ISL12008 Datasheet, PDF(16/19 Page) Intersil Corporation – I2C Real Time Clock with Battery Backup

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ISL12008 Datasheet, PDF (16/19 Pages) Intersil Corporation – I2C Real Time Clock with Battery Backup

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ISL12008

Application Section

Oscillator Crystal Requirements

The ISL12008 uses a standard 32.768kHz crystal. Either

through hole or surface mount crystals can be used. Table 7

lists some recommended surface mount crystals and the

parameters of each. This list is not exhaustive and other

surface mount devices can be used with the ISL12008 if

their specifications are very similar to the devices listed.

The crystal should have a required parallel load capacitance

of 12.5pF and an equivalent series resistance of less than

50k. The crystalâs temperature range specification should

match the application. Many crystals are rated for -10Â°C to

+60Â°C (especially through-hole and tuning fork types), so an

appropriate crystal should be selected if extended

temperature range is required.

TABLE 7. SUGGESTED SURFACE MOUNT CRYSTALS

MANUFACTURER

PART NUMBER

Citizen

CM200S

Epson

MC-405, MC-406

Raltron

RSM-200S

SaRonix

32S12

Ecliptek

ECPSM29T-32.768K

ECS

ECX-306

Fox

FSM-327

Crystal Oscillator Frequency Adjustment

The ISL12008 device contains circuitry for adjusting the

frequency of the crystal oscillator. This circuitry can be used

to trim oscillator initial accuracy as well as adjust the

frequency to compensate for temperature changes.

The Analog Trimming Register (ATR) is used to adjust the

load capacitance seen by the crystal. There are 6 bits of ATR

control, with linear capacitance increments available for

adjustment. Since the ATR adjustment is essentially âpullingâ

the frequency of the oscillator, the resulting frequency

changes will not be linear with incremental capacitance

changes. The equations (which govern pulling) show that

lower capacitor values of ATR adjustment will provide larger

increments. Also, the higher values of ATR adjustment will

produce smaller incremental frequency changes. The range

afforded by the ATR adjustment with a typical surface mount

crystal is typically -34ppm to +80ppm around the ATR = 0

default setting because of this property. The user should note

this when using the ATR for calibration. The temperature drift

of the capacitance used in the ATR control is extremely low,

so this feature can be used for temperature compensation

with good accuracy.

In addition to the analog compensation afforded by the

adjustable load capacitance, a digital compensation feature

is available for the ISL12008. There are 6 bits known as the

Digital Trimming Register (DTR). The range provided is

-63.0695ppm to +126.139ppm. DTR operates by adding or

skipping pulses in the clock counter. It is very useful for

coarse adjustments of frequency drift over temperature or

extending the adjustment range available with the ATR

Initial accuracy is best adjusted by enabling the 512Hz

frequency output (using the FT bit, address 08h bit 6), and

monitoring the FT/OUT pin with a calibrated frequency

counter. The gating time should be set long enough to

ensure accuracy to at least 1ppm. To calculate the ppm on

the measured 512Hz, simply divide the measured 512Hz by

512, then subtract 1 from the result and mulitple by

1,000,000. Please see Equation 3 for the formula:

ppm = (FT/512 - 1)*1E6

(EQ. 3)

The ATR should be set to the center position, or 00000b, to

begin with. Once the initial measurement is made, then the

ATR register can be changed to adjust the frequency. Note

for a range of 0 to 31 for the ATR register will increased

capacitance and lower the frequency with 31 for the

maximum negative correction, and for a range of 32 to 63 for

the ATR register will decreased capacitance and increase

the frequency with 32 for the maximum positive correction. If

the initial measurement shows the frequency is far off, it will

be necessary to use the DTR register to do a coarse

adjustment. Note that most all crystals will have tight enough

initial accuracy at room temperature so that a small ATR

Temperature Compensation

The ATR and DTR controls can be combined to provide

crystal drift temperature compensation. The typical

32.768kHz crystal has a drift characteristic that is similar to

that shown in Figure 15. There is a turnover temperature

(T0) where the drift is very near zero. The shape is parabolic

as it varies with the square of the difference between the

actual temperature and the turnover temperature.

-20

-40

-60

-80

-100

-120

-140

-160

-40 -30 -20 -10 0 10 20 30 40 50 60 70 80

TEMPERATURE (Â°C)

FIGURE 15. RTC CRYSTAL TEMPERATURE DRIFT

FN6690.1

September 26, 2008

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