Atmel ARM-Based Evaluation Kit for SAM4S16C, 32-Bit ARM® Cortex® Microcontroller ATSAM4S-WPIR-RD ATSAM4S-WPIR-RD Ficha De Dados
Códigos do produto
ATSAM4S-WPIR-RD
SAM4S Series [DATASHEET]
Atmel-11100G-ATARM-SAM4S-Datasheet_27-May-14
512
If system fast start-up time is not required, the first instruction after a wait mode exit can be located in the
embedded Flash. Under these conditions, prior to entering wait mode, the Flash controller must be programmed to
perform access in 0 wait-state (see Flash controller section).
The procedure and conditions to enter wait mode and the circuitry to exit wait mode are strictly the same as fast
start-up (see
29.13 Main Clock Failure Detector
The clock failure detector monitors the main crystal oscillator or ceramic resonator-based oscillator to identify an
eventual failure of this oscillator.
The clock failure detector can be enabled or disabled by bit CFDEN in the PMC Clock Generator Main Oscillator
The clock failure detector can be enabled or disabled by bit CFDEN in the PMC Clock Generator Main Oscillator
Register (CKGR_MOR). After a VDDCORE reset, the detector is disabled. However, if the oscillator is disabled
(MOSCXTEN = 0), the detector is disabled too.
The clock failure detection must be enabled only when system clock MCK selects the fast RC oscillator. The status
The clock failure detection must be enabled only when system clock MCK selects the fast RC oscillator. The status
register (PMC_SR) must be read two slow clock cycles after enabling the clock failure detector. Then, MCK can
select another clock source by programming the CSS field in PMC_MCKR.
A failure is detected by means of a counter incrementing on the main oscillator clock edge and timing logic clocked
A failure is detected by means of a counter incrementing on the main oscillator clock edge and timing logic clocked
on the slow RC oscillator controlling the counter. Thus, the slow RC oscillator must be enabled.
The counter is cleared when the slow RC oscillator clock signal is low and enabled when the signal is high. Thus
The counter is cleared when the slow RC oscillator clock signal is low and enabled when the signal is high. Thus
the failure detection time is 1 slow RC oscillator clock period. If, during the high level period of the slow RC
oscillator clock signal, less than 8 fast crystal oscillator clock periods have been counted, then a failure is reported.
If a failure of the main oscillator is detected, bit CFDEV in the PMC Status Register (PMC_SR) indicates a failure
If a failure of the main oscillator is detected, bit CFDEV in the PMC Status Register (PMC_SR) indicates a failure
event and generates an interrupt if the corresponding interrupt source is enabled. The interrupt remains active until
a read occurs in the PMC_SR. The user can know the status of the clock failure detection at any time by reading
the CFDS bit in the PMC_SR.
Figure 29-5.
Clock Failure Detection (Example)
If the main oscillator is selected as the source clock of MAINCK (MOSCSEL in CKGR_MOR = 1), and if the master
clock source is PLLACKor PLLBCK (CSS = 2 or 3), a clock failure detection automatically forces MAINCK to be
the source clock for the master clock (MCK).Then, regardless of the PMC configuration, a clock failure detection
automatically forces the fast RC oscillator to be the source clock for MAINCK. If the fast RC oscillator is disabled
when a clock failure detection occurs, it is automatically re-enabled by the clock failure detection mechanism.
It takes 2 slow RC oscillator clock cycles to detect and switch from the main oscillator, to the fast RC oscillator if
It takes 2 slow RC oscillator clock cycles to detect and switch from the main oscillator, to the fast RC oscillator if
the source master clock (MCK) is main clock (MAINCK), or three slow clock RC oscillator cycles if the source of
MCK is PLLACKor PLLBCK.
Main Crytal Clock
SLCK
Note: ratio of clock periods is for illustration purposes only
CDFEV
CDFS
Read PMC_SR