ADRDY

Bit 0: ADC ready This bit is set by hardware after the ADC has been enabled (ADEN = 1) and when the ADC reaches a state where it is ready to accept conversion requests. It is cleared by software writing 1 to it..

Allowed values:
0: NotReady: ADC not yet ready to start conversion
1: Ready: ADC ready to start conversion

EOSMP

Bit 1: End of sampling flag This bit is set by hardware during the conversion, at the end of the sampling phase.It is cleared by software by programming it to '1'..

Allowed values:
0: NotAtEnd: Not at the end of the samplings phase
1: AtEnd: End of sampling phase reached

EOC

Bit 2: End of conversion flag This bit is set by hardware at the end of each conversion of a channel when a new data result is available in the ADC_DR register. It is cleared by software writing 1 to it or by reading the ADC_DR register..

Allowed values:
0: NotComplete: Channel conversion is not complete
1: Complete: Channel conversion complete

EOS

Bit 3: End of sequence flag This bit is set by hardware at the end of the conversion of a sequence of channels selected by the CHSEL bits. It is cleared by software writing 1 to it..

Allowed values:
0: NotComplete: Conversion sequence is not complete
1: Complete: Conversion sequence complete

OVR

Bit 4: ADC overrun This bit is set by hardware when an overrun occurs, meaning that a new conversion has complete while the EOC flag was already set. It is cleared by software writing 1 to it..

Allowed values:
0: NoOverrun: No overrun occurred
1: Overrun: Overrun occurred

AWD1

Bit 7: Analog watchdog 1 flag This bit is set by hardware when the converted voltage crosses the values programmed in ADC_TR1 and ADC_HR1 registers. It is cleared by software by programming it to 1..

Allowed values:
0: NoEvent: No analog watchdog event occurred
1: Event: Analog watchdog event occurred

AWD2

Bit 8: Analog watchdog 2 flag This bit is set by hardware when the converted voltage crosses the values programmed in ADC_AWD2TR and ADC_AWD2TR registers. It is cleared by software programming it it..

Allowed values:
0: NoEvent: No analog watchdog event occurred
1: Event: Analog watchdog event occurred

AWD3

Bit 9: Analog watchdog 3 flag This bit is set by hardware when the converted voltage crosses the values programmed in ADC_AWD3TR and ADC_AWD3TR registers. It is cleared by software by programming it to 1..

Allowed values:
0: NoEvent: No analog watchdog event occurred
1: Event: Analog watchdog event occurred

EOCAL

Bit 11: End Of Calibration flag This bit is set by hardware when calibration is complete. It is cleared by software writing 1 to it..

Allowed values:
0: NotComplete: Calibration is not complete
1: Complete: Calibration complete

CCRDY

Bit 13: Channel Configuration Ready flag This flag bit is set by hardware when the channel configuration is applied after programming to ADC_CHSELR register or changing CHSELRMOD or SCANDIR. It is cleared by software by programming it to it. Note: When the software configures the channels (by programming ADC_CHSELR or changing CHSELRMOD or SCANDIR), it must wait until the CCRDY flag rises before configuring again or starting conversions, otherwise the new configuration (or the START bit) is ignored. Once the flag is asserted, if the software needs to configure again the channels, it must clear the CCRDY flag before proceeding with a new configuration..

Allowed values:
0: NotComplete: Channel configuration update not applied
1: Complete: Channel configuration update is applied

ADRDYIE

Bit 0: ADC ready interrupt enable This bit is set and cleared by software to enable/disable the ADC Ready interrupt. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: ADRDY interrupt disabled
1: Enabled: ADRDY interrupt enabled. An interrupt is generated when the ADRDY bit is set.

EOSMPIE

Bit 1: End of sampling flag interrupt enable This bit is set and cleared by software to enable/disable the end of the sampling phase interrupt. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: EOSMP interrupt disabled
1: Enabled: EOSMP interrupt enabled. An interrupt is generated when the EOSMP bit is set.

EOCIE

Bit 2: End of conversion interrupt enable This bit is set and cleared by software to enable/disable the end of conversion interrupt. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: EOC interrupt disabled
1: Enabled: EOC interrupt enabled. An interrupt is generated when the EOC bit is set.

EOSIE

Bit 3: End of conversion sequence interrupt enable This bit is set and cleared by software to enable/disable the end of sequence of conversions interrupt. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: EOS interrupt disabled
1: Enabled: EOS interrupt enabled. An interrupt is generated when the EOS bit is set.

OVRIE

Bit 4: Overrun interrupt enable This bit is set and cleared by software to enable/disable the overrun interrupt. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Overrun interrupt disabled
1: Enabled: Overrun interrupt enabled. An interrupt is generated when the OVR bit is set.

AWD1IE

Bit 7: Analog watchdog 1 interrupt enable This bit is set and cleared by software to enable/disable the analog watchdog interrupt. Note: The Software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Analog watchdog interrupt disabled
1: Enabled: Analog watchdog interrupt enabled

AWD2IE

Bit 8: Analog watchdog 2 interrupt enable This bit is set and cleared by software to enable/disable the analog watchdog interrupt. Note: The Software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Analog watchdog interrupt disabled
1: Enabled: Analog watchdog interrupt enabled

AWD3IE

Bit 9: Analog watchdog 3 interrupt enable This bit is set and cleared by software to enable/disable the analog watchdog interrupt. Note: The Software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Analog watchdog interrupt disabled
1: Enabled: Analog watchdog interrupt enabled

EOCALIE

Bit 11: End of calibration interrupt enable This bit is set and cleared by software to enable/disable the end of calibration interrupt. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: End of calibration interrupt disabled
1: Enabled: End of calibration interrupt enabled

CCRDYIE

Bit 13: Channel Configuration Ready Interrupt enable This bit is set and cleared by software to enable/disable the channel configuration ready interrupt. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Channel configuration ready interrupt disabled
1: Enabled: Channel configuration ready interrupt enabled

ADEN

Bit 0: ADC enable command This bit is set by software to enable the ADC. The ADC is effectively ready to operate once the ADRDY flag has been set. It is cleared by hardware when the ADC is disabled, after the execution of the ADDIS command. Note: The software is allowed to set ADEN only when all bits of ADC_CR registers are 0 (ADCAL = 0, ADSTP=0, ADSTART=0, ADDIS=0 and ADEN=0).

Allowed values:
0: Disabled: ADC disabled
1: Enabled: ADC enabled

ADDIS

Bit 1: ADC disable command This bit is set by software to disable the ADC (ADDIS command) and put it into power-down state (OFF state). It is cleared by hardware once the ADC is effectively disabled (ADEN is also cleared by hardware at this time). Note: Setting ADDIS to '1' is only effective when ADEN = 1 and ADSTART = 0 (which ensures that no conversion is ongoing).

Allowed values:
0: NotDisabling: No disable command active
1: Disabling: ADC disabling

ADSTART

Bit 2: ADC start conversion command This bit is set by software to start ADC conversion. Depending on the EXTEN [1:0] configuration bits, a conversion either starts immediately (software trigger configuration) or once a hardware trigger event occurs (hardware trigger configuration). It is cleared by hardware: In single conversion mode (CONT = 0, DISCEN = 0), when software trigger is selected (EXTEN = 00): at the assertion of the end of Conversion Sequence (EOS) flag. In discontinuous conversion mode(CONT = 0, DISCEN = 1), when the software trigger is selected (EXTEN = 00): at the assertion of the end of Conversion (EOC) flag. In all other cases: after the execution of the ADSTP command, at the same time as the ADSTP bit is cleared by hardware. Note: The software is allowed to set ADSTART only when ADEN = 1 and ADDIS = 0 (ADC is enabled and there is no pending request to disable the ADC). After writing to ADC_CHSELR register or changing CHSELRMOD or SCANDIRW, it is mandatory to wait until CCRDY flag is asserted before setting ADSTART, otherwise, the value written to ADSTART is ignored..

Allowed values:
0: NotActive: No conversion ongoing
1: Active: ADC operating and may be converting

ADSTP

Bit 4: ADC stop conversion command This bit is set by software to stop and discard an ongoing conversion (ADSTP Command). It is cleared by hardware when the conversion is effectively discarded and the ADC is ready to accept a new start conversion command. Note: Setting ADSTP to '1' is only effective when ADSTART = 1 and ADDIS = 0 (ADC is enabled and may be converting and there is no pending request to disable the ADC).

Allowed values:
0: NotStopping: No stop command active
1: Stopping: ADC stopping conversion

ADVREGEN

Bit 28: ADC Voltage Regulator Enable This bit is set by software, to enable the ADC internal voltage regulator. The voltage regulator output is available after tADCVREG_SETUP. It is cleared by software to disable the voltage regulator. It can be cleared only if ADEN is et to 0. Note: The software is allowed to program this bit field only when the ADC is disabled (ADCAL = 0, ADSTART = 0, ADSTP = 0, ADDIS = 0 and ADEN = 0)..

Allowed values:
0: Disabled: ADC voltage regulator disabled
1: Enabled: ADC voltage regulator enabled

ADCAL

Bit 31: ADC calibration This bit is set by software to start the calibration of the ADC. It is cleared by hardware after calibration is complete. Note: The software is allowed to set ADCAL only when the ADC is disabled (ADCAL=0, ADSTART=0, ADSTP=0, ADDIS=0 and ADEN=0). The software is allowed to update the calibration factor by writing ADC_CALFACT only when ADEN=1 and ADSTART=0 (ADC enabled and no conversion is ongoing)..

Allowed values:
0: NotCalibrating: ADC calibration either not yet performed or completed
1: Calibrating: ADC calibration in progress

DMAEN

Bit 0: Direct memory access enable This bit is set and cleared by software to enable the generation of DMA requests. This allows the DMA controller to be used to manage automatically the converted data. For more details, refer to . Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: DMA disabled
1: Enabled: DMA enabled

DMACFG

Bit 1: Direct memory access configuration This bit is set and cleared by software to select between two DMA modes of operation and is effective only when DMAEN=1. For more details, refer to page391 Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: OneShot: DMA one shot mode selected
1: Circular: DMA circular mode selected

SCANDIR

Bit 2: Scan sequence direction This bit is set and cleared by software to select the direction in which the channels is scanned in the sequence. It is effective only if CHSELMOD bit is cleared to 0. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: Upward: Upward scan (from CHSEL0 to CHSEL17)
1: Backward: Backward scan (from CHSEL17 to CHSEL0)

RES

Bits 3-4: Data resolution These bits are written by software to select the resolution of the conversion. Note: The software is allowed to write these bits only when ADEN=0..

Allowed values:
0: Bits12: 12 bits
1: Bits10: 10 bits
2: Bits8: 8 bits
3: Bits6: 6 bits

ALIGN

Bit 5: Data alignment This bit is set and cleared by software to select right or left alignment. Refer to Data alignment and resolution (oversampling disabled: OVSE = 0) on page389 Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Right: Right alignment
1: Left: Left alignment

EXTSEL

Bits 6-8: External trigger selection These bits select the external event used to trigger the start of conversion (refer to External triggers for details): Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: TIM1_TRGO: Timer 1 TRGO event
1: TIM1_CC4: Timer 1 CC4 event
2: TIM2_TRGO: Timer 2 TRGO event
3: TIM2_CH4: Timer 2 CH4 event
5: TIM2_CH3: Timer 2 CH3 event
7: EXTI_LINE11: EXTI line 11 event

EXTEN

Bits 10-11: External trigger enable and polarity selection These bits are set and cleared by software to select the external trigger polarity and enable the trigger. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Hardware trigger detection disabled
1: RisingEdge: Hardware trigger detection on the rising edge
2: FallingEdge: Hardware trigger detection on the falling edge
3: BothEdges: Hardware trigger detection on both the rising and falling edges

OVRMOD

Bit 12: Overrun management mode This bit is set and cleared by software and configure the way data overruns are managed. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Preserve: ADC_DR register is preserved with the old data when an overrun is detected
1: Overwrite: ADC_DR register is overwritten with the last conversion result when an overrun is detected

CONT

Bit 13: Single / continuous conversion mode This bit is set and cleared by software. If it is set, conversion takes place continuously until it is cleared. Note: It is not possible to have both discontinuous mode and continuous mode enabled: it is forbidden to set both bits DISCEN=1 and CONT=1. The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Single: Single conversion mode
1: Continuous: Continuous conversion mode

WAIT

Bit 14: Wait conversion mode This bit is set and cleared by software to enable/disable wait conversion mode.. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Wait conversion mode off
1: Enabled: Wait conversion mode on

AUTOFF

Bit 15: Auto-off mode This bit is set and cleared by software to enable/disable auto-off mode.. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Auto-off mode disabled
1: Enabled: Auto-off mode enabled

DISCEN

Bit 16: Discontinuous mode This bit is set and cleared by software to enable/disable discontinuous mode. Note: It is not possible to have both discontinuous mode and continuous mode enabled: it is forbidden to set both bits DISCEN=1 and CONT=1. The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Discontinuous mode disabled
1: Enabled: Discontinuous mode enabled

CHSELRMOD

Bit 21: Mode selection of the ADC_CHSELR register This bit is set and cleared by software to control the ADC_CHSELR feature: Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: BitPerInput: Each bit of the ADC_CHSELR register enables an input
1: Sequence: ADC_CHSELR register is able to sequence up to 8 channels

AWD1SGL

Bit 22: Enable the watchdog on a single channel or on all channels This bit is set and cleared by software to enable the analog watchdog on the channel identified by the AWDCH[4:0] bits or on all the channels Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: AllChannels: Analog watchdog 1 enabled on all channels
1: SingleChannel: Analog watchdog 1 enabled on a single channel

AWD1EN

Bit 23: Analog watchdog enable This bit is set and cleared by software. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Analog watchdog 1 disabled
1: Enabled: Analog watchdog 1 enabled

AWD1CH

Bits 26-30: Analog watchdog channel selection These bits are set and cleared by software. They select the input channel to be guarded by the analog watchdog. ..... Others: Reserved Note: The channel selected by the AWDCH[4:0] bits must be also set into the CHSELR register. The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values: 0x0-0x11

OVSE

Bit 0: Oversampler Enable This bit is set and cleared by software. Note: Software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Oversampler disabled
1: Enabled: Oversampler enabled

OVSR

Bits 2-4: Oversampling ratio This bit filed defines the number of oversampling ratio. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Mul2: 2x
1: Mul4: 4x
2: Mul8: 8x
3: Mul16: 16x
4: Mul32: 32x
5: Mul64: 64x
6: Mul128: 128x
7: Mul256: 256x

OVSS

Bits 5-8: Oversampling shift This bit is set and cleared by software. Others: Reserved Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NoShift: No shift
1: Shift1: Shift 1-bit
2: Shift2: Shift 2-bits
3: Shift3: Shift 3-bits
4: Shift4: Shift 4-bits
5: Shift5: Shift 5-bits
6: Shift6: Shift 6-bits
7: Shift7: Shift 7-bits
8: Shift8: Shift 8-bits

TOVS

Bit 9: Triggered Oversampling This bit is set and cleared by software. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: TriggerAll: All oversampled conversions for a channel are done consecutively after a trigger
1: TriggerEach: Each oversampled conversion for a channel needs a trigger

LFTRIG

Bit 29: Low frequency trigger mode enable This bit is set and cleared by software. Note: The software is allowed to write this bit only when ADSTART bit is cleared to 0 (this ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Low Frequency Trigger Mode disabled
1: Enabled: Low Frequency Trigger Mode enabled

CKMODE

Bits 30-31: ADC clock mode These bits are set and cleared by software to define how the analog ADC is clocked: In all synchronous clock modes, there is no jitter in the delay from a timer trigger to the start of a conversion. Note: The software is allowed to write these bits only when the ADC is disabled (ADCAL=0, ADSTART=0, ADSTP=0, ADDIS=0 and ADEN=0)..

Allowed values:
0: ADCLK: ADCCLK (Asynchronous clock mode)
1: PCLK_Div2: PCLK/2 (Synchronous clock mode)
2: PCLK_Div4: PCLK/4 (Synchronous clock mode)
3: PCLK: PCLK (Synchronous clock mode)

SMP1

Bits 0-2: Sampling time selection 1 These bits are written by software to select the sampling time that applies to all channels. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Cycles1_5: 1.5 ADC clock cycles
1: Cycles3_5: 3.5 ADC clock cycles
2: Cycles7_5: 7.5 ADC clock cycles
3: Cycles12_5: 12.5 ADC clock cycles
4: Cycles19_5: 19.5 ADC clock cycles
5: Cycles39_5: 39.5 ADC clock cycles
6: Cycles79_5: 79.5 ADC clock cycles
7: Cycles160_5: 160.5 ADC clock cycles

SMP2

Bits 4-6: Sampling time selection 2 These bits are written by software to select the sampling time that applies to all channels. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Cycles1_5: 1.5 ADC clock cycles
1: Cycles3_5: 3.5 ADC clock cycles
2: Cycles7_5: 7.5 ADC clock cycles
3: Cycles12_5: 12.5 ADC clock cycles
4: Cycles19_5: 19.5 ADC clock cycles
5: Cycles39_5: 39.5 ADC clock cycles
6: Cycles79_5: 79.5 ADC clock cycles
7: Cycles160_5: 160.5 ADC clock cycles

SMPSEL0

Bit 8: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL1

Bit 9: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL2

Bit 10: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL3

Bit 11: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL4

Bit 12: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL5

Bit 13: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL6

Bit 14: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL7

Bit 15: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL8

Bit 16: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL9

Bit 17: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL10

Bit 18: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL11

Bit 19: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL12

Bit 20: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL13

Bit 21: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL14

Bit 22: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL15

Bit 23: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL16

Bit 24: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL17

Bit 25: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

SMPSEL18

Bit 26: Channel-x sampling time selection These bits are written by software to define which sampling time is used. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Smp1: Sampling time of CHANNELx use the setting of SMP1 register
1: Smp2: Sampling time of CHANNELx use the setting of SMP2 register

LT1

Bits 0-11: Analog watchdog 1 lower threshold These bits are written by software to define the lower threshold for the analog watchdog. Refer to ADC_AWDxTR) on page395..

Allowed values: 0x0-0xfff

HT1

Bits 16-27: Analog watchdog 1 higher threshold These bits are written by software to define the higher threshold for the analog watchdog. Refer to ADC_AWDxTR) on page395..

Allowed values: 0x0-0xfff

LT2

Bits 0-11: Analog watchdog 2 lower threshold These bits are written by software to define the lower threshold for the analog watchdog. Refer to ADC_AWDxTR) on page395..

Allowed values: 0x0-0xfff

HT2

Bits 16-27: Analog watchdog 2 higher threshold These bits are written by software to define the higher threshold for the analog watchdog. Refer to ADC_AWDxTR) on page395..

Allowed values: 0x0-0xfff

CHSEL0

Bit 0: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL1

Bit 1: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL2

Bit 2: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL3

Bit 3: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL4

Bit 4: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL5

Bit 5: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL6

Bit 6: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL7

Bit 7: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL8

Bit 8: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL9

Bit 9: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL10

Bit 10: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL11

Bit 11: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL12

Bit 12: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL13

Bit 13: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL14

Bit 14: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL15

Bit 15: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL16

Bit 16: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL17

Bit 17: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

CHSEL18

Bit 18: Channel-x selection These bits are written by software and define which channels are part of the sequence of channels to be converted. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing). If CCRDY is not yet asserted after channel configuration (writing ADC_CHSELR register or changing CHSELRMOD or SCANDIR), the value written to this bit is ignored..

Allowed values:
0: NotSelected: Input Channel is not selected for conversion
1: Selected: Input Channel is selected for conversion

SQ1

Bits 0-3: 1st conversion of the sequence These bits are programmed by software with the channel number (0...14) assigned to the 8th conversion of the sequence. 0b1111 indicates end of the sequence. When 0b1111 (end of sequence) is programmed to the lower sequence channels, these bits are ignored. Refer to SQ8[3:0] for a definition of channel selection. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Ch0: Channel 0 selected for the Nth conversion
1: Ch1: Channel 1 selected for the Nth conversion
2: Ch2: Channel 2 selected for the Nth conversion
3: Ch3: Channel 3 selected for the Nth conversion
4: Ch4: Channel 4 selected for the Nth conversion
5: Ch5: Channel 5 selected for the Nth conversion
6: Ch6: Channel 6 selected for the Nth conversion
7: Ch7: Channel 7 selected for the Nth conversion
8: Ch8: Channel 8 selected for the Nth conversion
9: Ch9: Channel 9 selected for the Nth conversion
10: Ch10: Channel 10 selected for the Nth conversion
11: Ch11: Channel 11 selected for the Nth conversion
12: Ch12: Channel 12 selected for the Nth conversion
13: Ch13: Channel 13 selected for the Nth conversion
14: Ch14: Channel 14 selected for the Nth conversion
15: EOS: End of sequence

SQ2

Bits 4-7: 2nd conversion of the sequence These bits are programmed by software with the channel number (0...14) assigned to the 8th conversion of the sequence. 0b1111 indicates end of the sequence. When 0b1111 (end of sequence) is programmed to the lower sequence channels, these bits are ignored. Refer to SQ8[3:0] for a definition of channel selection. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Ch0: Channel 0 selected for the Nth conversion
1: Ch1: Channel 1 selected for the Nth conversion
2: Ch2: Channel 2 selected for the Nth conversion
3: Ch3: Channel 3 selected for the Nth conversion
4: Ch4: Channel 4 selected for the Nth conversion
5: Ch5: Channel 5 selected for the Nth conversion
6: Ch6: Channel 6 selected for the Nth conversion
7: Ch7: Channel 7 selected for the Nth conversion
8: Ch8: Channel 8 selected for the Nth conversion
9: Ch9: Channel 9 selected for the Nth conversion
10: Ch10: Channel 10 selected for the Nth conversion
11: Ch11: Channel 11 selected for the Nth conversion
12: Ch12: Channel 12 selected for the Nth conversion
13: Ch13: Channel 13 selected for the Nth conversion
14: Ch14: Channel 14 selected for the Nth conversion
15: EOS: End of sequence

SQ3

Bits 8-11: 3rd conversion of the sequence These bits are programmed by software with the channel number (0...14) assigned to the 8th conversion of the sequence. 0b1111 indicates end of the sequence. When 0b1111 (end of sequence) is programmed to the lower sequence channels, these bits are ignored. Refer to SQ8[3:0] for a definition of channel selection. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Ch0: Channel 0 selected for the Nth conversion
1: Ch1: Channel 1 selected for the Nth conversion
2: Ch2: Channel 2 selected for the Nth conversion
3: Ch3: Channel 3 selected for the Nth conversion
4: Ch4: Channel 4 selected for the Nth conversion
5: Ch5: Channel 5 selected for the Nth conversion
6: Ch6: Channel 6 selected for the Nth conversion
7: Ch7: Channel 7 selected for the Nth conversion
8: Ch8: Channel 8 selected for the Nth conversion
9: Ch9: Channel 9 selected for the Nth conversion
10: Ch10: Channel 10 selected for the Nth conversion
11: Ch11: Channel 11 selected for the Nth conversion
12: Ch12: Channel 12 selected for the Nth conversion
13: Ch13: Channel 13 selected for the Nth conversion
14: Ch14: Channel 14 selected for the Nth conversion
15: EOS: End of sequence

SQ4

Bits 12-15: 4th conversion of the sequence These bits are programmed by software with the channel number (0...14) assigned to the 8th conversion of the sequence. 0b1111 indicates end of the sequence. When 0b1111 (end of sequence) is programmed to the lower sequence channels, these bits are ignored. Refer to SQ8[3:0] for a definition of channel selection. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Ch0: Channel 0 selected for the Nth conversion
1: Ch1: Channel 1 selected for the Nth conversion
2: Ch2: Channel 2 selected for the Nth conversion
3: Ch3: Channel 3 selected for the Nth conversion
4: Ch4: Channel 4 selected for the Nth conversion
5: Ch5: Channel 5 selected for the Nth conversion
6: Ch6: Channel 6 selected for the Nth conversion
7: Ch7: Channel 7 selected for the Nth conversion
8: Ch8: Channel 8 selected for the Nth conversion
9: Ch9: Channel 9 selected for the Nth conversion
10: Ch10: Channel 10 selected for the Nth conversion
11: Ch11: Channel 11 selected for the Nth conversion
12: Ch12: Channel 12 selected for the Nth conversion
13: Ch13: Channel 13 selected for the Nth conversion
14: Ch14: Channel 14 selected for the Nth conversion
15: EOS: End of sequence

SQ5

Bits 16-19: 5th conversion of the sequence These bits are programmed by software with the channel number (0...14) assigned to the 8th conversion of the sequence. 0b1111 indicates end of the sequence. When 0b1111 (end of sequence) is programmed to the lower sequence channels, these bits are ignored. Refer to SQ8[3:0] for a definition of channel selection. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Ch0: Channel 0 selected for the Nth conversion
1: Ch1: Channel 1 selected for the Nth conversion
2: Ch2: Channel 2 selected for the Nth conversion
3: Ch3: Channel 3 selected for the Nth conversion
4: Ch4: Channel 4 selected for the Nth conversion
5: Ch5: Channel 5 selected for the Nth conversion
6: Ch6: Channel 6 selected for the Nth conversion
7: Ch7: Channel 7 selected for the Nth conversion
8: Ch8: Channel 8 selected for the Nth conversion
9: Ch9: Channel 9 selected for the Nth conversion
10: Ch10: Channel 10 selected for the Nth conversion
11: Ch11: Channel 11 selected for the Nth conversion
12: Ch12: Channel 12 selected for the Nth conversion
13: Ch13: Channel 13 selected for the Nth conversion
14: Ch14: Channel 14 selected for the Nth conversion
15: EOS: End of sequence

SQ6

Bits 20-23: 6th conversion of the sequence These bits are programmed by software with the channel number (0...14) assigned to the 8th conversion of the sequence. 0b1111 indicates end of the sequence. When 0b1111 (end of sequence) is programmed to the lower sequence channels, these bits are ignored. Refer to SQ8[3:0] for a definition of channel selection. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Ch0: Channel 0 selected for the Nth conversion
1: Ch1: Channel 1 selected for the Nth conversion
2: Ch2: Channel 2 selected for the Nth conversion
3: Ch3: Channel 3 selected for the Nth conversion
4: Ch4: Channel 4 selected for the Nth conversion
5: Ch5: Channel 5 selected for the Nth conversion
6: Ch6: Channel 6 selected for the Nth conversion
7: Ch7: Channel 7 selected for the Nth conversion
8: Ch8: Channel 8 selected for the Nth conversion
9: Ch9: Channel 9 selected for the Nth conversion
10: Ch10: Channel 10 selected for the Nth conversion
11: Ch11: Channel 11 selected for the Nth conversion
12: Ch12: Channel 12 selected for the Nth conversion
13: Ch13: Channel 13 selected for the Nth conversion
14: Ch14: Channel 14 selected for the Nth conversion
15: EOS: End of sequence

SQ7

Bits 24-27: 7th conversion of the sequence These bits are programmed by software with the channel number (0...14) assigned to the 8th conversion of the sequence. 0b1111 indicates end of the sequence. When 0b1111 (end of sequence) is programmed to the lower sequence channels, these bits are ignored. Refer to SQ8[3:0] for a definition of channel selection. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Ch0: Channel 0 selected for the Nth conversion
1: Ch1: Channel 1 selected for the Nth conversion
2: Ch2: Channel 2 selected for the Nth conversion
3: Ch3: Channel 3 selected for the Nth conversion
4: Ch4: Channel 4 selected for the Nth conversion
5: Ch5: Channel 5 selected for the Nth conversion
6: Ch6: Channel 6 selected for the Nth conversion
7: Ch7: Channel 7 selected for the Nth conversion
8: Ch8: Channel 8 selected for the Nth conversion
9: Ch9: Channel 9 selected for the Nth conversion
10: Ch10: Channel 10 selected for the Nth conversion
11: Ch11: Channel 11 selected for the Nth conversion
12: Ch12: Channel 12 selected for the Nth conversion
13: Ch13: Channel 13 selected for the Nth conversion
14: Ch14: Channel 14 selected for the Nth conversion
15: EOS: End of sequence

SQ8

Bits 28-31: 8th conversion of the sequence These bits are programmed by software with the channel number (0...14) assigned to the 8th conversion of the sequence. 0b1111 indicates the end of the sequence. When 0b1111 (end of sequence) is programmed to the lower sequence channels, these bits are ignored. ... Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Ch0: Channel 0 selected for the Nth conversion
1: Ch1: Channel 1 selected for the Nth conversion
2: Ch2: Channel 2 selected for the Nth conversion
3: Ch3: Channel 3 selected for the Nth conversion
4: Ch4: Channel 4 selected for the Nth conversion
5: Ch5: Channel 5 selected for the Nth conversion
6: Ch6: Channel 6 selected for the Nth conversion
7: Ch7: Channel 7 selected for the Nth conversion
8: Ch8: Channel 8 selected for the Nth conversion
9: Ch9: Channel 9 selected for the Nth conversion
10: Ch10: Channel 10 selected for the Nth conversion
11: Ch11: Channel 11 selected for the Nth conversion
12: Ch12: Channel 12 selected for the Nth conversion
13: Ch13: Channel 13 selected for the Nth conversion
14: Ch14: Channel 14 selected for the Nth conversion
15: EOS: End of sequence

LT3

Bits 0-11: Analog watchdog 3lower threshold These bits are written by software to define the lower threshold for the analog watchdog. Refer to ADC_AWDxTR) on page395..

Allowed values: 0x0-0xfff

HT3

Bits 16-27: Analog watchdog 3 higher threshold These bits are written by software to define the higher threshold for the analog watchdog. Refer to ADC_AWDxTR) on page395..

Allowed values: 0x0-0xfff

DATA

Bits 0-15: Converted data These bits are read-only. They contain the conversion result from the last converted channel. The data are left- or right-aligned as shown in OVSE = 0) on page389. Just after a calibration is complete, DATA[6:0] contains the calibration factor..

Allowed values: 0x0-0xffff

AWD2CH0

Bit 0: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH1

Bit 1: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH2

Bit 2: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH3

Bit 3: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH4

Bit 4: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH5

Bit 5: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH6

Bit 6: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH7

Bit 7: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH8

Bit 8: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH9

Bit 9: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH10

Bit 10: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH11

Bit 11: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH12

Bit 12: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH13

Bit 13: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH14

Bit 14: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH15

Bit 15: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH16

Bit 16: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH17

Bit 17: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD2CH18

Bit 18: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 2 (AWD2). Note: The channels selected through ADC_AWD2CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD2
1: Monitored: ADC analog channel-x is monitored by AWD2

AWD3CH0

Bit 0: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH1

Bit 1: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH2

Bit 2: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH3

Bit 3: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH4

Bit 4: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH5

Bit 5: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH6

Bit 6: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH7

Bit 7: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH8

Bit 8: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH9

Bit 9: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH10

Bit 10: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH11

Bit 11: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH12

Bit 12: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH13

Bit 13: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH14

Bit 14: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH15

Bit 15: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH16

Bit 16: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH17

Bit 17: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

AWD3CH18

Bit 18: Analog watchdog channel selection These bits are set and cleared by software. They enable and select the input channels to be guarded by analog watchdog 3 (AWD3). Note: The channels selected through ADC_AWD3CR must be also configured into the ADC_CHSELR registers. Refer to SQ8[3:0] for a definition of channel selection. The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: NotMonitored: ADC analog channel-x is not monitored by AWD3
1: Monitored: ADC analog channel-x is monitored by AWD3

CALFACT

Bits 0-6: Calibration factor These bits are written by hardware or by software. Once a calibration is complete,they are updated by hardware with the calibration factors. Software can write these bits with a new calibration factor. If the new calibration factor is different from the current one stored into the analog ADC, it is then applied once a new calibration is launched. Just after a calibration is complete, DATA[6:0] contains the calibration factor. Note: Software can write these bits only when ADEN=1 (ADC is enabled and no calibration is ongoing and no conversion is ongoing). Refer to SQ8[3:0] for a definition of channel selection..

Allowed values: 0x0-0x7f

PRESC

Bits 18-21: ADC prescaler Set and cleared by software to select the frequency of the clock to the ADC. Other: Reserved Note: Software is allowed to write these bits only when the ADC is disabled (ADCAL=0, ADSTART=0, ADSTP=0, ADDIS=0 and ADEN=0)..

Allowed values:
0: Div1: Input ADC clock not divided
1: Div2: Input ADC clock divided by 2
2: Div4: Input ADC clock divided by 4
3: Div6: Input ADC clock divided by 6
4: Div8: Input ADC clock divided by 8
5: Div10: Input ADC clock divided by 10
6: Div12: Input ADC clock divided by 12
7: Div16: Input ADC clock divided by 16
8: Div32: Input ADC clock divided by 32
9: Div64: Input ADC clock divided by 64
10: Div128: Input ADC clock divided by 128
11: Div256: Input ADC clock divided by 256

VREFEN

Bit 22: VREFINT enable This bit is set and cleared by software to enable/disable the VREFINT. Note: Software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: VREFINT disabled
1: Enabled: VREFINT enabled

TSEN

Bit 23: Temperature sensor enable This bit is set and cleared by software to enable/disable the temperature sensor. Note: Software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing)..

Allowed values:
0: Disabled: Temperature sensor disabled
1: Enabled: Temperature sensor enabled

VBATEN

Bit 24: VBAT enable This bit is set and cleared by software to enable/disable the VBAT channel. Note: The software is allowed to write this bit only when ADSTART=0 (which ensures that no conversion is ongoing).

Allowed values:
0: Disabled: VBAT channel disabled
1: Enabled: VBAT channel enabled

EN

Bit 0: AES enable This bit enables/disables the AES peripheral: At any moment, clearing then setting the bit re-initializes the AES peripheral. This bit is automatically cleared by hardware upon the completion of the key preparation (Mode 2) and upon the completion of GCM/GMAC/CCM initial phase..

DATATYPE

Bits 1-2: Data type selection This bitfield defines the format of data written in the AES_DINR register or read from the AES_DOUTR register, through selecting the mode of data swapping: For more details, refer to . Attempts to write the bitfield are ignored when the EN bit of the AES_CR register is set before the write access and it is not cleared by that write access..

MODE

Bits 3-4: AES operating mode This bitfield selects the AES operating mode: Attempts to write the bitfield are ignored when the EN bit of the AES_CR register is set before the write access and it is not cleared by that write access. Any attempt to selecting Mode 4 while either ECB or CBC chaining mode is not selected, defaults to effective selection of Mode 3. It is not possible to select a Mode 3 following a Mode 4..

CHMOD1

Bits 5-6: Chaining mode selection, bit [2] Refer to the bits [5:6] of the register for the description of the CHMOD[2:0] bitfield CHMOD[1:0]: Chaining mode selection, bits [1:0] This bitfield, together with the bit CHMOD[2] forming CHMOD[2:0], selects the AES chaining mode: others: Reserved Attempts to write the bitfield are ignored when the EN bit of the AES_CR register is set before the write access and it is not cleared by that write access..

CCFC

Bit 7: Computation complete flag clear Upon written to 1, this bit clears the computation complete flag (CCF) in the AES_SR register: Reading the flag always returns zero..

ERRC

Bit 8: Error flag clear Upon written to 1, this bit clears the RDERR and WRERR error flags in the AES_SR register: Reading the flag always returns zero..

CCFIE

Bit 9: CCF interrupt enable This bit enables or disables (masks) the AES interrupt generation when CCF (computation complete flag) is set:.

ERRIE

Bit 10: Error interrupt enable This bit enables or disables (masks) the AES interrupt generation when RDERR and/or WRERR is set:.

DMAINEN

Bit 11: DMA input enable This bit enables/disables data transferring with DMA, in the input phase: When the bit is set, DMA requests are automatically generated by AES during the input data phase. This feature is only effective when Mode 1 or Mode 3 is selected through the MODE[1:0] bitfield. It is not effective for Mode 2 (key derivation). Usage of DMA with Mode 4 (single decryption) is not recommended..

DMAOUTEN

Bit 12: DMA output enable This bit enables/disables data transferring with DMA, in the output phase: When the bit is set, DMA requests are automatically generated by AES during the output data phase. This feature is only effective when Mode 1 or Mode 3 is selected through the MODE[1:0] bitfield. It is not effective for Mode 2 (key derivation). Usage of DMA with Mode 4 (single decryption) is not recommended..

GCMPH

Bits 13-14: GCM or CCM phase selection This bitfield selects the phase of GCM, GMAC or CCM algorithm: The bitfield has no effect if other than GCM, GMAC or CCM algorithms are selected (through the ALGOMODE bitfield)..

CHMOD2

Bit 16: Chaining mode selection, bit [2] Refer to the bits [5:6] of the register for the description of the CHMOD[2:0] bitfield CHMOD[1:0]: Chaining mode selection, bits [1:0] This bitfield, together with the bit CHMOD[2] forming CHMOD[2:0], selects the AES chaining mode: others: Reserved Attempts to write the bitfield are ignored when the EN bit of the AES_CR register is set before the write access and it is not cleared by that write access..

KEYSIZE

Bit 18: Key size selection This bitfield defines the length of the key used in the AES cryptographic core, in bits: Attempts to write the bit are ignored when the EN bit of the AES_CR register is set before the write access and it is not cleared by that write access..

NPBLB

Bits 20-23: Number of padding bytes in last block The bitfield sets the number of padding bytes in last block of payload: ....

CCF

Bit 0: Computation completed flag This flag indicates whether the computation is completed: The flag is set by hardware upon the completion of the computation. It is cleared by software, upon setting the CCFC bit of the AES_CR register. Upon the flag setting, an interrupt is generated if enabled through the CCFIE bit of the AES_CR register. The flag is significant only when the DMAOUTEN bit is 0. It may stay high when DMA_EN is 1..

RDERR

Bit 1: Read error flag This flag indicates the detection of an unexpected read operation from the AES_DOUTR register (during computation or data input phase): The flag is set by hardware. It is cleared by software upon setting the ERRC bit of the AES_CR register. Upon the flag setting, an interrupt is generated if enabled through the ERRIE bit of the AES_CR register. The flag setting has no impact on the AES operation. Unexpected read returns zero..

WRERR

Bit 2: Write error This flag indicates the detection of an unexpected write operation to the AES_DINR register (during computation or data output phase): The flag is set by hardware. It is cleared by software upon setting the ERRC bit of the AES_CR register. Upon the flag setting, an interrupt is generated if enabled through the ERRIE bit of the AES_CR register. The flag setting has no impact on the AES operation. Unexpected write is ignored..

BUSY

Bit 3: Busy This flag indicates whether AES is idle or busy during GCM payload encryption phase.

DIN

Bits 0-31: Input data word A four-fold sequential write to this bitfield during the input phase results in writing a complete 128-bit block of input data to the AES peripheral. From the first to the fourth write, the corresponding data weights are [127:96], [95:64], [63:32], and [31:0]. Upon each write, the data from the 32-bit input buffer are handled by the data swap block according to the DATATYPE[1:0] bitfield, then written into the AES core 128-bit input buffer. The data signification of the input data block depends on the AES operating mode: - Mode 1 (encryption): plaintext - Mode 2 (key derivation): the bitfield is not used (AES_KEYRx registers used for input) - Mode 3 (decryption) and Mode 4 (key derivation then single decryption): ciphertext The data swap operation is described in page499..

DOUT

Bits 0-31: Output data word This read-only bitfield fetches a 32-bit output buffer. A four-fold sequential read of this bitfield, upon the computation completion (CCF set), virtually reads a complete 128-bit block of output data from the AES peripheral. Before reaching the output buffer, the data produced by the AES core are handled by the data swap block according to the DATATYPE[1:0] bitfield. Data weights from the first to the fourth read operation are: [127:96], [95:64], [63:32], and [31:0]. The data signification of the output data block depends on the AES operating mode: - Mode 1 (encryption): ciphertext - Mode 2 (key derivation): the bitfield is not used (AES_KEYRx registers used for output) - Mode 3 (decryption) and Mode 4 (key derivation then single decryption): plaintext The data swap operation is described in page499..

KEY

Bits 0-31: Cryptographic key, bits [31:0] This bitfield contains the bits [31:0] of the AES encryption or decryption key, depending on the operating mode: - In Mode 1 (encryption), Mode 2 (key derivation) and Mode 4 (key derivation then single decryption): the value to write into the bitfield is the encryption key. - In Mode 3 (decryption): the value to write into the bitfield is the encryption key to be derived before being used for decryption. After writing the encryption key into the bitfield, its reading before enabling AES returns the same value. Its reading after enabling AES and after the CCF flag is set returns the decryption key derived from the encryption key. Note: In mode 4 (key derivation then single decryption) the bitfield always contains the encryption key. The AES_KEYRx registers may be written only when KEYSIZE value is correct and when the AES peripheral is disabled (EN bit of the AES_CR register cleared). Note that, if, the key is directly loaded to AES_KEYRx registers (hence writes to key register is ignored and KEIF is set). Refer to for more details..

KEY

Bits 0-31: Cryptographic key, bits [63:32] Refer to the AES_KEYR0 register for description of the KEY[255:0] bitfield..

KEY

Bits 0-31: Cryptographic key, bits [95:64] Refer to the AES_KEYR0 register for description of the KEY[255:0] bitfield..

KEY

Bits 0-31: Cryptographic key, bits [127:96] Refer to the AES_KEYR0 register for description of the KEY[255:0] bitfield..

IVI

Bits 0-31: Initialization vector input, bits [31:0] Refer to for description of the IVI[127:0] bitfield. The initialization vector is only used in chaining modes other than ECB. The AES_IVRx registers may be written only when the AES peripheral is disabled.

IVI

Bits 0-31: Initialization vector input, bits [63:32] Refer to the AES_IVR0 register for description of the IVI[128:0] bitfield..

IVI

Bits 0-31: Initialization vector input, bits [95:64] Refer to the AES_IVR0 register for description of the IVI[128:0] bitfield..

IVI

Bits 0-31: Initialization vector input, bits [127:96] Refer to the AES_IVR0 register for description of the IVI[128:0] bitfield..

KEY

Bits 0-31: Cryptographic key, bits [159:128] Refer to the AES_KEYR0 register for description of the KEY[255:0] bitfield..

KEY

Bits 0-31: Cryptographic key, bits [191:160] Refer to the AES_KEYR0 register for description of the KEY[255:0] bitfield..

KEY

Bits 0-31: Cryptographic key, bits [223:192] Refer to the AES_KEYR0 register for description of the KEY[255:0] bitfield..

KEY

Bits 0-31: Cryptographic key, bits [255:224] Refer to the AES_KEYR0 register for description of the KEY[255:0] bitfield..

SUSP

Bits 0-31: AES suspend Upon suspend operation, this bitfield of every AES_SUSPxR register takes the value of one of internal AES registers..

SUSP

Bits 0-31: AES suspend Upon suspend operation, this bitfield of every AES_SUSPxR register takes the value of one of internal AES registers..

SUSP

Bits 0-31: AES suspend Upon suspend operation, this bitfield of every AES_SUSPxR register takes the value of one of internal AES registers..

SUSP

Bits 0-31: AES suspend Upon suspend operation, this bitfield of every AES_SUSPxR register takes the value of one of internal AES registers..

SUSP

Bits 0-31: AES suspend Upon suspend operation, this bitfield of every AES_SUSPxR register takes the value of one of internal AES registers..

SUSP

Bits 0-31: AES suspend Upon suspend operation, this bitfield of every AES_SUSPxR register takes the value of one of internal AES registers..

SUSP

Bits 0-31: AES suspend Upon suspend operation, this bitfield of every AES_SUSPxR register takes the value of one of internal AES registers..

SUSP

Bits 0-31: AES suspend Upon suspend operation, this bitfield of every AES_SUSPxR register takes the value of one of internal AES registers..

DR

Bits 0-31: Data register bits.

IDR

Bits 0-31: General-purpose 32-bit data register bits.

RESET

Bit 0: RESET bit.

POLYSIZE

Bits 3-4: Polynomial size These bits control the size of the polynomial..

REV_IN

Bits 5-6: Reverse input data These bits control the reversal of the bit order of the input data.

REV_OUT

Bit 7: Reverse output data This bit controls the reversal of the bit order of the output data..

CRC_INIT

Bits 0-31: Programmable initial CRC value.

POL

Bits 0-31: Programmable polynomial.

EN1

Bit 0: DAC channel1 enable This bit is set and cleared by software to enable/disable DAC channel1..

TEN1

Bit 1: DAC channel1 trigger enable This bit is set and cleared by software to enable/disable DAC channel1 trigger. Note: When software trigger is selected, the transfer from the DAC_DHR1 register to the DAC_DOR1 register takes only one dac_pclk clock cycle..

TSEL1

Bits 2-5: DAC channel1 trigger selection These bits select the external event used to trigger DAC channel1 ... Refer to the trigger selection tables in for details on trigger configuration and mapping. Note: Only used if bit TEN1 = 1 (DAC channel1 trigger enabled)..

WAVE1

Bits 6-7: DAC channel1 noise/triangle wave generation enable These bits are set and cleared by software. 1x: Triangle wave generation enabled Only used if bit TEN1 = 1 (DAC channel1 trigger enabled)..

MAMP1

Bits 8-11: DAC channel1 mask/amplitude selector These bits are written by software to select mask in wave generation mode or amplitude in triangle generation mode. bigger or equal to 1011: Unmask bits[11:0] of LFSR/ triangle amplitude equal to 4095.

DMAEN1

Bit 12: DAC channel1 DMA enable This bit is set and cleared by software..

DMAUDRIE1

Bit 13: DAC channel1 DMA Underrun Interrupt enable This bit is set and cleared by software..

CEN1

Bit 14: DAC channel1 calibration enable This bit is set and cleared by software to enable/disable DAC channel1 calibration, it can be written only if bit EN1=0 into DAC_CR (the calibration mode can be entered/exit only when the DAC channel is disabled) Otherwise, the write operation is ignored..

EN2

Bit 16: DAC channel2 enable This bit is set and cleared by software to enable/disable DAC channel2. Note: These bits are available only on dual-channel DACs. Refer to implementation..

TEN2

Bit 17: DAC channel2 trigger enable This bit is set and cleared by software to enable/disable DAC channel2 trigger Note: When software trigger is selected, the transfer from the DAC_DHR2 register to the DAC_DOR2 register takes only one dac_pclk clock cycle. These bits are available only on dual-channel DACs. Refer to implementation..

TSEL2

Bits 18-21: DAC channel2 trigger selection These bits select the external event used to trigger DAC channel2 ... Refer to the trigger selection tables in for details on trigger configuration and mapping. Note: Only used if bit TEN2 = 1 (DAC channel2 trigger enabled). These bits are available only on dual-channel DACs. Refer to implementation..

WAVE2

Bits 22-23: DAC channel2 noise/triangle wave generation enable These bits are set/reset by software. 1x: Triangle wave generation enabled Note: Only used if bit TEN2 = 1 (DAC channel2 trigger enabled) These bits are available only on dual-channel DACs. Refer to implementation..

MAMP2

Bits 24-27: DAC channel2 mask/amplitude selector These bits are written by software to select mask in wave generation mode or amplitude in triangle generation mode. bigger or equal to 1011: Unmask bits[11:0] of LFSR/ triangle amplitude equal to 4095 Note: These bits are available only on dual-channel DACs. Refer to implementation..

DMAEN2

Bit 28: DAC channel2 DMA enable This bit is set and cleared by software. Note: This bit is available only on dual-channel DACs. Refer to implementation..

DMAUDRIE2

Bit 29: DAC channel2 DMA underrun interrupt enable This bit is set and cleared by software. Note: This bit is available only on dual-channel DACs. Refer to implementation..

CEN2

Bit 30: DAC channel2 calibration enable This bit is set and cleared by software to enable/disable DAC channel2 calibration, it can be written only if EN2 bit is set to 0 into DAC_CR (the calibration mode can be entered/exit only when the DAC channel is disabled) Otherwise, the write operation is ignored. Note: This bit is available only on dual-channel DACs. Refer to implementation..

SWTRIG1

Bit 0: DAC channel1 software trigger This bit is set by software to trigger the DAC in software trigger mode. Note: This bit is cleared by hardware (one dac_pclk clock cycle later) once the DAC_DHR1 register value has been loaded into the DAC_DOR1 register..

SWTRIG2

Bit 1: DAC channel2 software trigger This bit is set by software to trigger the DAC in software trigger mode. Note: This bit is cleared by hardware (one dac_pclk clock cycle later) once the DAC_DHR2 register value has been loaded into the DAC_DOR2 register. This bit is available only on dual-channel DACs. Refer to implementation..

DACC1DHR

Bits 0-11: DAC channel1 12-bit right-aligned data These bits are written by software. They specify 12-bit data for DAC channel1..

DACC1DHR

Bits 4-15: DAC channel1 12-bit left-aligned data These bits are written by software. They specify 12-bit data for DAC channel1..

DACC1DHR

Bits 0-7: DAC channel1 8-bit right-aligned data These bits are written by software. They specify 8-bit data for DAC channel1..

DACC2DHR

Bits 0-11: DAC channel2 12-bit right-aligned data These bits are written by software. They specify 12-bit data for DAC channel2..

DACC2DHR

Bits 4-15: DAC channel2 12-bit left-aligned data These bits are written by software which specify 12-bit data for DAC channel2..

DACC2DHR

Bits 0-7: DAC channel2 8-bit right-aligned data These bits are written by software which specifies 8-bit data for DAC channel2..

DACC1DHR

Bits 0-11: DAC channel1 12-bit right-aligned data These bits are written by software which specifies 12-bit data for DAC channel1..

DACC2DHR

Bits 16-27: DAC channel2 12-bit right-aligned data These bits are written by software which specifies 12-bit data for DAC channel2..

DACC1DHR

Bits 4-15: DAC channel1 12-bit left-aligned data These bits are written by software which specifies 12-bit data for DAC channel1..

DACC2DHR

Bits 20-31: DAC channel2 12-bit left-aligned data These bits are written by software which specifies 12-bit data for DAC channel2..

DACC1DHR

Bits 0-7: DAC channel1 8-bit right-aligned data These bits are written by software which specifies 8-bit data for DAC channel1..

DACC2DHR

Bits 8-15: DAC channel2 8-bit right-aligned data These bits are written by software which specifies 8-bit data for DAC channel2..

DACC1DOR

Bits 0-11: DAC channel1 data output These bits are read-only, they contain data output for DAC channel1..

DACC2DOR

Bits 0-11: DAC channel2 data output These bits are read-only, they contain data output for DAC channel2..

DMAUDR1

Bit 13: DAC channel1 DMA underrun flag This bit is set by hardware and cleared by software (by writing it to 1)..

CAL_FLAG1

Bit 14: DAC channel1 calibration offset status This bit is set and cleared by hardware.

BWST1

Bit 15: DAC channel1 busy writing sample time flag This bit is systematically set just after Sample and hold mode enable and is set each time the software writes the register DAC_SHSR1, It is cleared by hardware when the write operation of DAC_SHSR1 is complete. (It takes about 3 LSI periods of synchronization)..

DMAUDR2

Bit 29: DAC channel2 DMA underrun flag This bit is set by hardware and cleared by software (by writing it to 1). Note: This bit is available only on dual-channel DACs. Refer to implementation..

CAL_FLAG2

Bit 30: DAC channel2 calibration offset status This bit is set and cleared by hardware Note: This bit is available only on dual-channel DACs. Refer to implementation..

BWST2

Bit 31: DAC channel2 busy writing sample time flag This bit is systematically set just after Sample and hold mode enable. It is set each time the software writes the register DAC_SHSR2, It is cleared by hardware when the write operation of DAC_SHSR2 is complete. (It takes about 3 LSI periods of synchronization). Note: This bit is available only on dual-channel DACs. Refer to implementation..

OTRIM1

Bits 0-4: DAC channel1 offset trimming value.

OTRIM2

Bits 16-20: DAC channel2 offset trimming value These bits are available only on dual-channel DACs. Refer to implementation..

MODE1

Bits 0-2: DAC channel1 mode These bits can be written only when the DAC is disabled and not in the calibration mode (when bit EN1=0 and bit CEN1 =0 in the DAC_CR register). If EN1=1 or CEN1 =1 the write operation is ignored. They can be set and cleared by software to select the DAC channel1 mode: DAC channel1 in Normal mode DAC channel1 in sample & hold mode Note: This register can be modified only when EN1=0..

MODE2

Bits 16-18: DAC channel2 mode These bits can be written only when the DAC is disabled and not in the calibration mode (when bit EN2=0 and bit CEN2 =0 in the DAC_CR register). If EN2=1 or CEN2 =1 the write operation is ignored. They can be set and cleared by software to select the DAC channel2 mode: DAC channel2 in Normal mode DAC channel2 in Sample and hold mode Note: This register can be modified only when EN2=0. Refer to for the availability of DAC channel2..

TSAMPLE1

Bits 0-9: DAC channel1 sample time (only valid in Sample and hold mode) These bits can be written when the DAC channel1 is disabled or also during normal operation. in the latter case, the write can be done only when BWST1 of DAC_SR register is low, If BWST1=1, the write operation is ignored..

TSAMPLE2

Bits 0-9: DAC channel2 sample time (only valid in Sample and hold mode) These bits can be written when the DAC channel2 is disabled or also during normal operation. in the latter case, the write can be done only when BWST2 of DAC_SR register is low, if BWST2=1, the write operation is ignored..

THOLD1

Bits 0-9: DAC channel1 hold time (only valid in Sample and hold mode) Hold time= (THOLD[9:0]) x LSI clock period Note: This register can be modified only when EN1=0..

THOLD2

Bits 16-25: DAC channel2 hold time (only valid in Sample and hold mode). Hold time= (THOLD[9:0]) x LSI clock period Note: This register can be modified only when EN2=0. These bits are available only on dual-channel DACs. Refer to implementation..

TREFRESH1

Bits 0-7: DAC channel1 refresh time (only valid in Sample and hold mode) Refresh time= (TREFRESH[7:0]) x LSI clock period Note: This register can be modified only when EN1=0..

TREFRESH2

Bits 16-23: DAC channel2 refresh time (only valid in Sample and hold mode) Refresh time= (TREFRESH[7:0]) x LSI clock period Note: This register can be modified only when EN2=0. These bits are available only on dual-channel DACs. Refer to implementation..