ISL12082 Datasheet, PDF(23/26 Page) Intersil Corporation – I2C-Bus™ Real Time Clock with Two Interrupts, Alarm, and Timer

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ISL12082 Datasheet, PDF (23/26 Pages) Intersil Corporation – I2C-Bus™ Real Time Clock with Two Interrupts, Alarm, and Timer

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ISL12082

the function will just be a matter of implementing software

and performing some calculations. Fairly accurate

temperature compensation can be implemented just by

using the crystal manufacturerâs specifications for the

turnover-temperature T0 and the drift coefficient (Î²). The

formula for calculating the oscillator adjustment necessary is

shown in Equation 9:

Adjustment(ppm) = (T â T0)2 âÎ²

(EQ. 9)

Once the temperature curve for a crystal is established, then

the designer should decide at what discrete temperatures

the compensation will change. Since drift is higher at

extreme temperatures, the compensation may not be

needed until the temperature is greater than +20Â°C from T0.

A sample curve of the ATR setting vs Frequency Adjustment

for the ISL12082 and a typical RTC crystal is given in

Figure 18. This curve may vary with different crystals, so it is

good practice to evaluate a given crystal in an ISL12082

circuit before establishing the adjustment values.

-10

-20

-30

-400

5 10 15 20 25 30 35 40 45 50 55 60

ATR SETTING

FIGURE 18. ATR SETTING vs OSCILLATOR FREQUENCY

ADJUSTMENT

This curve is then used to figure what ATR and DTR settings

are used for compensation. The results would be placed in a

lookup table for the microcontroller to access.

Layout Considerations

The crystal input at X1 has a very high impedance, and

oscillator circuits operating at low frequencies such as

32.768kHz are known to pick up noise very easily if layout

precautions are not followed. Most instances of erratic

clocking or large accuracy errors can be traced to the

susceptibility of the oscillator circuit to interference from

adjacent high speed clock or data lines. Careful layout of the

RTC circuit will avoid noise pickup and insure accurate

clocking.

Figure 19 shows a suggested layout for the ISL12082 device

using a surface mount crystal. Two main precautions should

be followed:

1. Do not run the serial bus lines or any high speed logic

lines in the vicinity of the crystal. These logic level lines

can induce noise in the oscillator circuit to cause

misclocking.

2. Add a ground trace around the crystal with one end

terminated at the chip ground. This will provide

termination for emitted noise in the vicinity of the RTC

device.

FIGURE 19. SUGGESTED LAYOUT FOR ISL12082 AND

CRYSTAL

In addition, it is a good idea to avoid a ground plane under

the X1 and X2 pins and the crystal, as this will affect the load

capacitance and therefore the oscillator accuracy of the

circuit. If the IRQ1/fOUT pin is used as a clock, it should be

routed away from the RTC device as well. The traces for the

VBAT and VCC pins can be treated as a ground, and should

be routed around the crystal.

Supercapacitor Backup

The ISL12082 device provides a VBAT pin which is used for

a battery backup input. A Supercapacitor can be used as an

alternative to a battery in cases where shorter backup times

are required. Since the battery backup supply current

required by the ISL12082 is extremely low, it is possible to

get months of backup operation using a Supercapacitor.

Typical capacitor values are a few ÂµF to 1F or more

depending on the application.

If backup is only needed for a few minutes, then a small

inexpensive electrolytic capacitor can be used. For extended

periods, a low leakage, high capacity Supercapacitor is the

best choice. These devices are available from such vendors

as Panasonic and Murata. The main specifications include

working voltage and leakage current. If the application is for

charging the capacitor from a +5V Â±5% supply with a signal

diode, then the voltage on the capacitor can vary from ~4.5V

to slightly over 5.0V. A capacitor with a rated WV of 5.0V

may have a reduced lifetime if the supply voltage is slightly

high. The leakage current should be as small as possible.

For example, a Supercapacitor should be specified with

leakage of well below 1ÂµA. A standard electrolytic capacitor

with DC leakage current in the microamps will have a

severely shortened backup time.

Following are some examples with equations to assist with

calculating backup times and required capacitance for the

ISL12082 device. The backup supply current plays a major

part in these equations, and a typical value was chosen for

example purposes. For a robust design, a margin of 30%

should be included to cover supply current and capacitance

tolerances over the results of the calculations. Even more

FN6731.3

November 24, 2008

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