X1227 Datasheet, PDF(22/28 Page) Xicor Inc. – Real Time Clock/Calendar/CPU Supervisor with EEPROM

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X1227 Datasheet, PDF (22/28 Pages) Xicor Inc. – Real Time Clock/Calendar/CPU Supervisor with EEPROM

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X1227

A ï¬nal application for the ATR control is in-circuit cali-

bration for high accuracy applications, along with a

temperature sensor chip. Once the RTC circuit is pow-

ered up with battery backup, the frequency drift is mea-

sured. The ATR control is then adjusted to a setting

which minimizes drift. Once adjusted at a particular

temperature, it is possible to adjust at other discrete

temperatures for minimal overall drift, and store the

resulting settings in the EEPROM. Extremely low over-

all temperature drift is possible with this method. The

Xicor evaluation board contains the circuitry necessary

to implement this control.

For more detailed operation see Xicorâs application

note AN154 on Xicorâs website at www.xicor.com.

Layout Considerations

The crystal input at X1 has a very high impedance and

will pick up high frequency signals from other circuits

on the board. Since the X2 pin is tied to the other side

of the crystal, it is also a sensitive node. These signals

can couple into the oscillator circuit and produce dou-

ble clocking or mis-clocking, seriously affecting the

accuracy of the RTC. Care needs to be taken in layout

of the RTC circuit to avoid noise pickup. Below in Fig-

ure 15 is a suggested layout for the X1226 or X1227

devices.

Figure 15. Suggested Layout for Xicor RTC in SO-8

The X1 and X2 connections to the crystal are to be

kept as short as possible. A thick ground trace around

the crystal is advised to minimize noise intrusion, but

ground near the X1 and X2 pins should be avoided as

it will add to the load capacitance at those pins. Keep in

mind these guidelines for other PCB layers in the vicin-

ity of the RTC device. A small decoupling capacitor at

the Vcc pin of the chip is mandatory, with a solid con-

nection to ground.

For other RTC products, the same rules stated above

should be observed, but adjusted slightly since the

packages and pinouts are slightly different.

Assembly

Most electronic circuits do not have to deal with

assembly issues, but with the RTC devices assembly

includes insertion or soldering of a live battery into an

unpowered circuit. If a socket is soldered to the board,

and a battery is inserted in ï¬nal assembly, then there

are no issues with operation of the RTC. If the battery

is soldered to the board directly, then the RTC device

Vback pin will see some transient upset from either sol-

dering tools or intermittent battery connections which

can stop the circuit from oscillating. Once the battery is

soldered to the board, the only way to assure the circuit

will start up is to momentarily (very short period of

time!) short the Vback pin to ground and the circuit will

begin to oscillate.

Oscillator Measurements

When a proper crystal is selected and the layout guide-

lines above are observed, the oscillator should start up

in most circuits in less than one second. Some circuits

may take slightly longer, but startup should deï¬nitely

occur in less than 5 seconds. When testing RTC cir-

cuits, the most common impulse is to apply a scope

probe to the circuit at the X2 pin (oscillator output) and

observe the waveform. DO NOT DO THIS! Although in

some cases you may see a useable waveform, due to

the parasitics (usually 10pF to ground) applied with the

scope probe, there will be no useful information in that

waveform other than the fact that the circuit is oscillat-

ing. The X2 output is sensitive to capacitive impedance

so the voltage levels and the frequency will be affected

REV 1.1.20 1/13/03

www.xicor.com

Characteristics subject to change without notice. 22 of 28

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