1' to enable the output
5. Enable the counter by setting the CEN bit in the TIMx_CR1 register.

The TIMx_CCRx register can be updated at any time by software to control the output waveform, provided that the preload register is not enabled (OCxPE='0', else TIMx_CCRx shadow register is updated only at the next update event UEV). An example is given in Figure 221 .

Figure 221. Output compare mode, toggle on OC1.

Timing diagram for Output compare mode, toggle on OC1. The diagram shows three horizontal timelines: TIMx_CNT, TIMx_CCR1, and OC1REF= OC1. TIMx_CNT shows values 0039, 003A, 003B, B200, and B201. TIMx_CCR1 shows values 003A and B201. OC1REF= OC1 shows a high-to-low transition at 003A and a low-to-high transition at B201. Arrows indicate that these transitions correspond to matches detected on CCR1, which generate an interrupt if enabled. A note at the top indicates that 0xB201 is written in the CC1R register.

Write 0xB201 in the CC1R register

TIMx_CNT: 0039 | 003A | 003B | ... | B200 | B201

TIMx_CCR1: 003A | B201

OC1REF= OC1: High-to-low transition at 003A, Low-to-high transition at B201

Match detected on CCR1
Interrupt generated if enabled

MSv67583V1

Timing diagram for Output compare mode, toggle on OC1. The diagram shows three horizontal timelines: TIMx_CNT, TIMx_CCR1, and OC1REF= OC1. TIMx_CNT shows values 0039, 003A, 003B, B200, and B201. TIMx_CCR1 shows values 003A and B201. OC1REF= OC1 shows a high-to-low transition at 003A and a low-to-high transition at B201. Arrows indicate that these transitions correspond to matches detected on CCR1, which generate an interrupt if enabled. A note at the top indicates that 0xB201 is written in the CC1R register.

18.3.9 PWM mode

Pulse Width Modulation mode allows to generate a signal with a frequency determined by the value of the TIMx_ARR register and a duty cycle determined by the value of the TIMx_CCRx register.

The PWM mode can be selected independently on each channel (one PWM per OCx output) by writing '110' (PWM mode 1) or '111' (PWM mode 2) in the OCxM bits in the TIMx_CCMRx register. The corresponding preload register must be enabled by setting the OCxPE bit in the TIMx_CCMRx register, and eventually the auto-reload preload register (in upcounting or center-aligned modes) by setting the ARPE bit in the TIMx_CR1 register.

As the preload registers are transferred to the shadow registers only when an update event occurs, before starting the counter, all registers must be initialized by setting the UG bit in the TIMx_EGR register.

The OCx polarity is software programmable using the CCxP bit in the TIMx_CCER register. It can be programmed as active high or active low. The OCx output is enabled by the CCxE bit in the TIMx_CCER register. Refer to the TIMx_CCERx register description for more details.

In PWM mode (1 or 2), TIMx_CNT and TIMx_CCRx are always compared to determine whether $TIMx\_CNT \leq TIMx\_CCRx$ .

The timer is able to generate PWM in edge-aligned mode only since the counter is upcounting.

PWM edge-aligned mode

In the following example, we consider PWM mode 1. The reference PWM signal OCxREF is high as long as $TIMx\_CNT < TIMx\_CCRx$ else it becomes low. If the compare value in TIMx_CCRx is greater than the auto-reload value (in TIMx_ARR) then OCxREF is held at '1'. If the compare value is 0 then OCxRef is held at '0'. Figure 222 shows some edge-aligned PWM waveforms in an example where TIMx_ARR=8.

Figure 222. Edge-aligned PWM waveforms (ARR=8)

Timing diagram showing edge-aligned PWM waveforms for different CCRx values (4, 8, >8, 0) relative to a counter register sequence (0-8, 0-1).

The diagram illustrates the relationship between the Counter register, OCXREF, and CCxIF signals for different CCRx values. The Counter register sequence is 0, 1, 2, 3, 4, 5, 6, 7, 8, 0, 1. Vertical dashed lines mark the counter values 0, 4, 8, and 0 again.

CCRx=4: OCXREF is high from counter 0 to 4, then low. CCxIF is high at counter 4.
CCRx=8: OCXREF is high from counter 0 to 8, then low. CCxIF is high at counter 8.
CCRx>8: OCXREF is always high ('1'). CCxIF is high at counter 0.
CCRx=0: OCXREF is always low ('0'). CCxIF is high at counter 0.

MS31093V1

Timing diagram showing edge-aligned PWM waveforms for different CCRx values (4, 8, >8, 0) relative to a counter register sequence (0-8, 0-1).

18.3.10 One-pulse mode

One-pulse mode (OPM) is a particular case of the previous modes. It allows the counter to be started in response to a stimulus and to generate a pulse with a programmable length after a programmable delay.

Starting the counter can be controlled through the slave mode controller. Generating the waveform can be done in output compare mode or PWM mode. One-pulse mode is selected by setting the OPM bit in the TIMx_CR1 register. This makes the counter stop automatically at the next update event UEV.

A pulse can be correctly generated only if the compare value is different from the counter initial value. Before starting (when the timer is waiting for the trigger), the configuration must be as follows:

\text{CNT} < \text{CCRx} \leq \text{ARR} \text{ (in particular, } 0 < \text{CCRx)}

Figure 223. Example of One-pulse mode

Timing diagram for One-pulse mode. The diagram shows four waveforms over time (t). 1. TI2: A rising edge triggers the sequence. 2. OC1REF: A high-level pulse starts after a delay t_DELAY and ends at t_DELAY + t_PULSE. 3. OC1: A high-level pulse starts at the same time as OC1REF and ends at the same time. 4. Counter: A staircase graph showing the counter value increasing from 0. It starts at the TI2 rising edge, increases in steps until it reaches TIMx_CCR1 at time t_DELAY, then continues to increase until it reaches TIMx_ARR at time t_DELAY + t_PULSE, where it resets to 0. The time interval from the start to TIMx_CCR1 is labeled t_DELAY, and the interval from TIMx_CCR1 to TIMx_ARR is labeled t_PULSE. The y-axis is labeled 'Counter' and has markers for 0, TIMx_CCR1, and TIMx_ARR. The x-axis is labeled 't'. A small code 'MSV67584V1' is in the bottom right corner of the diagram area.

For example one may want to generate a positive pulse on OC1 with a length of $t_{PULSE}$ and after a delay of $t_{DELAY}$ as soon as a positive edge is detected on the TI2 input pin.

Use TI2FP2 as trigger 1:

1. Map TI2FP2 to TI2 by writing CC2S='01' in the TIMx_CCMR1 register.
2. TI2FP2 must detect a rising edge, write CC2P='0' and CC2NP = '0' in the TIMx_CCER register.
3. Configure TI2FP2 as trigger for the slave mode controller (TRGI) by writing TS='110' in the TIMx_SMCR register.
4. TI2FP2 is used to start the counter by writing SMS to '110' in the TIMx_SMCR register (trigger mode).

The OPM waveform is defined by writing the compare registers (taking into account the clock frequency and the counter prescaler).

• The $t_{DELAY}$ is defined by the value written in the TIMx_CCR1 register.
• The $t_{PULSE}$ is defined by the difference between the auto-reload value and the compare value ( $TIMx\_ARR - TIMx\_CCR1$ ).
• Let's say one want to build a waveform with a transition from '0' to '1' when a compare match occurs and a transition from '1' to '0' when the counter reaches the auto-reload value. To do this PWM mode 2 must be enabled by writing OC1M='111' in the TIMx_CCMR1 register. Optionally the preload registers can be enabled by writing OC1PE='1' in the TIMx_CCMR1 register and ARPE in the TIMx_CR1 register. In this case one has to write the compare value in the TIMx_CCR1 register, the auto-reload value in the TIMx_ARR register, generate an update by setting the UG bit and wait for external trigger event on TI2. CC1P is written to '0' in this example.

Since only 1 pulse (Single mode) is needed, a 1 must be written in the OPM bit in the TIMx_CR1 register to stop the counter at the next update event (when the counter rolls over from the auto-reload value back to 0). When OPM bit in the TIMx_CR1 register is set to '0', so the Repetitive Mode is selected.

Particular case: OCx fast enable

In One-pulse mode, the edge detection on TIx input set the CEN bit which enables the counter. Then the comparison between the counter and the compare value makes the output toggle. But several clock cycles are needed for these operations and it limits the minimum delay $t_{\text{DELAY min}}$ we can get.

If one wants to output a waveform with the minimum delay, the OCxFE bit can be set in the TIMx_CCMRx register. Then OCxRef (and OCx) are forced in response to the stimulus, without taking in account the comparison. Its new level is the same as if a compare match had occurred. OCxFE acts only if the channel is configured in PWM1 or PWM2 mode.

18.3.11 TIM9/12 external trigger synchronization

The TIM9/12 timers can be synchronized with an external trigger in several modes: Reset mode, Gated mode and Trigger mode.

Slave mode: Reset mode

The counter and its prescaler can be reinitialized in response to an event on a trigger input. Moreover, if the URS bit from the TIMx_CR1 register is low, an update event UEV is generated. Then all the preloaded registers (TIMx_ARR, TIMx_CCRx) are updated.

In the following example, the upcounter is cleared in response to a rising edge on TI1 input:

1. Configure the channel 1 to detect rising edges on TI1. Configure the input filter duration (in this example, we do not need any filter, so we keep IC1F='0000'). The capture prescaler is not used for triggering, so it does not need to be configured. The CC1S bits select the input capture source only, CC1S = '01' in the TIMx_CCMR1 register. Program CC1P and CC1NP to '00' in TIMx_CCER register to validate the polarity (and detect rising edges only).
2. Configure the timer in reset mode by writing SMS='100' in TIMx_SMCR register. Select TI1 as the input source by writing TS='101' in TIMx_SMCR register.
3. Start the counter by writing CEN='1' in the TIMx_CR1 register.

The counter starts counting on the internal clock, then behaves normally until TI1 rising edge. When TI1 rises, the counter is cleared and restarts from 0. In the meantime, the trigger flag is set (TIF bit in the TIMx_SR register) and an interrupt request can be sent if enabled (depending on the TIE bit in TIMx_DIER register).

The following figure shows this behavior when the auto-reload register TIMx_ARR=0x36. The delay between the rising edge on TI1 and the actual reset of the counter is due to the resynchronization circuit on TI1 input.

Figure 224. Control circuit in reset mode

Timing diagram showing the control circuit in reset mode. The signals are:

TI1 : Input signal, initially high, then goes low, then high again.
UG : Update Generation signal, goes high when TI1 is high.
Counter clock = ck_cnt = ck_psc : Periodic square wave clock.
Counter register : Shows the count values: 30, 31, 32, 33, 34, 35, 36, 00, 01, 02, 03, 00, 01, 02, 03. The counter counts up from 30 to 36, then resets to 00 and continues counting.
TIF : Timer Interrupt Flag, goes high when the counter resets to 00 and goes low when the counter starts counting again (when TI1 goes low).

MS31401V2

Timing diagram for Figure 224. Control circuit in reset mode. The diagram shows five signals over time: TI1 (top), UG, Counter clock = ck_cnt = ck_psc, Counter register, and TIF (bottom). TI1 starts high, goes low, then high again. UG is a pulse that goes high when TI1 is high. The counter clock is a periodic square wave. The Counter register shows values 30, 31, 32, 33, 34, 35, 36, 00, 01, 02, 03, 00, 01, 02, 03. The counter starts at 30 and counts up to 36, then resets to 00. The TIF flag is set when the counter resets to 00 and is reset when the counter starts counting again (when TI1 goes low).

Slave mode: Gated mode

The counter can be enabled depending on the level of a selected input.

In the following example, the upcounter counts only when TI1 input is low:

1. Configure the channel 1 to detect low levels on TI1. Configure the input filter duration (in this example, we do not need any filter, so we keep IC1F='0000'). The capture prescaler is not used for triggering, so it does not need to be configured. The CC1S bits select the input capture source only, CC1S='01' in TIMx_CCMR1 register. Program CC1P='1' and CC1NP= '0' in TIMx_CCER register to validate the polarity (and detect low level only).
2. Configure the timer in gated mode by writing SMS='101' in TIMx_SMCR register. Select TI1 as the input source by writing TS='101' in TIMx_SMCR register.
3. Enable the counter by writing CEN='1' in the TIMx_CR1 register (in gated mode, the counter doesn't start if CEN='0', whatever is the trigger input level).

The counter starts counting on the internal clock as long as TI1 is low and stops as soon as TI1 becomes high. The TIF flag in the TIMx_SR register is set both when the counter starts or stops.

The delay between the rising edge on TI1 and the actual stop of the counter is due to the resynchronization circuit on TI1 input.

Figure 225. Control circuit in gated mode

Timing diagram for Figure 225: Control circuit in gated mode. The diagram shows five signals over time: TI1 (input), cnt_en (enable), Counter clock = ck_cnt = ck_psc (clock), Counter register (count), and TIF (interrupt flag). TI1 is high from the start until the first vertical dashed line. cnt_en is high from the start until the second vertical dashed line. The counter clock is a periodic square wave. The counter register starts at 30 and increments to 38. The TIF flag is set when the counter reaches 34 and is reset when it reaches 38. Arrows from 'Write TIF=0' point to the TIF signal at the values 34 and 38.

Slave mode: Trigger mode

The counter can start in response to an event on a selected input.

In the following example, the upcounter starts in response to a rising edge on TI2 input:

1. Configure the channel 2 to detect rising edges on TI2. Configure the input filter duration (in this example, we do not need any filter, so we keep IC2F='0000'). The capture prescaler is not used for triggering, so it does not need to be configured. The CC2S bits are configured to select the input capture source only, CC2S='01' in TIMx_CCMR1 register. Program CC2P='1' and CC2NP='0' in TIMx_CCER register to validate the polarity (and detect low level only).
2. Configure the timer in trigger mode by writing SMS='110' in TIMx_SMCR register. Select TI2 as the input source by writing TS='110' in TIMx_SMCR register.

When a rising edge occurs on TI2, the counter starts counting on the internal clock and the TIF flag is set.

The delay between the rising edge on TI2 and the actual start of the counter is due to the resynchronization circuit on TI2 input.

Figure 226. Control circuit in trigger mode

Timing diagram for Figure 226: Control circuit in trigger mode. The diagram shows five signals over time: TI2 (input), cnt_en (enable), Counter clock = ck_cnt = ck_psc (clock), Counter register (count), and TIF (interrupt flag). TI2 is low until a rising edge occurs, which triggers the counter. cnt_en is high from the start. The counter clock is a periodic square wave. The counter register starts at 34 and increments to 38. The TIF flag is set when the counter reaches 35 and is reset when it reaches 38.

18.3.12 Timer synchronization (TIM9/12)

The TIM timers are linked together internally for timer synchronization or chaining. Refer to Section 17.3.15: Timer synchronization for details.

18.3.13 Debug mode

When the microcontroller enters debug mode (Cortex®-M4 with FPU core halted), the TIMx counter either continues to work normally or stops, depending on DBG_TIMx_STOP configuration bit in DBG module. For more details, refer to .

18.4 TIM9 and TIM12 registers

Refer to Section 1.2 on page 51 for a list of abbreviations used in register descriptions.

The peripheral registers have to be written by half-words (16 bits) or words (32 bits). Read accesses can be done by bytes (8 bits), half-words (16 bits) or words (32 bits).

18.4.1 TIM9/12 control register 1 (TIMx_CR1)

Address offset: 0x00

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	Res.	CKD[1:0]		ARPE	Res.	Res.	Res.	OPM	URS	UDIS	CEN
						rw	rw	rw				rw	rw	rw	rw

Bits 15:10 Reserved, must be kept at reset value.

Bits 9:8 CKD : Clock division

This bit-field indicates the division ratio between the timer clock (CK_INT) frequency and sampling clock used by the digital filters (TIx),

00: $t_{DTS} = t_{CK\_INT}$

01: $t_{DTS} = 2 \times t_{CK\_INT}$

10: $t_{DTS} = 4 \times t_{CK\_INT}$

11: Reserved

Bit 7 ARPE : Auto-reload preload enable

0: TIMx_ARR register is not buffered.

1: TIMx_ARR register is buffered.

Bits 6:4 Reserved, must be kept at reset value.

Bit 3 OPM : One-pulse mode

0: Counter is not stopped on the update event

1: Counter stops counting on the next update event (clearing the CEN bit).

Bit 2 URS: Update request source

This bit is set and cleared by software to select the UEV event sources.

0: Any of the following events generates an update interrupt if enabled:

– Counter overflow
– Setting the UG bit

1: Only counter overflow generates an update interrupt if enabled.

Bit 1 UDIS: Update disable

This bit is set and cleared by software to enable/disable update event (UEV) generation.

0: UEV enabled. An UEV is generated by one of the following events:

– Counter overflow
– Setting the UG bit

Buffered registers are then loaded with their preload values.

1: UEV disabled. No UEV is generated, shadow registers keep their value (ARR, PSC, CCRx). The counter and the prescaler are reinitialized if the UG bit is set.

Bit 0 CEN: Counter enable

0: Counter disabled

1: Counter enabled

CEN is cleared automatically in one-pulse mode, when an update event occurs.

18.4.2 TIM9/12 slave mode control register (TIMx_SMCR)

Address offset: 0x08

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	MSM	TS[2:0]			Res.	SMS[2:0]
								rw	rw	rw	rw		rw	rw	rw

Bits 15:8 Reserved, must be kept at reset value.

Bit 7 MSM : Master/Slave mode

0: No action

1: The effect of an event on the trigger input (TRGI) is delayed to allow a perfect synchronization between the current timer and its slaves (through TRGO). It is useful in order to synchronize several timers on a single external event.

Bits 6:4 TS : Trigger selection

This bitfield selects the trigger input to be used to synchronize the counter.

000: Internal Trigger 0 (ITR0)

001: Internal Trigger 1 (ITR1)

010: Internal Trigger 2 (ITR2)

011: Internal Trigger 3 (ITR3)

100: TI1 Edge Detector (TI1F_ED)

101: Filtered Timer Input 1 (TI1FP1)

110: Filtered Timer Input 2 (TI2FP2)

111: Reserved.

See Table 115 for more details on the meaning of ITRx for each timer.

Note: These bits must be changed only when they are not used (e.g. when SMS='000') to avoid wrong edge detections at the transition.

Bit 3 Reserved, must be kept at reset value.

Bits 2:0 SMS : Slave mode selection

When external signals are selected, the active edge of the trigger signal (TRGI) is linked to the polarity selected on the external input (see Input control register and Control register descriptions).

000: Slave mode disabled - if CEN = 1 then the prescaler is clocked directly by the internal clock

001: Reserved

010: Reserved

011: Reserved

100: Reset mode - Rising edge of the selected trigger input (TRGI) reinitializes the counter and generates an update of the registers

101: Gated mode - The counter clock is enabled when the trigger input (TRGI) is high. The counter stops (but is not reset) as soon as the trigger becomes low. Counter starts and stops are both controlled

110: Trigger mode - The counter starts on a rising edge of the trigger TRGI (but it is not reset). Only the start of the counter is controlled

111: External clock mode 1 - Rising edges of the selected trigger (TRGI) clock the counter

Note: The Gated mode must not be used if TI1F_ED is selected as the trigger input (TS='100'). Indeed, TI1F_ED outputs 1 pulse for each transition on TI1F, whereas the Gated mode checks the level of the trigger signal.

Table 115. TIMx internal trigger connections

Slave TIM	ITR0 (TS = '000')	ITR1 (TS = '001')	ITR2 (TS = '010')	ITR3 (TS = '011')
TIM9	TIM2	TIM3	TIM10_OC	TIM11_OC
TIM12	TIM4	TIM5	TIM13_OC	TIM14_OC

18.4.3 TIM9/12 Interrupt enable register (TIMx_DIER)

Address offset: 0x0C

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	TIE	Res.	Res.	Res.	CC2IE	CC1IE	UIE
									rw				rw	rw	rw

Bits 15:7 Reserved, must be kept at reset value.

Bit 6 TIE : Trigger interrupt enable

0: Trigger interrupt disabled.

1: Trigger interrupt enabled.

Bits 5:3 Reserved, must be kept at reset value.

Bit 2 CC2IE : Capture/Compare 2 interrupt enable

0: CC2 interrupt disabled.

1: CC2 interrupt enabled.

Bit 1 CC1IE : Capture/Compare 1 interrupt enable

0: CC1 interrupt disabled.

1: CC1 interrupt enabled.

Bit 0 UIE : Update interrupt enable

0: Update interrupt disabled.

1: Update interrupt enabled.

18.4.4 TIM9/12 status register (TIMx_SR)

Address offset: 0x10

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	CC2OF	CC1OF	Res.	Res.	TIF	Res.	Res.	Res.	CC2IF	CC1IF	UIF
					rc_w0	rc_w0			rc_w0				rc_w0	rc_w0	rc_w0

Bits 15:11 Reserved, must be kept at reset value.

Bit 10 CC2OF : Capture/compare 2 overcapture flag
refer to CC1OF description

Bit 9 CC1OF : Capture/Compare 1 overcapture flag

This flag is set by hardware only when the corresponding channel is configured in input capture mode. It is cleared by software by writing it to '0'.

0: No overcapture has been detected.

1: The counter value has been captured in TIMx_CCR1 register while CC1IF flag was already set

Bits 8:7 Reserved, must be kept at reset value.

Bit 6 TIF : Trigger interrupt flag

This flag is set by hardware on trigger event (active edge detected on TRGI input when the slave mode controller is enabled in all modes but gated mode. It is set when the counter starts or stops when gated mode is selected. It is cleared by software.

0: No trigger event occurred.

1: Trigger interrupt pending.

Bits 5:3 Reserved, must be kept at reset value.

Bit 2 CC2IF : Capture/Compare 2 interrupt flag
refer to CC1IF description

Bit 1 CC1IF : Capture/compare 1 interrupt flag

If channel CC1 is configured as output:

This flag is set by hardware when the counter matches the compare value. It is cleared by software.

0: No match.

1: The content of the counter TIMx_CNT matches the content of the TIMx_CCR1 register. When the contents of TIMx_CCR1 are greater than the contents of TIMx_ARR, the CC1IF bit goes high on the counter overflow.

If channel CC1 is configured as input:

This bit is set by hardware on a capture. It is cleared by software or by reading the TIMx_CCR1 register.

0: No input capture occurred.

1: The counter value has been captured in TIMx_CCR1 register (an edge has been detected on IC1 which matches the selected polarity).

Bit 0 UIF : Update interrupt flag

This bit is set by hardware on an update event. It is cleared by software.

0: No update occurred.

1: Update interrupt pending. This bit is set by hardware when the registers are updated:

– At overflow and if UDIS='0' in the TIMx_CR1 register.
– When CNT is reinitialized by software using the UG bit in TIMx_EGR register, if URS='0' and UDIS='0' in the TIMx_CR1 register.
– When CNT is reinitialized by a trigger event (refer to the synchro control register description), if URS='0' and UDIS='0' in the TIMx_CR1 register.

18.4.5 TIM9/12 event generation register (TIMx_EGR)

Address offset: 0x14

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	TG	Res.	Res.	Res.	CC2G	CC1G	UG
									w				w	w	w

Bits 15:7 Reserved, must be kept at reset value.

Bit 6 TG : Trigger generation

This bit is set by software in order to generate an event, it is automatically cleared by hardware.
0: No action
1: The TIF flag is set in the TIMx_SR register. Related interrupt can occur if enabled

Bits 5:3 Reserved, must be kept at reset value.

Bit 2 CC2G : Capture/compare 2 generation

refer to CC1G description

Bit 1 CC1G : Capture/compare 1 generation

This bit is set by software to generate an event, it is automatically cleared by hardware.
0: No action
1: A capture/compare event is generated on channel 1:

If channel CC1 is configured as output:
the CC1IF flag is set, the corresponding interrupt is sent if enabled.

If channel CC1 is configured as input:
The current counter value is captured in the TIMx_CCR1 register. The CC1IF flag is set, the corresponding interrupt is sent if enabled. The CC1OF flag is set if the CC1IF flag was already high.

Bit 0 UG : Update generation

This bit can be set by software, it is automatically cleared by hardware.
0: No action
1: Re-initializes the counter and generates an update of the registers. The prescaler counter is also cleared and the prescaler ratio is not affected. The counter is cleared.

18.4.6 TIM9/12 capture/compare mode register 1 (TIMx_CCMR1)

Address offset: 0x18

Reset value: 0x0000

The channels can be used in input (capture mode) or in output (compare mode). The direction of a channel is defined by configuring the corresponding CCxS bits. All the other bits in this register have different functions in input and output modes. For a given bit, OCxx describes its function when the channel is configured in output mode, ICxx describes its function when the channel is configured in input mode. So one must take care that the same bit can have different meanings for the input stage and the output stage.

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	OC2M[2:0]			OC2PE	OC2FE	CC2S[1:0]		Res.	OC1M[2:0]			OC1PE	OC1FE	CC1S[1:0]
IC2F[3:0]				IC2PSC[1:0]		CC2S[1:0]		IC1F[3:0]				IC1PSC[1:0]		CC1S[1:0]
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Output compare mode

Bit 15 Reserved, must be kept at reset value.

Bits 14:12 OC2M[2:0] : Output compare 2 mode

Bit 11 OC2PE : Output compare 2 preload enable

Bit 10 OC2FE : Output compare 2 fast enable

Bits 9:8 CC2S[1:0] : Capture/Compare 2 selection

This bitfield defines the direction of the channel (input/output) as well as the used input.

00: CC2 channel is configured as output

01: CC2 channel is configured as input, IC2 is mapped on TI2

10: CC2 channel is configured as input, IC2 is mapped on TI1

11: CC2 channel is configured as input, IC2 is mapped on TRC. This mode works only if an internal trigger input is selected through the TS bit (TIMx_SMCR register)

Note: The CC2S bits are writable only when the channel is OFF (CC2E = 0 in TIMx_CCER).

Bit 7 Reserved, must be kept at reset value.

Bits 6:4 OC1M : Output compare 1 mode

These bits define the behavior of the output reference signal OC1REF from which OC1 and OC1N are derived. OC1REF is active high whereas the active levels of OC1 and OC1N depend on the CC1P and CC1NP bits, respectively.

000: Frozen - The comparison between the output compare register TIMx_CCR1 and the counter TIMx_CNT has no effect on the outputs. (this mode is used to generate a timing base).

001: Set channel 1 to active level on match. The OC1REF signal is forced high when the TIMx_CNT counter matches the capture/compare register 1 (TIMx_CCR1).

010: Set channel 1 to inactive level on match. The OC1REF signal is forced low when the TIMx_CNT counter matches the capture/compare register 1 (TIMx_CCR1).

011: Toggle - OC1REF toggles when TIMx_CNT=TIMx_CCR1

100: Force inactive level - OC1REF is forced low

101: Force active level - OC1REF is forced high

110: PWM mode 1 - In upcounting, channel 1 is active as long as TIMx_CNT < TIMx_CCR1 else it is inactive. In downcounting, channel 1 is inactive (OC1REF='0') as long as TIMx_CNT > TIMx_CCR1, else it is active (OC1REF='1')

111: PWM mode 2 - In upcounting, channel 1 is inactive as long as TIMx_CNT < TIMx_CCR1 else it is active. In downcounting, channel 1 is active as long as TIMx_CNT > TIMx_CCR1 else it is inactive.

Note: In PWM mode 1 or 2, the OCREF level changes only when the result of the comparison changes or when the output compare mode switches from "frozen" mode to "PWM" mode.

Bit 3 OC1PE : Output compare 1 preload enable

0: Preload register on TIMx_CCR1 disabled. TIMx_CCR1 can be written at anytime, the new value is taken into account immediately

1: Preload register on TIMx_CCR1 enabled. Read/Write operations access the preload register. TIMx_CCR1 preload value is loaded into the active register at each update event

Bit 2 OC1FE : Output compare 1 fast enable

This bit is used to accelerate the effect of an event on the trigger input on the CC output.

0: CC1 behaves normally depending on the counter and CCR1 values even when the trigger is ON. The minimum delay to activate the CC1 output when an edge occurs on the trigger input is 5 clock cycles

1: An active edge on the trigger input acts like a compare match on the CC1 output. Then, OC is set to the compare level independently of the result of the comparison. Delay to sample the trigger input and to activate CC1 output is reduced to 3 clock cycles. OC1FE acts only if the channel is configured in PWM1 or PWM2 mode.

Bits 1:0 CC1S : Capture/Compare 1 selection

This bitfield defines the direction of the channel (input/output) as well as the used input.

00: CC1 channel is configured as output

01: CC1 channel is configured as input, IC1 is mapped on TI1

10: CC1 channel is configured as input, IC1 is mapped on TI2

11: CC1 channel is configured as input, IC1 is mapped on TRC. This mode works only if an internal trigger input is selected through the TS bit (TIMx_SMCR register)

Note: The CC1S bits are writable only when the channel is OFF (CC1E = 0 in TIMx_CCER).

Input capture mode

Bits 15:12 IC2F : Input capture 2 filter

Bits 11:10 IC2PSC[1:0] : Input capture 2 prescaler

Bits 9:8 CC2S : Capture/compare 2 selection

This bitfield defines the direction of the channel (input/output) as well as the used input.

00: CC2 channel is configured as output

01: CC2 channel is configured as input, IC2 is mapped on TI2

10: CC2 channel is configured as input, IC2 is mapped on TI1

11: CC2 channel is configured as input, IC2 is mapped on TRC. This mode works only if an internal trigger input is selected through the TS bit (TIMx_SMCR register)

Note: The CC2S bits are writable only when the channel is OFF (CC2E = 0 in TIMx_CCER).

Bits 7:4 IC1F : Input capture 1 filter

This bitfield defines the frequency used to sample the TI1 input and the length of the digital filter applied to TI1. The digital filter is made of an event counter in which N consecutive events are needed to validate a transition on the output:

0000: No filter, sampling is done at $f_{DTS}$ 1000: $f_{SAMPLING}=f_{DTS}/8$ , N=6

0001: $f_{SAMPLING}=f_{CK\_INT}$ , N=2 1001: $f_{SAMPLING}=f_{DTS}/8$ , N=8

0010: $f_{SAMPLING}=f_{CK\_INT}$ , N=4 1010: $f_{SAMPLING}=f_{DTS}/16$ , N=5

0011: $f_{SAMPLING}=f_{CK\_INT}$ , N=8 1011: $f_{SAMPLING}=f_{DTS}/16$ , N=6

0100: $f_{SAMPLING}=f_{DTS}/2$ , N=6 1100: $f_{SAMPLING}=f_{DTS}/16$ , N=8

0101: $f_{SAMPLING}=f_{DTS}/2$ , N=8 1101: $f_{SAMPLING}=f_{DTS}/32$ , N=5

0110: $f_{SAMPLING}=f_{DTS}/4$ , N=6 1110: $f_{SAMPLING}=f_{DTS}/32$ , N=6

0111: $f_{SAMPLING}=f_{DTS}/4$ , N=8 1111: $f_{SAMPLING}=f_{DTS}/32$ , N=8

Bits 3:2 IC1PSC : Input capture 1 prescaler

This bitfield defines the ratio of the prescaler acting on the CC1 input (IC1).

The prescaler is reset as soon as CC1E='0' (TIMx_CCER register).

00: no prescaler, capture is done each time an edge is detected on the capture input

01: capture is done once every 2 events

10: capture is done once every 4 events

11: capture is done once every 8 events

Bits 1:0 CC1S : Capture/Compare 1 selection

This bitfield defines the direction of the channel (input/output) as well as the used input.

00: CC1 channel is configured as output

01: CC1 channel is configured as input, IC1 is mapped on TI1

10: CC1 channel is configured as input, IC1 is mapped on TI2

11: CC1 channel is configured as input, IC1 is mapped on TRC. This mode is working only if an internal trigger input is selected through TS bit (TIMx_SMCR register)

Note: The CC1S bits are writable only when the channel is OFF (CC1E = 0 in TIMx_CCER).

18.4.7 TIM9/12 capture/compare enable register (TIMx_CCER)

Address offset: 0x20

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	CC2NP	Res.	CC2P	CC2E	CC1NP	Res.	CC1P	CC1E
								rw		rw	rw	rw		rw	rw

Bits 15:8 Reserved, must be kept at reset value.

Bit 7 CC2NP : Capture/Compare 2 output Polarity
refer to CC1NP description

Bit 6 Reserved, must be kept at reset value.

Bit 5 CC2P : Capture/Compare 2 output Polarity
refer to CC1P description

Bit 4 CC2E : Capture/Compare 2 output enable
refer to CC1E description

Bit 3 CC1NP : Capture/Compare 1 complementary output Polarity
CC1 channel configured as output: CC1NP must be kept cleared
CC1 channel configured as input: CC1NP is used in conjunction with CC1P to define TI1FP1/TI2FP1 polarity (refer to CC1P description).

Bit 2 Reserved, must be kept at reset value.

Bit 1 CC1P : Capture/Compare 1 output Polarity.

CC1 channel configured as output:

0: OC1 active high.

1: OC1 active low.

CC1 channel configured as input:

CC1NP/CC1P bits select TI1FP1 and TI2FP1 polarity for trigger or capture operations.

00: noninverted/rising edge

Circuit is sensitive to TIxFP1 rising edge (capture, trigger in reset, external clock or trigger mode), TIxFP1 is not inverted (trigger in gated mode, encoder mode).

01: inverted/falling edge

Circuit is sensitive to TIxFP1 falling edge (capture, trigger in reset, external clock or trigger mode), TIxFP1 is inverted (trigger in gated mode, encoder mode).

10: reserved, do not use this configuration.

Note: 11: noninverted/both edges

Circuit is sensitive to both TIxFP1 rising and falling edges (capture, trigger in reset, external clock or trigger mode), TIxFP1 is not inverted (trigger in gated mode). This configuration must not be used for encoder mode.

Bit 0 CC1E : Capture/Compare 1 output enable.

CC1 channel configured as output:

0: Off - OC1 is not active.

1: On - OC1 signal is output on the corresponding output pin.

CC1 channel configured as input:

This bit determines if a capture of the counter value can actually be done into the input capture/compare register 1 (TIMx_CCR1) or not.

0: Capture disabled.

1: Capture enabled.

Table 116. Output control bit for standard OCx channels

CCxE bit	OCx output state
0	Output disabled (OCx='0', OCx_EN='0')
1	OCx=OCxREF + Polarity, OCx_EN='1'

Note: The states of the external I/O pins connected to the standard OCx channels depend on the state of the OCx channel and on the GPIO registers.

18.4.8 TIM9/12 counter (TIMx_CNT)

Address offset: 0x24

Reset value: 0x0000 0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
CNT[15:0]
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bits 15:0 CNT[15:0] : Counter value

18.4.9 TIM9/12 prescaler (TIMx_PSC)

Address offset: 0x28

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
PSC[15:0]
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bits 15:0 PSC[15:0] : Prescaler value

The counter clock frequency CK_CNT is equal to $f_{CK\_PSC} / (PSC[15:0] + 1)$ .

PSC contains the value to be loaded into the active prescaler register at each update event.

18.4.10 TIM9/12 auto-reload register (TIMx_ARR)

Address offset: 0x2C

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
ARR[15:0]
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bits 15:0 ARR[15:0] : Auto-reload value

ARR is the value to be loaded into the actual auto-reload register.

Refer to Section 18.3.1: Time-base unit for more details about ARR update and behavior.

The counter is blocked while the auto-reload value is null.

18.4.11 TIM9/12 capture/compare register 1 (TIMx_CCR1)

Address offset: 0x34

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
CCR1[15:0]
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bits 15:0 CCR1[15:0] : Capture/Compare 1 value

If channel CC1 is configured as output:

CCR1 is the value to be loaded into the actual capture/compare 1 register (preload value). It is loaded permanently if the preload feature is not selected in the TIMx_CCMR1 register (OC1PE bit). Else the preload value is copied into the active capture/compare 1 register when an update event occurs.

The active capture/compare register contains the value to be compared to the TIMx_CNT counter and signaled on the OC1 output.

If channel CC1 is configured as input:

CCR1 is the counter value transferred by the last input capture 1 event (IC1).

18.4.12 TIM9/12 capture/compare register 2 (TIMx_CCR2)

Address offset: 0x38

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
CCR2[15:0]
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bits 15:0 CCR2[15:0] : Capture/Compare 2 value

If channel CC2 is configured as output:

CCR2 is the value to be loaded into the actual capture/compare 2 register (preload value). It is loaded permanently if the preload feature is not selected in the TIMx_CCMR2 register (OC2PE bit). Else the preload value is copied into the active capture/compare 2 register when an update event occurs.

The active capture/compare register contains the value to be compared to the TIMx_CNT counter and signalled on the OC2 output.

If channel CC2 is configured as input:

CCR2 is the counter value transferred by the last input capture 2 event (IC2).

18.4.13 TIM9/12 register map

TIM9/12 registers are mapped as 16-bit addressable registers as described below:

Table 117. TIM9/12 register map and reset values

Offset	Register	31	30	29	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Offset	Register	0x00	TIMx_CR1	Res.			Res.						CKD [1:0]		ARPE	Res.			OPM	URS	UDIS	CEN
Reset value										0	0	0				0	0	0	0
0x08	TIMx_SMCR	0x00	Res.			Res.							MSM	TS[2:0]			Res.	SMS[2:0]
0x08	Reset value											0					0	0	0
0x0C	TIMx_DIER	Res.			Res.									TIE	Res.			CC2IE	CC1IE	UIE
0x0C	Reset value													0				0	0	0
0x10	TIMx_SR	Res.			Res.					CC2OF	CC1OF	Res.	TIF	Res.			CC2IF	CC1IF	UIF
0x10	Reset value									0	0		0				0	0	0
0x14	TIMx_EGR	Res.			Res.							TG	Res.			CC2G	CC1G	UG
0x14	Reset value											0				0	0	0
0x18	TIMx_CCMR1 Output Compare mode	Res.			Res.	OC2M [2:0]			OC2PE	OC2FE	CC2S [1:0]		Res.	OC1M [2:0]			OC1PE	OC1FE	CC1S [1:0]
	Reset value				0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
	TIMx_CCMR1 Input Capture mode	Res.			IC2F[3:0]				IC2 PSC [1:0]		CC2S [1:0]		IC1F[3:0]				IC1 PSC [1:0]		CC1S [1:0]
	Reset value				0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x1C	Reserved	Res.			Res.
0x20	TIMx_CCER	Res.			Res.								CC2NP	Res.	CC2P	CC2E	CC1NP	Res.	CC1P	CC1E
0x20	Reset value												0		0	0	0		0	0
0x24	TIMx_CNT	Res.			CNT[15:0]
0x24	Reset value				0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x28	TIMx_PSC	Res.			PSC[15:0]
0x28	Reset value				0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x2C	TIMx_ARR	Res.			ARR[15:0]
0x2C	Reset value				0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x30	Reserved	Res.			Res.

Table 117. TIM9/12 register map and reset values (continued)

Offset	Register	31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
0x34	TIMx_CCR1	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	CCR1[15:0]
0x34	Reset value																	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x38	TIMx_CCR2	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	CCR2[15:0]
0x38	Reset value																	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x3C to 0x4C	Reserved	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res

Refer to Section 2.2 on page 56 for the register boundary addresses.

18.5 TIM10/11/13/14 registers

The peripheral registers have to be written by half-words (16 bits) or words (32 bits). Read accesses can be done by bytes (8 bits), half-words (16 bits) or words (32 bits).

18.5.1 TIM10/11/13/14 control register 1 (TIMx_CR1)

Address offset: 0x00

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	Res.	CKD[1:0]		ARPE	Res.	Res.	Res.	Res.	URS	UDIS	CEN
						rw		rw					rw	rw	rw

Bits 15:10 Reserved, must be kept at reset value.

Bits 9:8 CKD : Clock division

This bit-field indicates the division ratio between the timer clock (CK_INT) frequency and sampling clock used by the digital filters (TIx),

00: $t_{DTS} = t_{CK\_INT}$

01: $t_{DTS} = 2 \times t_{CK\_INT}$

10: $t_{DTS} = 4 \times t_{CK\_INT}$

11: Reserved

Bit 7 ARPE : Auto-reload preload enable

0: TIMx_ARR register is not buffered

1: TIMx_ARR register is buffered

Bits 6:3 Reserved, must be kept at reset value.

Bit 2 URS : Update request source

This bit is set and cleared by software to select the update interrupt (UEV) sources.

0: Any of the following events generate an UEV if enabled:

– Counter overflow
– Setting the UG bit

1: Only counter overflow generates an UEV if enabled.

Bit 1 UDIS : Update disable

This bit is set and cleared by software to enable/disable update interrupt (UEV) event generation.

0: UEV enabled. An UEV is generated by one of the following events:

– Counter overflow
– Setting the UG bit.

Buffered registers are then loaded with their preload values.

1: UEV disabled. No UEV is generated, shadow registers keep their value (ARR, PSC, CCRx). The counter and the prescaler are reinitialized if the UG bit is set.

Bit 0 CEN : Counter enable

0: Counter disabled

1: Counter enabled

18.5.2 TIM10/11/13/14 Interrupt enable register (TIMx_DIER)

Address offset: 0x0C

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	CC1IE	UIE
														rw	rw

Bits 15:2 Reserved, must be kept at reset value.

Bit 1 CC1IE : Capture/Compare 1 interrupt enable

0: CC1 interrupt disabled

1: CC1 interrupt enabled

Bit 0 UIE : Update interrupt enable

0: Update interrupt disabled

1: Update interrupt enabled

18.5.3 TIM10/11/13/14 status register (TIMx_SR)

Address offset: 0x10

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	Res.	CC1OF	Res.	Res.	Res.	Res.	Res.	Res.	Res.	CC1IF	UIF
						rc_w0								rc_w0	rc_w0

Bits 15:10 Reserved, must be kept at reset value.

Bit 9 CC1OF : Capture/Compare 1 overcapture flag

This flag is set by hardware only when the corresponding channel is configured in input capture mode. It is cleared by software by writing it to '0'.

0: No overcapture has been detected.

1: The counter value has been captured in TIMx_CCR1 register while CC1IF flag was already set

Bits 8:2 Reserved, must be kept at reset value.

Bit 1 CC1IF : Capture/compare 1 interrupt flag

If channel CC1 is configured as output:

This flag is set by hardware when the counter matches the compare value. It is cleared by software.

0: No match.

If channel CC1 is configured as input:

This bit is set by hardware on a capture. It is cleared by software or by reading the TIMx_CCR1 register.

0: No input capture occurred.

1: The counter value has been captured in TIMx_CCR1 register (an edge has been detected on IC1 which matches the selected polarity).

Bit 0 UIF : Update interrupt flag

This bit is set by hardware on an update event. It is cleared by software.

0: No update occurred.

1: Update interrupt pending. This bit is set by hardware when the registers are updated:

– At overflow and if UDIS='0' in the TIMx_CR1 register.
– When CNT is reinitialized by software using the UG bit in TIMx_EGR register, if URS='0' and UDIS='0' in the TIMx_CR1 register.

18.5.4 TIM10/11/13/14 event generation register (TIMx_EGR)

Address offset: 0x14

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	CC1G	UG
														w	w

Bits 15:2 Reserved, must be kept at reset value.

Bit 1 CC1G : Capture/compare 1 generation

This bit is set by software in order to generate an event, it is automatically cleared by hardware.

0: No action

1: A capture/compare event is generated on channel 1:

If channel CC1 is configured as output:

CC1IF flag is set, Corresponding interrupt or is sent if enabled.

If channel CC1 is configured as input:

The current value of the counter is captured in TIMx_CCR1 register. The CC1IF flag is set, the corresponding interrupt is sent if enabled. The CC1OF flag is set if the CC1IF flag was already high.

Bit 0 UG : Update generation

This bit can be set by software, it is automatically cleared by hardware.

0: No action

1: Re-initialize the counter and generates an update of the registers. Note that the prescaler counter is cleared too (anyway the prescaler ratio is not affected). The counter is cleared.

18.5.5 TIM10/11/13/14 capture/compare mode register 1 (TIMx_CCMR1)

Address offset: 0x18

Reset value: 0x0000

The channels can be used in input (capture mode) or in output (compare mode). The direction of a channel is defined by configuring the corresponding CCxS bits. All the other bits of this register have a different function in input and in output mode. For a given bit, OCxx describes its function when the channel is configured in output, ICxx describes its function when the channel is configured in input. So the user must take care that the same bit can have a different meaning for the input stage and for the output stage.

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	OC1M[2:0]			OC1PE	OC1FE	CC1S[1:0]
Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	IC1F[3:0]				IC1PSC[1:0]		CC1S[1:0]
								rw	rw	rw	rw	rw	rw	rw	rw

Output compare mode

Bits 15:7 Reserved, must be kept at reset value.

Bits 6:4 OC1M : Output compare 1 mode

These bits define the behavior of the output reference signal OC1REF from which OC1 is derived. OC1REF is active high whereas OC1 active level depends on CC1P bit.

000: Frozen. The comparison between the output compare register TIMx_CCR1 and the counter TIMx_CNT has no effect on the outputs.

001: Set channel 1 to active level on match. OC1REF signal is forced high when the counter TIMx_CNT matches the capture/compare register 1 (TIMx_CCR1).

010: Set channel 1 to inactive level on match. OC1REF signal is forced low when the counter TIMx_CNT matches the capture/compare register 1 (TIMx_CCR1).

011: Toggle - OC1REF toggles when TIMx_CNT = TIMx_CCR1.

100: Force inactive level - OC1REF is forced low.

101: Force active level - OC1REF is forced high.

110: PWM mode 1 - Channel 1 is active as long as TIMx_CNT < TIMx_CCR1 else inactive.

111: PWM mode 2 - Channel 1 is inactive as long as TIMx_CNT < TIMx_CCR1 else active.

Note: In PWM mode 1 or 2, the OCREF level changes when the result of the comparison changes or when the output compare mode switches from frozen to PWM mode.

Bit 3 OC1PE : Output compare 1 preload enable

0: Preload register on TIMx_CCR1 disabled. TIMx_CCR1 can be written at anytime, the new value is taken in account immediately.

1: Preload register on TIMx_CCR1 enabled. Read/Write operations access the preload register. TIMx_CCR1 preload value is loaded in the active register at each update event.

Bit 2 OC1FE : Output compare 1 fast enable

This bit is used to accelerate the effect of an event on the trigger input on the CC output.

0: CC1 behaves normally depending on counter and CCR1 values even when the trigger is ON. The minimum delay to activate CC1 output when an edge occurs on the trigger input is 5 clock cycles.

1: An active edge on the trigger input acts like a compare match on CC1 output. OC is then set to the compare level independently of the result of the comparison. Delay to sample the trigger input and to activate CC1 output is reduced to 3 clock cycles. OC1FE acts only if the channel is configured in PWM1 or PWM2 mode.

Bits 1:0 CC1S : Capture/Compare 1 selection

This bit-field defines the direction of the channel (input/output) as well as the used input.

00: CC1 channel is configured as output.

01: CC1 channel is configured as input, IC1 is mapped on TI1.

10:

11:

Note: CC1S bits are writable only when the channel is OFF (CC1E = 0 in TIMx_CCER).

Input capture mode

Bits 15:8 Reserved, must be kept at reset value.

Bits 7:4 IC1F : Input capture 1 filter

This bit-field defines the frequency used to sample TI1 input and the length of the digital filter applied to TI1. The digital filter is made of an event counter in which N consecutive events are needed to validate a transition on the output:

0000: No filter, sampling is done at $f_{DTS}$	1000: $f_{SAMPLING}=f_{DTS}/8$ , N=6
0001: $f_{SAMPLING}=f_{CK\_INT}$ , N=2	1001: $f_{SAMPLING}=f_{DTS}/8$ , N=8
0010: $f_{SAMPLING}=f_{CK\_INT}$ , N=4	1010: $f_{SAMPLING}=f_{DTS}/16$ , N=5
0011: $f_{SAMPLING}=f_{CK\_INT}$ , N=8	1011: $f_{SAMPLING}=f_{DTS}/16$ , N=6
0100: $f_{SAMPLING}=f_{DTS}/2$ , N=6	1100: $f_{SAMPLING}=f_{DTS}/16$ , N=8
0101: $f_{SAMPLING}=f_{DTS}/2$ , N=8	1101: $f_{SAMPLING}=f_{DTS}/32$ , N=5
0110: $f_{SAMPLING}=f_{DTS}/4$ , N=6	1110: $f_{SAMPLING}=f_{DTS}/32$ , N=6
0111: $f_{SAMPLING}=f_{DTS}/4$ , N=8	1111: $f_{SAMPLING}=f_{DTS}/32$ , N=8

Bits 3:2 IC1PSC : Input capture 1 prescaler

This bit-field defines the ratio of the prescaler acting on CC1 input (IC1).

The prescaler is reset as soon as CC1E='0' (TIMx_CCER register).

00: no prescaler, capture is done each time an edge is detected on the capture input

01: capture is done once every 2 events

10: capture is done once every 4 events

11: capture is done once every 8 events

Bits 1:0 CC1S : Capture/Compare 1 selection

This bit-field defines the direction of the channel (input/output) as well as the used input.

00: CC1 channel is configured as output

01: CC1 channel is configured as input, IC1 is mapped on TI1

10: Reserved

11: Reserved

Note: CC1S bits are writable only when the channel is OFF (CC1E = 0 in TIMx_CCER).

18.5.6 TIM10/11/13/14 capture/compare enable register (TIMx_CCER)

Address offset: 0x20

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	CC1NP	Res.	CC1P	CC1E
												rw		rw	rw

Bits 15:4 Reserved, must be kept at reset value.

Bit 3 CC1NP : Capture/Compare 1 complementary output Polarity.

CC1 channel configured as output: CC1NP must be kept cleared.

CC1 channel configured as input: CC1NP bit is used in conjunction with CC1P to define TI1FP1 polarity (refer to CC1P description).

Bit 2 Reserved, must be kept at reset value.

Bit 1 CC1P : Capture/Compare 1 output Polarity.

CC1 channel configured as output:

0: OC1 active high

1: OC1 active low

CC1 channel configured as input:

The CC1P bit selects TI1FP1 and TI2FP1 polarity for trigger or capture operations.

00: noninverted/rising edge

Circuit is sensitive to TI1FP1 rising edge (capture mode), TI1FP1 is not inverted.

01: inverted/falling edge

Circuit is sensitive to TI1FP1 falling edge (capture mode), TI1FP1 is inverted.

10: reserved, do not use this configuration.

11: noninverted/both edges

Circuit is sensitive to both TI1FP1 rising and falling edges (capture mode), TI1FP1 is not inverted.

Bit 0 CC1E : Capture/Compare 1 output enable.

CC1 channel configured as output:

0: Off - OC1 is not active

1: On - OC1 signal is output on the corresponding output pin

CC1 channel configured as input:

This bit determines if a capture of the counter value can actually be done into the input capture/compare register 1 (TIMx_CCR1) or not.

0: Capture disabled

1: Capture enabled

Table 118. Output control bit for standard OCx channels

CCxE bit	OCx output state
0	Output Disabled (OCx='0', OCx_EN='0')
1	OCx=OCxREF + Polarity, OCx_EN='1'

Note: The state of the external I/O pins connected to the standard OCx channels depends on the OCx channel state and the GPIO registers.

18.5.7 TIM10/11/13/14 counter (TIMx_CNT)

Address offset: 0x24

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
CNT[15:0]
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bits 15:0 CNT[15:0] : Counter value

18.5.8 TIM10/11/13/14 prescaler (TIMx_PSC)

Address offset: 0x28

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
PSC[15:0]
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bits 15:0 PSC[15:0] : Prescaler value

The counter clock frequency $CK\_CNT$ is equal to $f_{CK\_PSC} / (PSC[15:0] + 1)$ .

PSC contains the value to be loaded in the active prescaler register at each update event.

18.5.9 TIM10/11/13/14 auto-reload register (TIMx_ARR)

Address offset: 0x2C

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
ARR[15:0]
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bits 15:0 ARR[15:0] : Auto-reload value

ARR is the value to be loaded in the actual auto-reload register.

Refer to Section 18.3.1: Time-base unit for more details about ARR update and behavior.

The counter is blocked while the auto-reload value is null.

18.5.10 TIM10/11/13/14 capture/compare register 1 (TIMx_CCR1)

Address offset: 0x34

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
CCR1[15:0]
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bits 15:0 CCR1[15:0] : Capture/Compare 1 value

If channel CC1 is configured as output:

CCR1 is the value to be loaded in the actual capture/compare 1 register (preload value).

It is loaded permanently if the preload feature is not selected in the TIMx_CCMR1 register (bit OC1PE). Else the preload value is copied in the active capture/compare 1 register when an update event occurs.

The active capture/compare register contains the value to be compared to the counter TIMx_CNT and signaled on OC1 output.

If channel CC1 is configured as input:

CCR1 is the counter value transferred by the last input capture 1 event (IC1).

18.5.11 TIM11 option register 1 (TIM11_OR)

Address offset: 0x50

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	TI1_RMP[1:0]
															rw

Bits 15:2 Reserved, must be kept at reset value.

Bits 1:0 TI1_RMP[1:0] : TIM11 Input 1 remapping capability

Set and cleared by software.

00,11: TIM11 Channel1 is connected to the GPIO (refer to the Alternate function mapping table in the datasheets).

01: SPDIFRX_FRAME_SYNC is connected to TIM11_CH1 to measure the clock drift of received SPDIF frames.

10: HSE_RTC clock (HSE divided by programmable prescaler) is connected to the TIM11_CH1 input for measurement purposes.

18.5.12 TIM10/11/13/14 register map

TIMx registers are mapped as 16-bit addressable registers as described in the table below:

Table 119. TIM10/11/13/14 register map and reset values

Offset	Register	31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
0x00	TIMx_CR1	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	CKD [1:0]		ARPE	Res.	Res.	Res.	Res.	URS	UDIS	CEN
0x00	Reset value																							0	0	0					0	0	0
0x08	TIMx_SMCR	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.
0x08	Reset value
0x0C	TIMx_DIER	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	CC1IE	UIE
0x0C	Reset value																															0	0
0x10	TIMx_SR	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	CC1OF	Res.	Res.	Res.	Res.	Res.	Res.	Res.	CC1IF	UIF
0x10	Reset value																							0								0	0
0x14	TIMx_EGR	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	CC1G	UG
0x14	Reset value																															0	0
0x18	TIMx_CCMR1 Output compare mode	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	OC1M [2:0]			OC1PE	OC1FE	CC1S [1:0]
	Reset value																									0	0	0	0	0	0	0
	TIMx_CCMR1 Input capture mode	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	IC1F[3:0]				IC1PSC [1:0]		CC1S [1:0]
	Reset value																									0	0	0	0	0	0	0	0
0x1C	Reserved	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.
0x20	TIMx_CCER	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	CC1NP	Res.	CC1P	CC1E
0x20	Reset value																													0		0	0
0x24	TIMx_CNT	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	CNT[15:0]
0x24	Reset value																	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x28	TIMx_PSC	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	PSC[15:0]
0x28	Reset value																	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x2C	TIMx_ARR	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	ARR[15:0]
0x2C	Reset value																	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x30	Reserved	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.	Res.

Table 119. TIM10/11/13/14 register map and reset values (continued)

Offset	Register	31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
0x34	TIMx_CCR1	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	CCR1[15:0]
0x34	Reset value																	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x38 to 0x4C	Reserved	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res
0x50	TIMx_OR	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	Res	T1/_RMP
0x50	Reset value																															0	0

Refer to Section 2.2 on page 56 for the register boundary addresses.