C8051F987-GMR Silicon Labs, C8051F987-GMR Datasheet - Page 204

C8051F987-GMR

Manufacturer Part Number

C8051F987-GMR

Description

8-bit Microcontrollers - MCU 8kB 512B RAM

Manufacturer

Silicon Labs

Datasheet

1.C8051F986-GUR.pdf (322 pages)

Specifications of C8051F987-GMR

Rohs

yes

Core

8051

Processor Series

C8051

Data Bus Width

8 bit

Current page: 204 of 322
Download datasheet (2Mb)

C8051F99x-C8051F98x

20.2.5. Automatic Gain Control (Crystal Mode Only) and SmaRTClock Bias Doubling

Automatic Gain Control allows the SmaRTClock oscillator to trim the oscillation amplitude of a crystal in

order to achieve the lowest possible power consumption. Automatic Gain Control automatically detects

when the oscillation amplitude has reached a point where it safe to reduce the drive current, therefore, it

may be enabled during crystal startup. It is recommended to enable Automatic Gain Control in most sys-

tems which use the SmaRTClock oscillator in Crystal Mode. The following are recommended crystal spec-

ifications and operating conditions when Automatic Gain Control is enabled:



When using Automatic Gain Control, it is recommended to perform an oscillation robustness test to ensure

that the chosen crystal will oscillate under the worst case condition to which the system will be exposed.

The worst case condition that should result in the least robust oscillation is at the following system condi-

tions: lowest temperature, highest supply voltage, highest ESR, highest load capacitance, and lowest bias

current (AGC enabled, Bias Double Disabled).

To perform the oscillation robustness test, the SmaRTClock oscillator should be enabled and selected as

the system clock source. Next, the SYSCLK signal should be routed to a port pin configured as a push-pull

digital output. The positive duty cycle of the output clock can be used as an indicator of oscillation robust-

ness. As shown in Figure 20.2, duty cycles less than 55% indicate a robust oscillation. As the duty cycle

approaches 60%, oscillation becomes less reliable and the risk of clock failure increases. Increasing the

bias current (by disabling AGC) will always improve oscillation robustness and will reduce the output

clock’s duty cycle. This test should be performed at the worst case system conditions, as results at very

low temperatures or high supply voltage will vary from results taken at room temperature or low supply

voltage.

As an alternative to performing the oscillation robustness test, Automatic Gain Control may be disabled at

the cost of increased power consumption (approximately 200 nA). Disabling Automatic Gain Control will

provide the crystal oscillator with higher immunity against external factors which may lead to clock failure.

Automatic Gain Control must be disabled if using the SmaRTClock oscillator in self-oscillate mode.

Table 20.3 shows a summary of the oscillator bias settings. The SmaRTClock Bias Doubling feature allows

the self-oscillation frequency to be increased (almost doubled) and allows a higher crystal drive strength in

crystal mode. High crystal drive strength is recommended when the crystal is exposed to poor environmen-

tal conditions such as excessive moisture. SmaRTClock Bias Doubling is enabled by setting BIASX2

(RTC0XCN.5) to 1.

204

ESR < 50 k

Load Capacitance < 10 pF

Supply Voltage < 3.0 V

Temperature > –20 °C

Figure 20.2. Interpreting Oscillation Robustness (Duty Cycle) Test Results

25%

Safe Operating Zone

55%

Low Risk of Clock

Rev. 1.1

Failure

60%

High Risk of Clock

Failure

Duty Cycle

C8051F987-GMR Silicon Labs, C8051F987-GMR Datasheet - Page 204

C8051F987-GMR

Specifications of C8051F987-GMR

Related parts for C8051F987-GMR