ISL12022MIBZ-T Intersil, ISL12022MIBZ-T Datasheet - Page 19

ISL12022MIBZ-T

Manufacturer Part Number

ISL12022MIBZ-T

Description

IC RTC/CALENDAR TEMP SENS 20SOIC

Manufacturer

Intersil

Type

Clock/Calendarr

Datasheet

1.ISL12022MIBZ-T.pdf (31 pages)

Specifications of ISL12022MIBZ-T

Memory Size

128B

Time Format

HH:MM:SS (12/24 hr)

Date Format

YY-MM-DD-dd

Interface

I²C, 2-Wire Serial

Voltage - Supply

2.7 V ~ 5.5 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

20-SOIC (7.5mm Width)

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

ISL12022MIBZ-TCT

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

ISL12022MIBZ-T

Manufacturer:

INTERSIL

Quantity:

20 000

Company:

Meier Automation Equipment Co., Limited

Part Number:

ISL12022MIBZ-TR5421

Manufacturer:

INTERSIL

Quantity:

20 000

Current page: 19 of 31
Download datasheet (616Kb)

ALPHA Register (ALPHA)

The ALPHA variable is 8 bits and is defined as the

temperature coefficient of crystal from -40°C to T0, or

the ALPHA Cold (there is an Alpha Hot register that

must be programmed as well). It is normally given in

units of ppm/°C

ISL12022M device uses a scaled version of the absolute

value of this coefficient in order to get an integer value.

Therefore, ALPHA <7:0> is defined as the (|Actual

ALPHA Value| x 2048) and converted to binary. For

example, a crystal with Alpha of -0.034ppm/°C

scaled (|2048*(-0.034)| = 70d) and then converted to

a binary number of 01000110b.

The practical range of Actual ALPHA values is from

-0.020 to -0.060.

The ISL12022M has a preset ALPHA value

corresponding to the crystal in the module. This value

is recalled on initial power-up and is preset in

device production. It is READ ONLY and cannot

be overwritten by the user.

BETA Register (BETA)

The BETA register has special Write properties. Only the

TSE, BTSE and BTSR bits can be written; the BETA bits

are READ-ONLY. A write to both bytes in this register will

only change the 3 MSB’s (TSE, BTSE, BTSR), and the

5 LSB’s will remain the same as set at the factory.

TEMPERATURE SENSOR ENABLED BIT (TSE)

This bit enables the Temperature Sensing operation,

including the temperature sensor, A/D converter and

FATR/FDTR register adjustment. The default mode after

power-up is disabled: (TSE = 0). To enable the operation,

TSE should be set to 1. (TSE = 1). When temp sense is

disabled, the initial values for IATR and IDTR registers

are used for frequency control.

When TSE is set to 1, the temperature conversion cycle

begins and will end when two temperature conversions

are completed. The average of the two conversions is in

the TEMP registers.

TEMP SENSOR CONVERSION IN BATTERY MODE

BIT (BTSE)

This bit enables the Temperature Sensing and Correction

in battery mode. BTSE = 0 (default) no conversion, Temp

Sensing or Compensation in battery mode. BTSE = 1

indicates Temp Sensing and Compensation enabled in

ADDR

0Dh

ADD

0Ch

TSE BTSE BTSR BETA4 BETA3 BETA2 BETA1 BETA0

ALPHA6 ALPHA5 ALPHA4 ALPHA3 ALPHA2 ALPHA1 ALPHA0

TABLE 13. ALPHA REGISTER

, with a typical value of -0.034. The

TABLE 14.

is first

ISL12022M

battery mode. The BTSE is disabled when the battery

voltage is lower than 2.7V. No temperature

compensation will take place with VBAT<2.7V.

FREQUENCY OF TEMPERATURE SENSING AND

CORRECTION BIT (BTSR)

This bit controls the frequency of Temp Sensing and

Correction. BTSR = 0 default mode is every 10 minutes,

BTSR = 1 is every 1.0 minute. Note that BTSE has to be

enabled in both cases. See Table 15.

The temperature measurement conversion time is the

same for battery mode as for V

22ms. The battery mode current will increase during

this conversion time to typically 68µA. The average

increase in battery current is much lower than this due

to the small duty cycle of the ON-time versus OFF-time

for the conversion.

To figure the average increase in battery current, we take

the change in current times the duty cycle. For the

1 minute temperature period, the average current is

expressed in Equation 1:

For the 10 minute temperature period the average

current is expressed in Equation 2:

If the application has a stable temperature environment

that doesn’t change quickly, the 10 minute option will

work well and the backup battery lifetime impact is

minimized. If quick temperature variations are expected

(multiple cycles of more than 10° within an hour), then

the 1 minute option should be considered and the slightly

higher battery current figured into overall battery life.

GAIN FACTOR OF AT BIT (BETA<4:0>)

Beta is specified to take care of the Cm variations of the

crystal. Most crystals specify Cm around 2.2fF. For

example, if Cm > 2.2fF, the actual AT steps may reduce

from 1ppm/step to approximately 0.80ppm/step. Beta

is then used to adjust for this variation and restore the

step size to 1ppm/step.

BETA values are limited in the range from 01000 to

11111, as shown in Table 16

is tested at two AT settings as follows:

BETA VALUES = (AT(max) - AT (min))/63, where:

TABLE 15. FREQUENCY OF TEMPERATURE SENSING

ΔI

BAT

BTSE

0.022s

----------------- -

0.022s

----------------- -

600s

60s

AND CORRECTION BIT

68μA

250nA

25nA

BTSR

To use Table 16, the device

mode, approximately

BATTERY MODE

TC PERIOD IN

10 Minutes

1 Minute

OFF

June 4, 2010

FN6668.7

(EQ. 1)

(EQ. 2)

ISL12022MIBZ-T Intersil, ISL12022MIBZ-T Datasheet - Page 19

ISL12022MIBZ-T

Specifications of ISL12022MIBZ-T

Available stocks

Related parts for ISL12022MIBZ-T