ISL12026AIBZ-T [RENESAS]
Real Time Clock/Calendar with I<sup>2</sup>C Bus™ and EEPROM; SOIC8, TSSOP8; Temp Range: -40° to 85°C;型号: | ISL12026AIBZ-T |
厂家: | RENESAS TECHNOLOGY CORP |
描述: | Real Time Clock/Calendar with I<sup>2</sup>C Bus™ and EEPROM; SOIC8, TSSOP8; Temp Range: -40° to 85°C 可编程只读存储器 电动程控只读存储器 电可擦编程只读存储器 时钟 光电二极管 外围集成电路 |
文件: | 总24页 (文件大小:1178K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
DATASHEET
ISL12026, ISL12026A
Real Time Clock/Calendar with I2C Bus™ and EEPROM
FN8231
Rev 9.00
November 30, 2010
The ISL12026 and the ISL12026A devices are micro power
real time clocks with timing and crystal compensation,
clock/calender, power-fail indicator, two periodic or polled
alarms, intelligent battery backup switching, and integrated
512x8-bit EEPROM configured in 16 Bytes per page.
Features
• Real Time Clock/Calendar
- Tracks Time in Hours, Minutes and Seconds
- Day of the Week, Day, Month and Year
- 3 Selectable Frequency Outputs
The oscillator uses an external, low-cost 32.768kHz crystal.
The real time clock tracks time with separate registers for
hours, minutes, and seconds. The device has calendar
registers for date, month, year and day of the week. The
calendar is accurate through 2099, with automatic leap year
correction.
• Two Non-Volatile Alarms
- Settable on the Second, Minute, Hour, Day of the Week,
Day or Month
- Repeat Mode (Periodic Interrupts)
• Automatic Backup to Battery or SuperCap
• On-Chip Oscillator Compensation
The ISL12026 and ISL12026A have different types of Power
Control Settings. The ISL12026 uses the Legacy Mode
Setting, which follows conditions set in X1226 products. The
ISL12026A uses the Standard Mode Setting. Please refer to
“Power Control Operation” on page 13 for more details. Also,
please refer to “I2C Communications During Battery Backup”
on page 22 for important details.
- Internal Feedback Resistor and Compensation
Capacitors
- 64 Position Digitally Controlled Trim Capacitor
- 6 Digital Frequency Adjustment Settings to ±30ppm
• 512x8 Bits of EEPROM
- 16-Byte Page Write Mode (32 total pages)
- 8 Modes of BlockLock™ Protection
- Single Byte Write Capability
Pinouts
ISL12026, ISL12026A
(8 LD SOIC)
• High Reliability
TOP VIEW
- Data Retention: 50 years
- Endurance: >2,000,000 Cycles Per Byte
V
V
X1
X2
DD
1
2
8
7
6
5
BAT
• I2C Interface
SCL
SDA
IRQ/F
OUT
3
4
- 400kHz Data Transfer Rate
GND
• 800nA Battery Supply Current
• Package Options
ISL12026, ISL12026A
(8 LD TSSOP)
TOP VIEW
- 8 Ld SOIC and 8 Ld TSSOP Packages
• Pb-Free (RoHS Compliant)
V
BAT
SCL
1
2
8
7
6
5
Applications
V
SDA
DD
X1
X2
• Utility Meters
GND
IRQ/F
3
4
• HVAC Equipment
OUT
• Audio/Video Components
• Set-Top Box/Television
• Modems
• Network Routers, Hubs, Switches, Bridges
• Cellular Infrastructure Equipment
• Fixed Broadband Wireless Equipment
• Pagers/PDA
• POS Equipment
• Test Meters/Fixtures
• Office Automation (Copiers, Fax)
• Home Appliances
• Computer Products
• Other Industrial/Medical/Automotive
FN8231 Rev 9.00
November 30, 2010
Page 1 of 24
ISL12026, ISL12026A
Ordering Information
PART NUMBER
(Notes 1, 2, 3)
PART
MARKING
V
TRIP POINT BSW BIT DEFAULT TEMP RANGE
PACKAGE
(Pb-Free)
PKG.
DWG. #
BAT
(V)
< V
< V
2.2
2.2
SETTING
BSW = 1
BSW = 1
BSW = 0
BSW = 0
(°C)
ISL12026IBZ
ISL12026IVZ
ISL12026AIBZ
ISL12026AIVZ
NOTES:
12026 IBZ
2026 IVZ
V
V
-40 to +85
-40 to +85
-40 to +85
-40 to +85
8 Ld SOIC
M8.15
DD
BAT
BAT
8 Ld TSSOP
8 Ld SOIC
M8.173
M8.15
DD
12026A IBZ
2026A IVZ
8 Ld TSSOP
M8.173
1. Add “-T*” suffix for tape and reel. Please refer to TB347 for details on reel specifications.
2. These Intersil Pb-free plastic packaged products employ special Pb-free material sets, molding compounds/die attach materials, and 100% matte
tin plate plus anneal (e3 termination finish, which is RoHS compliant and compatible with both SnPb and Pb-free soldering operations). Intersil Pb-
free products are MSL classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J STD-020.
3. For Moisture Sensitivity Level (MSL), please see device information page for ISL12026, ISL12026A. For more information on MSL please see
techbrief TB363.
Block Diagram
OSC
COMPENSATION
X1
X2
TIMER
CALENDAR
LOGIC
BATTERY
SWITCH
CIRCUITRY
TIME
KEEPING
REGISTERS
(SRAM)
V
V
FREQUENCY
DIVIDER
DD
1Hz
OSCILLATOR
32.768kHz
BAT
IRQ/F
OUT
SELECT
STATUS
CONTROL/
REGISTERS
(EEPROM)
CONTROL
DECODE
LOGIC
COMPARE
SERIAL
INTERFACE
DECODER
REGISTERS
SCL
SDA
ALARM
(SRAM)
ALARM REGS
(EEPROM)
8
4k
EEPROM
ARRAY
Pin Descriptions
PIN NUMBER
SOIC
TSSOP
SYMBOL
DESCRIPTION
1
3
X1
The X1 pin is the input of an inverting amplifier and is intended to be connected to one pin of an external
32.768kHz quartz crystal. X1 can also be driven directly from a 32.768kHz source (see “Application Section”
on page 19.)
2
3
4
5
X2
The X2 pin is the output of an inverting amplifier and is intended to be connected to one pin of an external
32.768kHz quartz crystal (see “Application Section” on page 19.)
IRQ/F
Interrupt Output/Frequency Output is a multi-functional pin that can be used as interrupt or frequency
output pin. The function is set via the control register. This output is an open drain configuration.
OUT
4
5
6
7
GND
Ground.
SDA
Serial Data (SDA) is a bidirectional pin used to transfer serial data into and out of the device. It has an open
drain output and may be wire OR’ed with other open drain or open collector outputs.
6
7
8
8
1
2
SCL
The Serial Clock (SCL) input is used to clock all serial data into and out of the device. The input buffer on
this pin is always active (not gated).
V
This input provides a backup supply voltage to the device. V
supplies power to the device in the event
BAT
BAT
that the V
supply fails. This pin should be tied to ground if not used.
DD
V
Power Supply.
DD
FN8231 Rev 9.00
November 30, 2010
Page 2 of 24
ISL12026, ISL12026A
Absolute Maximum Ratings
Thermal Information
Voltage on V , V
, SCL, SDA, and IRQ/F
Pins
Thermal Resistance (Typical)
(°C/W)
(°C/W)
JC
DD BAT
JA
OUT
(respect to ground). . . . . . . . . . . . . . . . . . . . . . . . . . -0.3V to 6.0V
Voltage on X1 and X2 Pins
8 Ld SOIC Package (Notes 5, 6) . . . . .
8 Ld TSSOP Package (Notes 5, 6) . . .
115
140
50
48
(respect to ground). . . . . . . . . . . . . . . . . . . . . . . . . . -0.3V to 2.5V
Latchup (Note 4) . . . . . . . . . . . . . . . . . . . Class II, Level B @ +85°C
ESD Rating
Storage Temperature . . . . . . . . . . . . . . . . . . . . . . . .-65°C to +150°C
Pb-free reflow profile . . . . . . . . . . . . . . . . . . . . . . . . . .see link below
http://www.intersil.com/pbfree/Pb-FreeReflow.asp
Human Body Model . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .±2kV
Machine Model. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .175V
CAUTION: Do not operate at or near the maximum ratings listed for extended periods of time. Exposure to such conditions may adversely impact product reliability and
result in failures not covered by warranty.
NOTES:
4. Jedec Class II pulse conditions and failure criterion used. Level B exceptions are: Using a max positive pulse of 8.35V on all pins except X1 and
X2, Using a max positive pulse of 2.75V on X1 and X2, and using a max negative pulse of -1V for all pins.
5. is measured with the component mounted on a high effective thermal conductivity test board in free air. See Tech Brief TB379 for details.
JA
6. For , the “case temp” location is taken at the package top center.
JC
DC Electrical Specifications Unless otherwise noted, V = +2.7V to +5.5V, T = -40°C to +85°C, Typical values are @ T = +25°C
DD
A
A
and V = 3.3V.
DD
MIN
MAX
SYMBOL
PARAMETER
Main Power Supply
Backup Power Supply
CONDITIONS
(Note 16)
TYP
(Note 16)
UNIT
V
NOTES
V
2.7
1.8
5.5
5.5
DD
V
V
BAT
Electrical Specifications
MIN
MAX
SYMBOL
PARAMETER
Supply Current with I2C Active
CONDITIONS
(Note 16)
TYP
(Note 16)
UNIT
µA
NOTES
I
V
V
V
V
V
V
= 2.7V
500
800
2.5
7, 8, 9
DD1
DD
DD
DD
DD
DD
DD
BAT
= 5.5V
µA
I
I
Supply Current for Non-Volatile
Programming
= 2.7V
= 5.5V
mA
mA
µA
7, 8, 9
9
DD2
DD3
3.5
Supply Current for Main
Timekeeping (Low Power Mode)
= V
= V
= V
= V
= 2.7V
= 5.5V
10
SDA
SDA
SCL
SCL
20
µA
I
Battery Supply Current
V
V
= 1.8V,
= V = V
800
850
1000
nA
7, 10, 11
BAT
= V
= 0
= 0
DD
SDA
SCL
RESET
V
V
= 3.0V,
1200
nA
BAT
= V
= V
= V
DD
SDA
SCL
RESET
I
Battery Input Leakage
V
= 5.5V, V
= 1.8V
100
2.6
nA
V
BATLKG
DD
BAT
V
V
V
V
V
Mode Threshold
Hysteresis
1.8
2.2
30
50
11
TRIP
BAT
TRIP
BAT
V
mV
mV
V/ms
11, 14
11, 14
12
TRIPHYS
V
Hysteresis
BATHYS
V
Negative Slew Rate
DD
10
DD SR-
IRQ/F
OUT
V
Output Low Voltage
V
= 5V
= 3mA
0.4
0.4
V
V
OL
DD
I
OL
V
= 1.8V
DD
I
= 1mA
OL
I
Output Leakage Current
V
V
= 5.5V
100
400
nA
LO
DD
= 5.5V
OUT
FN8231 Rev 9.00
November 30, 2010
Page 3 of 24
ISL12026, ISL12026A
EEPROM Specifications
MIN
MAX
PARAMETER
EEPROM Endurance
EEPROM Retention
TEST CONDITIONS
(Note 16)
TYP
(Note 16)
UNITS
Cycles
Years
NOTES
>2,000,000
50
Temperature 75°C
Serial Interface (I2C) Specifications
DC Electrical Specifications
MIN
MAX
SYMBOL
PARAMETER
TEST CONDITIONS
(Note 16)
TYP
(Note 16)
UNITS
NOTES
V
SDA and SCL Input Buffer LOW
Voltage
-0.3
0.3xV
V
V
V
IL
DD
V
SDA and SCL Input Buffer HIGH
Voltage
0.7 x V
V
+ 0.3
DD
IH
DD
Hysteresis SDA and SCL Input Buffer
Hysteresis
0.05 x V
0
DD
V
I
SDA Output Buffer LOW Voltage
Input Leakage Current on SCL
I/O Leakage Current on SDA
I
= 4mA
OL
0.4
V
OL
LI
V
V
= 5.5V
= 5.5V
100
100
nA
nA
IN
IN
I
LO
AC Electrical Specifications
MIN
(Note 16)
MAX
(Note 16) UNITS
SYMBOL
PARAMETER
SCL Frequency
TEST CONDITIONS
TYP
NOTES
f
400
50
kHz
ns
SCL
t
Pulse width Suppression Time at
SDA and SCL Inputs
Any pulse narrower than the max
spec is suppressed.
IN
t
SCL Falling Edge to SDA Output
Data Valid
SCL falling edge crossing 30% of
900
ns
ns
AA
V
, until SDA exits the 30% to 70%
DD
of V
window.
DD
t
Time the Bus Must be Free Before SDA crossing 70% of V
during a
DD
1300
BUF
the Start of a New Transmission
STOP condition, to SDA crossing
70% of V during the following
DD
START condition.
t
Clock LOW Time
Measured at the 30% of V
crossing.
1300
600
600
600
ns
ns
ns
ns
LOW
DD
DD
t
Clock HIGH Time
Measured at the 70% of V
crossing.
HIGH
t
START Condition Set-up Time
START Condition Hold Time
SCL rising edge to SDA falling edge.
Both crossing 70% of V
SU:STA
HD:STA
.
DD
t
t
From SDA falling edge crossing
30% of V to SCL falling edge
DD
crossing 70% of V
.
DD
Input Data Set-up Time
Input Data Hold Time
From SDA exiting the 30% to 70% of
window, to SCL rising edge
100
0
ns
ns
SU:DAT
V
DD
crossing 30% of V
.
DD
t
From SCL rising edge crossing 70%
of V to SDA entering the 30% to
HD:DAT
DD
70% of V
window.
DD
FN8231 Rev 9.00
November 30, 2010
Page 4 of 24
ISL12026, ISL12026A
AC Electrical Specifications
(Continued)
MIN
MAX
SYMBOL
PARAMETER
TEST CONDITIONS
(Note 16)
TYP
(Note 16) UNITS
NOTES
t
STOP Condition Set-up Time
From SCL rising edge crossing 70%
600
ns
SU:STO
of V , to SDA rising edge crossing
DD
30% of V
.
DD
t
STOP Condition Hold Time for
Read or Volatile Only Write
From SDA rising edge to SCL falling
edge. Both crossing 70% of V
600
0
ns
ns
HD:STO
.
DD
t
Output Data Hold Time
From SCL falling edge crossing 30%
of V , until SDA enters the 30% to
DH
DD
70% of V
window.
DD
Cpin
SDA and SCL Pin Capacitance
Non-volatile Write Cycle Time
SDA and SCL Rise Time
10
20
pF
ms
ns
t
12
14
WC
t
From 30% to 70% of V
From 70% to 30% of V
20 + 0.1xCb
300
300
400
R
DD
DD
t
SDA and SCL Fall Time
20 +0.1xCb
ns
15
15
15
F
Cb
Capacitive Loading of SDA or SCL Total on-chip and off-chip
10
1
pF
k
R
SDA and SCL Bus Pull-up Resistor Maximum is determined by t and t .
PU
R
F
Off-chip
For Cb = 400pF, max is about
2k~2.5k.
For Cb = 40pF, max is about
15k~20k
NOTES:
7. IRQ/F
Inactive.
OUT
8. V = V
x 0.1, V = V
x 0.9, f
= 400kHz
SCL
IL
DD
IH
+V
BAT BATHYS
DD
9. V
> V
DD
10. Bit BSW = 0 (Standard Mode), ATR = 00h, V
11. Specified at +25°C.
1.8V
BAT
12. In order to ensure proper timekeeping, the V
13. Parameter is not 100% tested.
specification must be followed.
DD SR-
14. t
is the minimum cycle time to be allowed for any non-volatile Write by the user, it is the time from valid STOP condition at the end of Write
WC
sequence of a serial interface Write operation, to the end of the self-timed internal non-volatile write cycle.
15. These are I2C specific parameters and are not directly tested, however they are used during device testing to validate device specification.
16. Compliance to datasheet limits is assured by one or more methods: production test, characterization and/or design.
Timing Diagrams
Bus Timing
t
t
t
t
R
F
HIGH
LOW
t
HD:STO
SCL
t
SU:DAT
t
t
HD:DAT
t
SU:STA
SU:STO
t
HD:STA
SDA
(INPUT TIMING)
t
t
BUF
DH
t
AA
SDA
(OUTPUT TIMING)
FN8231 Rev 9.00
November 30, 2010
Page 5 of 24
ISL12026, ISL12026A
Write Cycle Timing
SCL
8TH BIT OF LAST BYTE
ACK
SDA
t
WC
STOP
START
CONDITION
CONDITION
Typical Performance Curves Temperature is +25°C unless otherwise specified.
0.9
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
BSW = 0 OR 1
SCL, SDA PULL-UPS = 0V
BSW = 0 OR 1
SCL, SDA PULL-UPS = 0V
SCL, SDA PULL-UPS = V
BSW = 0 OR 1
BAT
1.8
2.3
2.8
3.3
3.8
(V)
4.3
4.8
5.3
1.8
2.3
2.8
3.3
3.8
(V)
4.3
4.8
5.3
V
V
BAT
BAT
FIGURE 1. I
vs V
SBIB = 0
FIGURE 2. I
vs V
SBIB = 1
BAT,
BAT
BAT,
BAT
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0.0
5.0
4.5
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
V
= 5.5V
DD
V
= 3.0V
BAT
V
= 3.3V
DD
-45 -35 -25 -15 -5
5
15 25 35 45 55 65 75 85
-45 -35 -25 -15 -5
5
15 25 35 45 55 65 75 85
TEMPERATURE (°C)
TEMPERATURE (°C)
FIGURE 4. I
vs TEMPERATURE
BAT
FIGURE 3. I
vs TEMPERATURE
DD3
FN8231 Rev 9.00
November 30, 2010
Page 6 of 24
ISL12026, ISL12026A
Typical Performance Curves (Continued)Temperature is +25°C unless otherwise specified.
4.5
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
80
60
40
20
0
-20
-40
1.8
2.3
2.8
3.3
3.8
(V)
4.3
4.8
5.3
-32 -28 -24 -20 -16 -12 -8 -4
0
4
8
12 16 20 24 28
V
ATR SETTING
DD
FIGURE 5. I
vs V
FIGURE 6. F
vs ATR SETTING
OUT
DD3
DD
Description
Pin Descriptions
The ISL12026 device is a Real Time Clock with clock/calendar,
two polled alarms with integrated 512x8 EEPROM, oscillator
compensation and battery backup switch.
Serial Clock (SCL)
The SCL input is used to clock all data into and out of the device.
The input buffer on this pin is always active (not gated). The pull-
up resistor on this pin must use the same voltage source as
The oscillator uses an external, low-cost 32.768kHz crystal. All
compensation and trim components are integrated on the chip.
This eliminates several external discrete components and a
trim capacitor, saving board area and component cost.
V
.
DD
Serial Data (SDA)
SDA is a bidirectional pin used to transfer data into and out of
the device. It has an open drain output and may be wire ORed
with other open drain or open collector outputs. The input
buffer is always active (not gated).
The Real Time Clock keeps track of time with separate
registers for Hours, Minutes and Seconds. The Calendar has
separate registers for Date, Month, Year and Day-of-week. The
calendar is correct through 2099, with automatic leap year
correction.
This open drain output requires the use of a pull-up resistor. The
pull-up resistor on this pin must use the same voltage source as
The Dual Alarms can be set to any Clock/Calendar value for a
match. For instance, every minute, every Tuesday, or 5:23 AM
on March 21. The alarms can be polled in the Status Register
V
. The output circuitry controls the fall time of the output
DD
signal with the use of a slope controlled pull-down. The circuit is
designed to comply with 400kHz I2C interface speed.
or can provide a hardware interrupt (IRQ/F
Pin). There is a
OUT
V
pulse mode for the alarms allowing for repetitive alarm
functionality.
BAT
This input provides a backup supply voltage to the device.
V
supplies power to the device in the event the V supply
DD
BAT
The IRQ/F
pin may be software selected to provide a
OUT
fails. This pin can be connected to a battery, a SuperCap or
tied to ground if not used.
frequency output of 1Hz, 4096Hz, or 32,768Hz or inactive.
The device offers a backup power input pin. This V pin
BAT
IRQ/F
(Interrupt Output/Frequency Output)
OUT
This dual function pin can be used as an interrupt or frequency
output pin. The IRQ/F mode is selected via the frequency
allows the device to be backed up by battery or SuperCap. The
entire ISL12026 device is fully operational from 2.7V to 5.5V
and the clock/calendar portion of the ISL12026 device remains
fully operational down to 1.8V (Standby Mode).
OUT
out control bits of the INT register.
• Interrupt Mode. The pin provides an interrupt signal output.
This signal notifies a host processor that an alarm has
occurred and requests action. It is an open drain active low
output.
The ISL12026 device provides 4k bits of EEPROM with 8
modes of BlockLock™ control. The BlockLock™ allows a safe,
secure memory for critical user and configuration data, while
allowing a large user storage area.
• Frequency Output Mode. The pin outputs a clock signal
which is related to the crystal frequency. The frequency
output is user selectable and enabled via the I2C bus. It is an
open drain output.
FN8231 Rev 9.00
November 30, 2010
Page 7 of 24
ISL12026, ISL12026A
register write is in progress and the RTC continues to run
during any non-volatile write sequences.
X1, X2
The X1 and X2 pins are the input and output, respectively, of
an inverting amplifier. An external 32.768kHz quartz crystal is
used with the ISL12026 to supply a timebase for the real time
clock. Internal compensation circuitry provides high accuracy
over the operating temperature range from -40°C to +85°C.
This oscillator compensation network can be used to calibrate
the crystal timing accuracy over-temperature either during
manufacturing or with an external temperature sensor and
microcontroller for active compensation. X2 is intended to drive
a crystal only, and should not drive any external circuit.
Accuracy of the Real Time Clock
The accuracy of the Real Time Clock depends on the accuracy
of the quartz crystal that is used as the time base for the RTC.
Since the resonant frequency of a crystal is temperature
dependent, the RTC performance will also be dependent upon
temperature. The frequency deviation of the crystal is a
function of the turnover temperature of the crystal from the
crystal’s nominal frequency. For example, a >20ppm frequency
deviation translates into an accuracy of >1 minute per month.
These parameters are available from the crystal manufacturer.
Intersil’s RTC family provides on-chip crystal compensation
networks to adjust load-capacitance to tune oscillator
frequency from -34ppm to +80ppm when using a 12.5pF load
crystal. For more detailed information, see “Application
Section” on page 19.
X1
X2
FIGURE 7. RECOMMENDED CRYSTAL CONNECTION
Real Time Clock Operation
Clock/Control Registers (CCR)
The Real Time Clock (RTC) uses an external 32.768kHz
quartz crystal to maintain an accurate internal representation of
the second, minute, hour, day, date, month and year. The RTC
has leap-year correction. The clock also corrects for months
having fewer than 31 days and has a bit that controls 24 hour
or AM/PM format. When the ISL12026 powers up after the loss
The Control/Clock Registers are located in an area separate
from the EEPROM array and are only accessible following a
slave byte of “1101111x” and reads or writes to addresses
[0000h:003Fh]. The clock/control memory map has memory
addresses from 0000h to 003Fh. The defined addresses are
described in the Table 1. Writing to and reading from the
undefined addresses are not recommended.
of both V
and V , the clock will not operate until at least
BAT
DD
one byte is written to the clock register.
CCR Access
Reading the Real Time Clock
The contents of the CCR can be modified by performing a byte
or a page write operation directly to any address in the CCR.
Prior to writing to the CCR (except the status register),
however, the WEL and RWEL bits must be set using a three
step process (see “Writing to the Clock/Control Registers” on
page 12).
The RTC is read by initiating a Read command and specifying
the address corresponding to the register of the Real Time
Clock. The RTC Registers can then be read in a Sequential
Read Mode. Since the clock runs continuously and a read takes
a finite amount of time, there is the possibility that the clock
could change during the course of a read operation. In this
device, the time is latched by the read command (falling edge of
the clock on the ACK bit prior to RTC data output) into a
separate latch to avoid time changes during the read operation.
The clock continues to run. Alarms occurring during a read are
unaffected by the read operation.
The CCR is divided into 5 sections. These are:
1. Alarm 0 (8 bytes; non-volatile)
2. Alarm 1 (8 bytes; non-volatile)
3. Control (5 bytes; non-volatile)
4. Real Time Clock (8 bytes; volatile)
5. Status (1 byte; volatile)
Writing to the Real Time Clock
The time and date may be set by writing to the RTC registers.
RTC Register should be written ONLY with Page Write. To
avoid changing the current time by an incomplete write
operation, write to the all 8 bytes in one write operation. When
writing the RTC registers, the new time value is loaded into a
separate buffer at the falling edge of the clock during the
Acknowledge. This new RTC value is loaded into the RTC
Register by a stop bit at the end of a valid write sequence. An
invalid write operation aborts the time update procedure and
the contents of the buffer are discarded. After a valid write
operation, the RTC will reflect the newly loaded data beginning
with the next “one second” clock cycle after the stop bit is
written. The RTC continues to update the time while an RTC
Each register is read and written through buffers. The
non-volatile portion (or the counter portion of the RTC) is
updated only if RWEL is set and only after a valid write operation
and stop bit. A sequential read or page write operation provides
access to the contents of only one section of the CCR per
operation. Access to another section requires a new operation.
A read or write can begin at any address in the CCR.
It is not necessary to set the RWEL bit prior to writing the
status register. See “Status Register (SR)” on page 9. supports
a single byte read or write only. Continued reads or writes from
this section terminates the operation.
FN8231 Rev 9.00
November 30, 2010
Page 8 of 24
ISL12026, ISL12026A
The state of the CCR can be read by performing a random
read at any address in the CCR at any time. This returns the
contents of that register location. Additional registers are read
by performing a sequential read. The read instruction latches
all Clock registers into a buffer, so an update of the clock does
not change the time being read. A sequential read of the CCR
will not result in the output of data from the memory array. At
the end of a read, the master supplies a stop condition to end
the operation and free the bus. After a read of the CCR, the
address remains at the previous address +1 so the user can
execute a current address read of the CCR and continue
reading the next Register.
AL1, AL0: Alarm Bits - Volatile
These bits announce if either alarm 0 or alarm 1 match the real
time clock. If there is a match, the respective bit is set to ‘1’.
The falling edge of the last data bit in a SR Read operation
resets the flags. Note: Only the AL bits that are set when an SR
read starts will be reset. An alarm bit that is set by an alarm
occurring during an SR read operation will remain set after the
read operation is complete.
OSCF: Oscillator Fail Indicator
This bit is set to “1” if the oscillator is not operating, or is
operating, but has clock jitter which does not affect the
accuracy of RTC counting. The bit is set to “0” if the oscillator is
functioning, and does not have clock jitter. This bit is read only,
and is set/reset by hardware.
Real Time Clock Registers
SC, MN, HR, DT, MO, YR: Clock/Calendar Registers
RWEL: Register Write Enable Latch - Volatile
These registers depict BCD representations of the time. As
such, SC (Seconds) and MN (Minutes) range from 00 to 59,
HR (Hour) is 1 to 12 with an AM or PM indicator (H21 bit) or 0
to 23 (with MIL = 1), DT (Date) is 1 to 31, MO (Month) is 1 to
12, YR (Year) is 0 to 99.
This bit is a volatile latch that powers up in the LOW (disabled)
state. The RWEL bit must be set to “1” prior to any writes to the
Clock/Control Registers. Writes to RWEL bit do not cause a
non-volatile write cycle, so the device is ready for the next
operation immediately after the stop condition. A write to the
CCR requires both the RWEL and WEL bits to be set in a
specific sequence.
DW: Day of the Week Register
This register provides a Day of the Week status and uses three
bits DY2 to DY0 to represent the seven days of the week. The
counter advances in the cycle 0-1-2-3-4-5-6-0-1-2-… The
assignment of a numerical value to a specific day of the week
is arbitrary and may be decided by the system software
designer. The default value is defined as ‘0’.
WEL: Write Enable Latch - Volatile
The WEL bit controls the access to the CCR during a write
operation. This bit is a volatile latch that powers up in the LOW
(disabled) state. While the WEL bit is LOW, writes to the CCR
address will be ignored, although acknowledgment is still issued.
The WEL bit is set by writing a “1” to the WEL bit and zeroes to
the other bits of the Status Register. Once set, WEL remains set
until either reset to 0 (by writing a “0” to the WEL bit and zeroes
to the other bits of the Status Register) or until the part powers
up again. Writes to WEL bit do not cause a non-volatile write
cycle, so the device is ready for the next operation immediately
after the stop condition.
24 Hour Time
If the MIL bit of the HR register is 1, the RTC uses a 24-hour
format. If the MIL bit is 0, the RTC uses a 12-hour format and H21
bit functions as an AM/PM indicator with a ‘1’ representing PM.
The clock defaults to standard time with H21 = 0.
Leap Years
Leap years add the day February 29 and are defined as those
years that are divisible by 4.
RTCF: Real Time Clock Fail Bit - Volatile
This bit is set to a “1” after a total power failure. This is a read
only bit that is set by hardware (ISL12026 internally) when the
device powers up after having lost all power to the device (both
Status Register (SR)
The Status Register is located in the CCR memory map at
address 003Fh. This is a volatile register only and is used to
control the WEL and RWEL write enable latches, read power
status and two alarm bits. This register is separate from both
the array and the Clock/Control Registers (CCR).
V
V
and V
go to 0V). The bit is set regardless of whether
is applied first. The loss of only one of the
DD
BAT
or V
DD
BAT
supplies does not set the RTCF bit to “1”. On power-up after a
total power failure, all registers are set to their default states
and the clock will not increment until at least one byte is written
to the clock register. The first valid write to the RTC section
after a complete power failure resets the RTCF bit to “0”
(writing one byte is sufficient).
TABLE 1. STATUS REGISTER (SR)
ADDR
003Fh BAT AL1 AL0 OSCF
Default
7
6
5
4
3
0
0
2
1
0
RWEL WEL RTCF
0
0
0
0
0
0
1
Unused Bits
BAT: Battery Supply - Volatile
This bit set to “1” indicates that the device is operating from
, not V . It is a read-only bit and is set/reset by hardware
Bit 3 in the SR is not used, but must be zero. The Data Byte
output during a SR read will contain a zero in this bit location.
V
BAT
DD
(ISL12026 internally). Once the device begins operating from
, the device sets this bit to “0”.
V
DD
FN8231 Rev 9.00
November 30, 2010
Page 9 of 24
ISL12026, ISL12026A
TABLE 2. CLOCK/CONTROL MEMORY MAP
BIT
ADDR.
003F
0037
0036
0035
0034
0033
0032
0031
0030
0014
0013
0012
0011
0010
000F
000E
000D
000C
000B
000A
0009
0008
0007
0006
0005
0004
0003
0002
0001
0000
TYPE
REG NAME
SR
7
BAT
0
6
AL1
0
5
AL0
Y2K21
0
4
OSCF
Y2K20
0
3
0
2
RWEL
0
1
0
RTCF
Y2K10
DY0
Y10
G10
D10
H10
M10
S10
0
RANGE
Status
WEL
0
01h
20h
00h
00h
00h
01h
00h
00h
00h
40h
00h
00h
00h
00h
20h
00h
01h
20h
00h
00h
00h
01h
00h
00h
00h
00h
00h
00h
00h
00h
20h
00h
RTC
(SRAM)
Y2K
Y2K13
0
19/20
0-6
DW
0
0
DY2
Y12
G12
D12
H12
M12
S12
0
DY1
Y11
G11
D11
H11
M11
S11
0
YR
Y23
0
Y22
0
Y21
0
Y20
G20
D20
H20
M20
S20
0
Y13
G13
D13
H13
M13
S13
0
0-99
1-12
1-31
0-23
0-59
0-59
MO
DT
0
0
D21
H21
M21
S21
0
HR
MIL
0
0
MN
M22
S22
BSW
0
SC
0
Control
(EEPROM)
PWR
DTR
SBIB
0
0
0
0
DTR2 DTR1
DTR0
ATR0
0
ATR
0
0
ATR5
AL0E
BP0
ATR4
FO1
0
ATR3
FO0
0
ATR2
ATR1
INT
IM
BP2
0
AL1E
BP1
0
0
0
0
0
BL
0
Alarm1
(EEPROM)
Y2K1
DWA1
YRA1
MOA1
DTA1
HRA1
MNA1
SCA1
Y2K0
DWA0
YRA0
MOA0
DTA0
HRA0
MNA0
SCA0
A1Y2K21 A1Y2K20 A1Y2K13
0
0
A1Y2K10 19/20
EDW1
0
0
0
0
DY2
DY1
DY0
0-6
Unused - Default = RTC Year value (No EEPROM) - Future expansion
EMO1
EDT1
EHR1
0
0
0
0
A1G20
A1D20
A1H20
A1M20
A1S20
A1G13
A1D13
A1H13
A1G12 A1G11
A1D12 A1D11
A1H12 A1H11
A1G10
A1D10
A1H10
1-12
1-31
0-23
0-59
0-59
00h
00h
00h
00h
00h
20h
00h
00h
00h
00h
00h
00h
20h
00h
A1D21
A1H21
EMN1 A1M22 A1M21
ESC1 A1S22 A1S21
A1M13 A1M12 A1M11 A1M10
A1S13 A1S12 A1S11 A1S10
Alarm0
(EEPROM)
0
0
0
A0Y2K21 A0Y2K20 A0Y2K13
0
0
A0Y2K10 19/20
EDW0
0
0
0
DY2
DY1
DY0
0-6
Unused - Default = RTC Year value (No EEPROM) - Future expansion
EMO0
EDT0
EHR0
0
0
0
0
A0G20
A0D20
A0H20
A0M20
A0S20
A0G13
A0D13
A0H13
A0G12 A0G11
A0D12 A0D11
A0H12 A0H11
A0G10
A0D10
A0H10
1-12
1-31
0-23
0-59
0-59
00h
00h
00h
00h
00h
00h
00h
00h
00h
00h
A0D21
A0H21
EMN0 A0M22 A0M21
ESC0 A0S22 A0S21
A0M13 A0M12 A0M11 A0M10
A0S13 A0S12 A0S11 A0S10
See “Device Operation” on page 12 and “Application Section”
on page 19 for more information.
Alarm Registers (Non-Volatile)
Alarm0 and Alarm1
Control Registers (Non-Volatile)
The alarm register bytes are set up identical to the RTC
register bytes, except that the MSB of each byte functions as
an enable bit (enable = “1”). These enable bits specify which
alarm registers (seconds, minutes, etc.) are used to make the
comparison. Note that there is no alarm byte for year.
The Control Bits and Registers described in the following are
non-volatile.
BL Register
BP2, BP1, BP0 - Block Protect Bits
The alarm function works as a comparison between the alarm
registers and the RTC registers. As the RTC advances, the
alarm will be triggered once a match occurs between the alarm
registers and the RTC registers. Any one alarm register,
multiple registers, or all registers can be enabled for a match.
The Block Protect Bits, BP2, BP1 and BP0, determine which
blocks of the array are write protected. A write to a protected block
of memory is ignored. The block protect bits will prevent write
operations to one of eight segments of the array. The partitions
are described in Table 3.
FN8231 Rev 9.00
November 30, 2010
Page 10 of 24
ISL12026, ISL12026A
TABLE 3.
Oscillator Compensation Registers
There are two trimming options.
PROTECTED ADDRESSES
ISL12026
ARRAY LOCK
None
• ATR. Analog Trimming Register
• DTR. Digital Trimming Register
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
None (Default)
180 – 1FF
Upper 1/4
h
h
h
h
h
h
These registers are non-volatile. The combination of analog
and digital trimming can give up to -64 to +110 ppm of total
adjustment.
100 – 1FF
h
Upper 1/2
000 – 1FF
h
Full Array
000 – 03F
h
First 4 Pages
First 8 Pages
First 16 Pages
Full Array
ATR Register - ATR5, ATR4, ATR3, ATR2, ATR1,
ATR0: Analog Trimming Register
000 – 07F
h
6 analog trimming bits, ATR0 to ATR5, are provided in order to
adjust the on-chip load capacitance value for frequency
compensation of the RTC. Each bit has a different weight for
capacitance adjustment. For example, using a Citizen CFS-
206 crystal with different ATR bit combinations provides an
estimated ppm adjustment range from -34 to +80ppm to the
nominal frequency compensation.
000 – 0FF
h
h
h
000 – 1FF
h
INT Register: Interrupt Control and
Frequency Output Register
IM, AL1E, AL0E - Interrupt Control and Status Bits
There are two Interrupt Control bits, Alarm 1 Interrupt Enable
(AL1E) and Alarm 0 Interrupt Enable (AL0E) to specifically
enable or disable the alarm interrupt signal output
X1
(IRQ/F
). The interrupts are enabled when either the AL1E
OUT
C
C
X1
X2
CRYSTAL
or AL0E or both bits are set to ‘1’ and both the FO1 and FO0
bits are set to 0 (F disabled).
OSCILLATOR
OUT
X2
The IM bit enables the pulsed interrupt mode. To enter this
mode, the AL0E or AL1E bits are set to “1”, and the IM bit to “1”.
The IRQ/F
output will now be pulsed each time an alarm
OUT
occurs. This means that once the interrupt mode alarm is set, it
will continue to alarm for each occurring match of the alarm and
present time. This mode is convenient for hourly or daily
hardware interrupts in microcontroller applications such as
security cameras or utility meter reading.
FIGURE 8. DIAGRAM OF ATR
The effective on-chip series load capacitance, C
, ranges
LOAD
from 4.5pF to 20.25pF with a mid-scale value of 12.5pF
(default). C is changed via two digitally controlled
In the case that both Alarm 0 and Alarm 1 are enabled, the
LOAD
IRQ/F
pin will be pulsed each time either alarm matches
OUT
capacitors, C and C , connected from the X1 and X2 pins
X1
X2
the RTC (both alarms can provide hardware interrupt). If the IM
to ground (see Figure 8). The value of C and C is given by
X1
X2
bit is also set to "1", the IRQ/F
alarms as well.
will be pulsed for each of the
OUT
Equation 1:
C
= 16 b5 + 8 b4 + 4 b3 + 2 b2 + 1 b1 + 0.5 b0 + 9pF
X
FO1, FO0 - Programmable Frequency Output Bits
(EQ. 1)
These are two output control bits. They select one of three
divisions of the internal oscillator, that is applied to the
The effective series load capacitance is the combination of C
X1
and C
:
IRQ/F
output pin. Table 4 shows the selection bits for this
X2
OUT
output. When using this function, the Alarm output function is
disabled.
1
----------------------------------
C
=
LOAD
1
1
---------- ----------
+
C
C
X2
X1
TABLE 4. PROGRAMMABLE FREQUENCY OUTPUT BITS
16 b5 + 8 b4 + 4 b3 + 2 b2 + 1 b1 + 0.5 b0 + 9
FO1
FO0
OUTPUT FREQUENCY
Alarm output (F disabled)
-----------------------------------------------------------------------------------------------------------------------------
C
=
pF
(EQ. 2)
LOAD
2
0
0
1
1
0
1
0
1
OUT
32.768kHz
4096Hz
1Hz
For example, C
(ATR = 00000) = 12.5pF, C
LOAD
LOAD
(ATR = 100000) = 4.5pF, and C
(ATR = 011111) = 20.25pF.
LOAD
The entire range for the series combination of load capacitance
goes from 4.5pF to 20.25pF in 0.25pF steps. Note that these are
typical values.
FN8231 Rev 9.00
November 30, 2010
Page 11 of 24
ISL12026, ISL12026A
DTR Register - DTR2, DTR1, DTR0: Digital Trimming
Register
Device Operation
Writing to the Clock/Control Registers
The digital trimming Bits DTR2, DTR1 and DTR0 adjust the
number of counts per second and average the ppm error to
achieve better accuracy.
Changing any of the bits of the clock/control registers requires
the following steps:
1. Write a 02h to the Status Register to set the Write Enable
Latch (WEL). This is a volatile operation, so there is no
delay after the write (operation preceded by a start and
ended with a stop).
DTR2 is a sign bit. DTR2 = 0 means frequency compensation
is > 0. DTR2 = 1 means frequency compensation is < 0.
DTR1 and DTR0 are scale bits. DTR1 gives 10 ppm
adjustment and DTR0 gives 20 ppm adjustment.
2. Write a 06h to the Status Register to set both the Register
Write Enable Latch (RWEL) and the WEL bit. This is also a
volatile cycle. The zeros in the data byte are required
(operation proceeded by a start and ended with a stop).
A range from -30ppm to +30ppm can be represented by using
the three DTR bits.
TABLE 5. DIGITAL TRIMMING REGISTERS
Write all 8 bytes to the RTC registers, or one byte to the SR, or
one to five bytes to the control registers. This sequence starts
with a start bit, requires a slave byte of “11011110” and an
address within the CCR and is terminated by a stop bit. A write
to the EEPROM registers in the CCR will initiate a non-volatile
write cycle and will take up to 20ms to complete. A write to the
RTC registers (SRAM) will require much shorter cycle time (t =
DTR REGISTER
ESTIMATED FREQUENCY
DTR2
DTR1
DTR0
PPM
0
0
0
0
1
1
1
1
0
1
0
1
0
1
0
1
0
0
1
1
0
0
1
1
0
+10
+20
+30
0
t
). Writes to undefined areas have no effect. The RWEL bit
BUF
is reset by the completion of a write to the CCR, so the
sequence must be repeated to again initiate another change to
the CCR contents. If the sequence is not completed for any
reason (by sending an incorrect number of bits or sending a
start instead of a stop, for example), the RWEL bit is not reset
and the device remains in an active mode. Writing all zeros to
the status register resets both the WEL and RWEL bits. A read
operation occurring between any of the previous operations
will not interrupt the register write operation.
-10
-20
-30
PWR Register: SBIB, BSW
SBIB: - Serial Bus Interface (Enable)
Alarm Operation
The serial bus can be disabled in battery backup mode by
setting this bit to “1”. This will minimize power drain on the
battery. The Serial Interface can be enabled in battery backup
mode by setting this bit to “0”. (default is “0”). See “BSW:
Power Control Bit” on page 12.
Since the alarm works as a comparison between the alarm
registers and the RTC registers, it is ideal for notifying a host
processor of a particular time event, which triggers some
action as a result. The host can be notified by either a
hardware interrupt (the IRQ/F
pin) or by polling the Status
OUT
BSW: Power Control Bit
Register (SR) Alarm bits. These two volatile bits (AL1for Alarm
1 and AL0 for Alarm 0), indicate if an alarm has happened. The
bits are set on an alarm condition regardless of whether the
The Power Control bit, BSW, determines the conditions for
switching between V
options.
and Backup Battery. There are two
DD
IRQ/F
interrupt is enabled. The AL1 and AL0 bits in the
OUT
status register are reset by the falling edge of the eighth clock
of status register read.
Option 1. Standard Mode: Set “BSW = 0”
Option 2. Legacy Mode: Set “BSW = 1”
There are two alarm operation modes: Single Event and
periodic Interrupt Mode:
See “Power Control Operation” on page 13 for more details.
Also see “I2C Communications During Battery Backup” on
page 22 for important details.
1. Single Event Mode is enabled by setting the AL0E or AL1E
bit to “1”, the IM bit to “0”, and disabling the frequency
output. This mode permits a one-time match between the
alarm registers and the RTC registers. Once this match
TABLE 6. V
TRIP POINT WITH DIFFERENT BSW SETTING
BAT
V
TRIP POINT
(V)
BAT
occurs, the AL0 or AL1 bit is set to “1” and the IRQ/F
OUT
BSW BIT
POWER CONTROL SETTING
output will be pulled low and will remain low until the AL0 or
AL1 bit is read, which will automatically resets it. Both Alarm
registers can be set at the same time to trigger alarms. The
0
1
2.2
Standard Mode (ISL12026A)
Legacy Mode (ISL12026)
V
< V
BAT
DD
IRQ/F
output will be set by either alarm, and will need
OUT
to be cleared to enable triggering by a subsequent alarm.
Polling the SR will reveal which alarm has been set.
FN8231 Rev 9.00
November 30, 2010
Page 12 of 24
ISL12026, ISL12026A
2. Interrupt Mode (or “Pulsed Interrupt Mode” or PIM) is
enabled by setting the AL0E or AL1E bit to “1” the IM bit to
“1”, and disabling the frequency output. If both AL0E and
AL1E bits are set to "1", then both AL0E and AL1E PIM
If the Alarm1 is used, SCA1 would need to have the correct
data written.
Power Control Operation
The power control circuit accepts a V
and a V
input.
BAT
alarms will function. The IRQ/F
output will now be
DD
OUT
pulsed each time each of the alarms occurs. This means
that once the interrupt mode alarm is set, it will continue to
alarm for each occurring match of the alarm and present
time. This mode is convenient for hourly or daily hardware
interrupts in microcontroller applications such as security
cameras or utility meter reading. Interrupt Mode CANNOT
be used for general periodic alarms, however, since a
specific time period cannot be programmed for interrupt,
only matches to a specific time of day. The interrupt mode
is only stopped by disabling the IM bit or the Alarm Enable
bits.
Many types of batteries can be used with Intersil RTC
products. For example, 3.0V or 3.6V Lithium batteries are
appropriate, and battery sizes are available that can power an
Intersil RTC device for up to 10 years. Another option is to use
a SuperCap for applications where V
is interrupted for up to
DD
a month. See “Application Section” on page 19 for more
information.
There are two options for setting the change-over conditions
from V
to Battery backup mode. The BSW bit in the PWR
DD
register controls this operation:
Writing to the Alarm Registers
•
•
Option 1 - Standard Mode (ISL12026A Default)
Option 2 - Legacy Mode (ISL12026 Default)
The Alarm Registers are non-volatile but require special attention
to insure a proper non-volatile write takes place. Specifically, byte
writes to individual registers are good for all but registers 0006h
and 0000Eh, which are the DWA0 and DWA1 registers,
respectively. Those registers will require a special page write for
non-volatile storage. The recommended page write sequences
are as follows:
Note that the I2C bus may or may not be operational during
battery backup. That function is controlled by the SBIB bit. That
operation is covered after the power control section.
OPTION 1- STANDARD POWER CONTROL MODE
(ISL12026A DEFAULT)
1. 16-byte page writes: The best way to write or update the
Alarm Registers is to perform a 16-byte write beginning at
address 0001h (MNA0) and wrapping around and ending at
address 0000h (SCA0). This will insure that non-volatile
storage takes place. This means that the code must be
designed so that the Alarm0 data is written starting with
Minutes register, and then all the Alarm1 data, with the last
byte being the Alarm0 Seconds (the page ends at the
Alarm1 Y2k register and then wraps around to address
0000h).
In the Standard mode, the supply will switch over to the battery
when V
drops below V
or V , whichever is lower. In
TRIP BAT
DD
this mode, accidental operation from the battery is prevented
since the battery backup input will only be used when the V
DD
supply is shut off.
To select Option 1, BSW bit in the Power Register must be set
to “BSW = 0”. A description of power switchover follows.
Standard Mode Power Switchover
Alternatively, the 16-byte page write could start with
address 0009h, wrap around and finish with address
0008h. Note that any page write ending at address 0007h
or 000Fh (the highest byte in each Alarm) will not trigger a
non-volatile write, so wrapping around or overlapping to
the following Alarm's Seconds register is advised.
• Normal Operating Mode (V ) to Battery Backup Mode
DD
(V
)
BAT
To transition from the V
to V
mode, both of the following
DD
BAT
conditions must be met:
- Condition 1:
V
< V
- V
DD
BAT BATHYS
2. Other non-volatile writes: It is possible to do writes of less
than an entire page, but the final byte must always be
addresses 0000h through 0004h or 0008h though 000Ch to
trigger a non-volatile write. Writing to those blocks of
5 bytes sequentially, or individually, will trigger a
where V
50mV
BATHYS
- Condition 2:
V
< V
DD
TRIP
TRIP
where V
2.2V
non-volatile write. If the DWA0 or DWA1 registers need to
be set, then enough bytes will need to be written to overlap
with the other Alarm register and trigger the non-volatile
write. For Example, if the DWA0 register is being set, then
the code can start with a multiple byte write beginning at
address 0006h, and then write 3 bytes ending with the
SCA1 register as follows:
• Battery Backup Mode (V
) to Normal Mode (V
)
BAT
DD
The ISL12026 device will switch from the V
when one of the following conditions occurs:
to V
mode
BAT
DD
- Condition 1:
V
> V
+ V
DD
BAT BATHYS
where V
50mV
BATHYS
Addr Name
0006h DWA0
0007h Y2K0
0008h SCA1
- Condition 2:
V
> V
+ V
DD
TRIP TRIPHYS
where V
30mV
TRIPHYS
FN8231 Rev 9.00
November 30, 2010
Page 13 of 24
ISL12026, ISL12026A
There are two discrete situations that are possible when using
The Legacy Mode power control conditions are illustrated in
Figure 11.
Standard Mode: V
< V
and V
> V . These two
BAT
TRIP
BAT
TRIP
power control situations are illustrated in Figures 9 and 10.
V
DD
VOLTAGE
BATTERY BACKUP
MODE
ON
V
BAT
V
In
DD
Off
V
TRIP
2.2V
1.8V
V
BAT
FIGURE 11. BATTERY SWITCHOVER IN LEGACY MODE
V
+ V
BATHYS
BAT
V
- V
BATHYS
BAT
Serial Communication
The device supports the I2C protocol.
FIGURE 9. BATTERY SWITCHOVER WHEN V
< V
TRIP
BAT
Clock and Data
Data states on the SDA line can change only during SCL LOW.
SDA state changes during SCL HIGH are reserved for
indicating start and stop conditions (see Figure 12).
BATTERY BACKUP
MODE
V
DD
Start Condition
V
BAT
3.0V
2.2V
All commands are preceded by the start condition, which is a
HIGH to LOW transition of SDA when SCL is HIGH. The
device continuously monitors the SDA and SCL lines for the
start condition and will not respond to any command until this
condition has been met (see Figure 13).
V
TRIP
V
TRIP
V
+ V
TRIP
TRIPHYS
FIGURE 10. BATTERY SWITCHOVER WHEN V
> V
TRIP
BAT
Stop Condition
OPTION 2 -LEGACY POWER CONTROL MODE (ISL12026
DEFAULT)
All communications must be terminated by a stop condition,
which is a LOW to HIGH transition of SDA when SCL is HIGH.
The stop condition is also used to place the device into the
Standby power mode after a read sequence. A stop condition
can only be issued after the transmitting device has released
the bus (see Figure 13).
The Legacy Mode follows conditions set in X1226 products. In
this mode, switching from V to V
is simply done by
DD
BAT
comparing the voltages and the device operates from whichever
is the higher voltage. Care should be taken when changing from
Normal to Legacy Mode. If the V
then the device will enter battery back up and unless the battery
is disconnected or the voltage decreases, the device will no
voltage is higher than V
,
BAT
DD
Acknowledge
Acknowledge is a software convention used to indicate
successful data transfer. The transmitting device, either master
or slave, will release the bus after transmitting 8 bits. During
the ninth clock cycle, the receiver will pull the SDA line LOW to
acknowledge that it received the 8 bits of data (see Figure 14).
longer operate from V
.
DD
To select the Option 2, BSW bit in the Power Register must be
set to “BSW = 1”
• Normal Mode (V ) to Battery Backup Mode (V
)
BAT
The device will respond with an acknowledge after recognition
of a start condition and if the correct Device Identifier and
Select bits are contained in the Slave Address Byte. If a write
operation is selected, the device will respond with an
acknowledge after the receipt of each subsequent 8-bit word.
The device will not acknowledge if the slave address byte is
incorrect.
DD
To transition from the V
to V mode, the following
BAT
DD
conditions must be met:
V
< V - V
DD
BAT
BATHYS
• Battery Backup Mode (V
) to Normal Mode (V
)
DD
BAT
The device will switch from the V
following condition occurs:
to V
mode when the
DD
BAT
V
> V
+V
DD
BAT BATHYS
FN8231 Rev 9.00
November 30, 2010
Page 14 of 24
ISL12026, ISL12026A
SCL
SDA
DATA STABLE
DATA CHANGE
DATA STABLE
FIGURE 12. VALID DATA CHANGES ON THE SDA BUS
SCL
SDA
START
STOP
FIGURE 13. VALID START AND STOP CONDITIONS
SCL FROM
MASTER
1
8
9
DATA OUTPUT
FROM TRANSMITTER
DATA OUTPUT
FROM RECEIVER
START
ACKNOWLEDGE
FIGURE 14. ACKNOWLEDGE RESPONSE FROM RECEIVER
In the read mode, the device will transmit 8 bits of data, release
the SDA line, then monitor the line for an acknowledge. If an
acknowledge is detected and no stop condition is generated by
the master, the device will continue to transmit data. The
device will terminate further data transmissions if an
acknowledge is not detected. The master must then issue a
stop condition to return the device to Standby mode and place
the device into a known state.
Bit 3 through Bit 1 of the slave byte specifies the device select
bits. These are set to ‘111’.
The last bit of the Slave Address Byte defines the operation to
be performed. When this R/W bit is a one, then a read
operation is selected. A zero selects a write operation
(see Figure 15).
After loading the entire Slave Address Byte from the SDA bus,
the ISL12026 compares the device identifier and device select
bits with ‘1010111’ or ‘1101111’. Upon a correct compare, the
device outputs an acknowledge on the SDA line.
Device Addressing
Following a start condition, the master must output a Slave
Address Byte. The first 4 bits of the Slave Address Byte specify
access to either the EEPROM array or to the CCR. Slave bits
‘1010’ access the EEPROM array. Slave bits ‘1101’ access the
CCR.
When shipped from the factory, EEPROM array is
UNDEFINED, and should be programmed by the customer to a
known state.
FN8231 Rev 9.00
November 30, 2010
Page 15 of 24
ISL12026, ISL12026A
DEVICE IDENTIFIER
SLAVE ADDRESS BYTE
BYTE 0
ARRAY
CCR
1
1
0
1
1
0
0
1
1
1
1
0
R/W
A8
WORD ADDRESS 1
BYTE 1
0
0
0
0
0
0
WORD ADDRESS 0
BYTE 2
A7
D7
A6
D6
A5
D5
A4
D4
A3
D3
A2
D2
A1
D1
A0
D0
DATA BYTE
BYTE 3
FIGURE 15. SLAVE ADDRESS, WORD ADDRESS, AND DATA BYTES (16 BYTE PAGES)
S
T
A
R
T
SIGNALS FROM
THE MASTER
S
T
O
P
SLAVE
ADDRESS
WORD
ADDRESS 1
WORD
ADDRESS 0
DATA
SDA BUS
1
1 1 1 0
0 0 0 0 0 0 0
A
C
K
A
C
K
A
C
K
A
C
K
SIGNALS FROM
THE SLAVE
FIGURE 16. BYTE WRITE SEQUENCE
Following the Slave Byte is a two byte word address. The word
address is either supplied by the master device or obtained
from an internal counter. On power up the internal address
counter is set to address 0h, so a current address read of the
EEPROM array starts at address 0. When required, as part of
a random read, the master must supply the 2 Word Address
Bytes as shown in Figure 15.
address bytes the ISL12026 awaits the 8 bits of data. After
receiving the 8 data bits, the ISL12026 again responds with an
acknowledge. The master then terminates the transfer by
generating a stop condition. The ISL12026 then begins an
internal write cycle of the data to the non-volatile memory.
During the internal write cycle, the device inputs are disabled,
so the device will not respond to any requests from the master.
The SDA output is at high impedance (see Figure 16).
In a random read operation, the slave byte in the “dummy
write” portion must match the slave byte in the “read” section.
That is if the random read is from the array the slave byte must
be 1010111x in both instances. Similarly, for a random read of
the Clock/Control Registers, the slave byte must be 1101111x
in both places.
A write to a protected block of memory is ignored, but will still
receive an acknowledge. At the end of the write command, the
ISL12026 will not initiate an internal write cycle, and will
continue to ACK commands.
Byte writes to all of the non-volatile registers are allowed,
except the DWAn registers which require multiple byte writes
or page writes to trigger non-volatile writes. See “Device
Operation” on page 12 for more information.
Write Operations
Byte Write
For a write operation, the device requires the Slave Address
Byte and the Word Address Bytes. This gives the master
access to any one of the words in the array or CCR. (Note:
Prior to writing to the CCR, the master must write a 02h, then
06h to the status register in two preceding operations to enable
the write operation. See “Writing to the Clock/Control
Page Write
The ISL12026 has a page write operation. It is initiated in the
same manner as the byte write operation; but instead of
terminating the write cycle after the first data byte is
transferred, the master can transmit up to 15 more bytes to the
memory array and up to 7 more bytes to the clock/control
registers. The RTC registers require a page write (8 bytes),
individual register writes are not allowed. (Note: Prior to writing
Registers” on page 12). Upon receipt of each address byte, the
ISL12026 responds with an acknowledge. After receiving both
FN8231 Rev 9.00
November 30, 2010
Page 16 of 24
ISL12026, ISL12026A
to the CCR, the master must write a 02h, then 06h to the status
register in two preceding operations to enable the write
operation. See “Writing to the Clock/Control Registers” on
page 12).
bytes in a page, then the previously loaded data is over-written
by the new data, one byte at a time. Refer to Figure 18. The
master terminates the Data Byte loading by issuing a stop
condition, which causes the ISL12026 to begin the non-volatile
write cycle. As with the byte write operation, all inputs are
disabled until completion of the internal write cycle. Refer to
Figure 17 for the address, acknowledge, and data transfer
sequence.
After the receipt of each byte, the ISL12026 responds with an
acknowledge, and the address is internally incremented by
one. The address pointer remains at the last address byte
written. When the counter reaches the end of the page, it “rolls
over” and goes back to the first address on the same page.
This means that the master can write 16 bytes to a memory
array page or 8 bytes to a CCR section starting at any location
on that page. For example, if the master begins writing at
location 10 of the memory and loads 15 bytes, then the first 6
bytes are written to addresses 10 through 15, and the last 6
bytes are written to columns 0 through 5. Afterwards, the
address counter would point to location 6 on the page that was
just written. If the master supplies more than the maximum
Stops and Write Modes
Stop conditions that terminate write operations must be sent by
the master after sending at least 1 full data byte and it’s
associated ACK signal. If a stop is issued in the middle of a
data byte, or before 1 full data byte + ACK is sent, then the
ISL12026 resets itself without performing the write. The
contents of the array are not affected.
1 N 16 FOR EEPROM ARRAY
1 N 8 FOR CCR
S
T
SIGNALS FROM
THE MASTER
S
T
O
P
A
R
T
WORD
ADDRESS 1
SLAVE
ADDRESS
WORD
ADDRESS 0
DATA
(1)
DATA
(n)
SDA BUS
1
1 1 1 0
0 0 0 0 0 0 0
A
C
K
A
C
K
A
C
K
A
C
K
SIGNALS FROM
THE SLAVE
FIGURE 17. PAGE WRITE SEQUENCE
6 BYTES
6 BYTES
ADDRESS
10
ADDRESS = 5
ADDRESS
15
ADDRESS POINTER ENDS
AT ADDR = 5
FIGURE 18. WRITING 12 BYTES TO A 16-BYTE MEMORY PAGE STARTING AT ADDRESS 10
FN8231 Rev 9.00
November 30, 2010
Page 17 of 24
ISL12026, ISL12026A
In a similar operation called “Set Current Address,” the device
sets the address if a stop is issued instead of the second start
shown in Figure 21. The ISL12026 then goes into standby
mode after the stop and all bus activity will be ignored until a
start is detected. This operation loads the new address into the
address counter. The next Current Address Read operation will
read from the newly loaded address. This operation could be
useful if the master knows the next address it needs to read,
but is not ready for the data.
Acknowledge Polling
Disabling of the inputs during non-volatile write cycles can be
used to take advantage of the 12ms (typ) write cycle time.
Once the stop condition is issued to indicate the end of the
master’s byte load operation, the ISL12026 initiates the
internal non-volatile write cycle. Acknowledge polling can
begin immediately. To do this, the master issues a start
condition followed by the Memory Array Slave Address Byte for
a write or read operation (AEh or AFh). If the ISL12026 is still
busy with the non-volatile write cycle then no ACK will be
returned. When the ISL12026 has completed the write
operation, an ACK is returned and the host can proceed with
the read or write operation. Refer to the flow chart in Figure 20.
Note: Do not use the CCR Slave byte (DEh or DFh) for
Acknowledge Polling.
S
S
T
T
O
P
SIGNALS FROM
THE MASTER
SLAVE
ADDRESS
A
R
T
SDA BUS
1
1 1 1 1
Read Operations
A
C
K
SIGNALS FROM
THE SLAVE
DATA
There are three basic read operations: Current Address Read,
Random Read and Sequential Read.
FIGURE 19. CURRENT ADDRESS READ SEQUENCE
Current Address Read
Internally the ISL12026 contains an address counter that
maintains the address of the last word read incremented by
one. Therefore, if the last read was to address n, the next read
operation would access data from address n + 1. On power-up,
the 16-bit address is initialized to 00h. In this way, a current
address read immediately after the power on reset can
download the entire contents of memory starting at the first
location. Upon receipt of the Slave Address Byte with the R/W
bit set to one, the ISL12026 issues an acknowledge, then
transmits 8 data bits. The master terminates the read operation
by not responding with an acknowledge during the ninth clock
and issuing a stop condition. Refer to Figure 19 for the
address, acknowledge, and data transfer sequence.
BYTE LOAD
COMPLETED BY
ISSUING STOP.
ENTER ACK POLLING
ISSUE START
ISSUE MEMORY ARRAY SLAVE
ADDRESS BYTE
AFH (READ) OR AEH (WRITE)
ISSUE STOP
NO
It should be noted that the ninth clock cycle of the read
operation is not a “don’t care.” To terminate a read operation,
the master must either issue a stop condition during the ninth
cycle or hold SDA HIGH during the ninth clock cycle and then
issue a stop condition.
ACK
RETURNED?
YES
NO
NON-VOLATILE WRITE
CYCLE COMPLETE. CONTINUE
ISSUE STOP
Random Read
COMMAND SEQUENCE?
Random read operations allow the master to access any
location in the ISL12026. Prior to issuing the Slave Address
Byte with the R/W bit set to zero, the master must first perform
a “dummy” write operation.
YES
CONTINUE
NORMAL READ OR
WRITE COMMAND
SEQUENCE
The master issues the start condition and the slave address
byte, receives an acknowledge, then issues the word address
bytes. After acknowledging receipt of each word address byte,
the master immediately issues another start condition and the
slave address byte with the R/W bit set to one. This is followed
by an acknowledge from the device and then by the 8-bit data
word. The master terminates the read operation by not
responding with an acknowledge and then issuing a stop
condition. Refer to Figure 21 for the address, acknowledge and
data transfer sequence.
PROCEED
FIGURE 20. ACKNOWLEDGE POLLING SEQUENCE
FN8231 Rev 9.00
November 30, 2010
Page 18 of 24
ISL12026, ISL12026A
S
T
A
R
T
S
T
A
R
T
S
T
O
P
SIGNALS FROM
THE MASTER
SLAVE
ADDRESS
WORD
ADDRESS 0
SLAVE
ADDRESS
WORD
ADDRESS 1
SDA BUS
1
1 1 1 1
1
1 1 1 0
0 0 0 0 0 0 0
A
C
K
A
C
K
A
C
K
A
C
K
SIGNALS FROM
THE SLAVE
DATA
FIGURE 21. RANDOM ADDRESS READ SEQUENCE
S
T
O
P
SLAVE
ADDRESS
A
C
K
A
C
K
A
C
K
SIGNALS FROM
THE MASTER
SDA BUS
1
A
C
K
SIGNALS FROM
THE SLAVE
DATA
(2)
DATA
(n-1)
DATA
(1)
DATA
(n)
(n is any integer greater than 1)
FIGURE 22. SEQUENTIAL READ SEQUENCE
The Intersil RTC family uses an oscillator circuit with on-chip
crystal compensation network, including adjustable
load-capacitance. The only external component required is the
crystal. The compensation network is optimized for operation
with certain crystal parameters which are common in many of
the surface mount or tuning-fork crystals available today. Table
7 summarizes these parameters.
Sequential Read
Sequential reads can be initiated as either a current address
read or random address read. The first data byte is transmitted
as with the other modes; however, the master now responds
with an acknowledge, indicating it requires additional data. The
device continues to output data for each acknowledge received.
The master terminates the read operation by not responding
with an acknowledge and then issuing a stop condition.
TABLE 7. CRYSTAL PARAMETERS REQUIRED FOR INTERSIL
RTCs
The data output is sequential, with the data from address n
followed by the data from address n + 1. The address counter
for read operations increments through all page and column
addresses, allowing the entire memory contents to be serially
read during one operation. At the end of the address space,
the counter “rolls over” to the start of the address space, and
the ISL12026 continues to output data for each acknowledge
received. Refer to Figure 22 for the acknowledge and data
transfer sequence.
PARAMETER MIN TYP
MAX UNITS
NOTES
Frequency
32.768
kHz
Frequency
Tolerance
±100
30
ppm Down to 20ppm
if desired
Turnover
20
25
°C
Typically the value
used for most
crystals
Temperature
Operating Temp -40
Range
85
50
°C
pF
k
Application Section
Parallel Load
Capacitance
12.5
Crystal Oscillator and Temperature Compensation
Intersil has now integrated the oscillator compensation circuity
on-chip, to eliminate the need for external components and
adjust for crystal drift over temperature and enable very high
accuracy time keeping (<5ppm drift).
Equivalent
Series
Resistance
For best oscillator
performance
Table 8 contains some crystal manufacturers and part numbers
that meet the requirements for the Intersil RTC products.
FN8231 Rev 9.00
November 30, 2010
Page 19 of 24
ISL12026, ISL12026A
Layout Considerations
TABLE 8. CRYSTAL MANUFACTURERS
TEMP
RANGE TOLERANCE
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 double 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. In Figure 23 is a
suggested layout for the ISL12026 or ISL12027 devices in 8 Ld
SO package.
+25°C FREQ.
PART
MANUFACTURER
NUMBER
(°C)
(ppm)
Citizen
CM201, CM202, CM200S -40 to +85
±20ppm
±20ppm
±20ppm
±20ppm
±20ppm
±20ppm
±20ppm
Epson
MC-405, MC-406
RSM-200S-A or B
32S12A or B
-40 to +85
-40 to +85
-40 to +85
-10 to +60
-10 to +60
-40 to +85
Raltron
SaRonix
Ecliptek
ECS
ECPSM29T-32.768K
ECX-306/ECX-306I
FSM-327
Fox
The turnover temperature in Table 7 describes the temperature
where the apex of the of the drift vs temperature curve occurs.
This curve is parabolic with the drift increasing as (T - T0)2. For
an Epson MC-405 device, for example, the turnover
temperature is typically +25°C, and a peak drift of >110ppm
occurs at the temperature extremes of -40°C and +85°C. It is
possible to address this variable drift by adjusting the load
capacitance of the crystal, which will result in predictable
change to the crystal frequency. The Intersil RTC family allows
this adjustment over temperature since the devices include on-
chip load capacitor trimming. This control is handled by the
Analog Trimming Register, or ATR, which has 6-bits of control.
The load capacitance range covered by the ATR circuit is
approximately 3.25pF to 18.75pF, in 0.25pF increments. Note
that actual capacitance would also include about 2pF of
package related capacitance. In-circuit tests with commercially
available crystals demonstrate that this range of capacitance
allows frequency control from +80ppm to -34ppm, using a
12.5pF load crystal.
U1
R5
X1
47k
FIGURE 23. SUGGESTED LAYOUT FOR INTERSIL 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 vicinity of the RTC device. A small
In addition to the analog compensation afforded by the
adjustable load capacitance, a digital compensation feature is
available for the Intersil RTC family. There are 3-bits known as
the Digital Trimming Register or DTR, and they operate by
adding or skipping pulses in the clock signal. The range
provided is ±30ppm in increments of 10ppm. The default
setting is 0ppm. The DTR control can be used for coarse
adjustments of frequency drift over-temperature or for crystal
initial accuracy correction.
decoupling capacitor at the V
pin of the chip is mandatory,
DD
with a solid connection to ground.
The ISL12026 product has a special consideration. The
IRQ/F - pin on the 8 Ld SOIC package is located next to the
X2 pin. When this pin is used as a frequency output (IRQ/
) and is set to 32.768kHz, noise can couple to the X1 or
OUT
F
OUT
X2 pins and cause double-clocking. The layout in Figure 23
minimizes this by running the IRQ/F output away from the
OUT
A final application for the ATR control is in-circuit calibration for
high accuracy applications, along with a temperature sensor
chip. Once the RTC circuit is powered up with battery backup,
X1 and X2 pins. Also, reducing the switching current at this pin
by careful selection of the pull-up resistor value will reduce
noise. Intersil suggests a minimum value of 5.1k for
the IRQ/F
output is set at 32.768kHz and frequency drift is
OUT
32.768kHz, and higher values (up to 20k) for lower frequency
measured. 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 overall temperature drift is possible with this
method. The Intersil evaluation board contains the circuitry
necessary to implement this control.
IRQ/F
outputs.
OUT
For other RTC products, the same rules previously stated
should be observed, but slightly adjusted since the
packages and pinouts are different.
Oscillator Measurements
When a proper crystal is selected and the layout guidelines
above are observed, the oscillator should start-up in most
FN8231 Rev 9.00
November 30, 2010
Page 20 of 24
ISL12026, ISL12026A
circuits in less than one second. Some circuits may take
slightly longer, but start-up should definitely occur in less than
5 seconds. When testing RTC circuits, 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 usable
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 oscillating. The X2 output is sensitive to capacitive
impedance so the voltage levels and the frequency will be
affected by the parasitic elements in the scope probe. Applying
a scope probe can possibly cause a faulty oscillator to start up,
hiding other issues (although in the Intersil RTCs, the internal
circuitry assures start-up when using the proper crystal and
layout).
V
V
BAT
2.7V TO 5.5V
DD
SUPERCAP
V
SS
FIGURE 24. SUPERCAPACITOR CHARGING CIRCUIT
Alarm Operation Examples
Following are examples of both Single Event and periodic
Interrupt Mode alarms.
EXAMPLE 1
Alarm 0 set with single interrupt (IM = ”0”)
A single alarm will occur on January 1 at 11:30am.
A. Set Alarm 0 registers as follows:
The best way to analyze the RTC circuit is to power it up and
read the real time clock as time advances, or if the chip has the
IRQ/F
output, look at the output of that pin on an
OUT
oscilloscope (after enabling it with the control register, and
using a pull-up resistor for an open-drain output). Alternatively,
BIT
ALARM0
REGISTER 7
6
0
0
5
0
1
4
0
1
3
0
0
2
0
0
1
0
0
0
0
0
HEX
DESCRIPTION
the ISL12026 device has an IRQ/F
output, which can be
OUT
SCA0
MNA0
0
1
00h Seconds disabled
checked by setting an alarm for each minute. Using the pulse
interrupt mode setting, the once-per-minute interrupt functions
as an indication of proper oscillation.
B0h Minutes set to 30,
enabled
HRA0
DTA0
MOA0
DWA0
1
1
1
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
0
91h Hours set to 11,
enabled
Backup Battery Operation
Many types of batteries can be used with the Intersil RTC
products. 3.0V or 3.6V Lithium batteries are appropriate, and
sizes are available that can power a Intersil RTC device for up
to 10 years. Another option is to use a SuperCap for
81h Date set to 1,
enabled
81h Month set to 1,
enabled
applications where V
may disappear intermittently for short
DD
00h Day of week
disabled
periods of time. Depending on the value of SuperCap used,
backup time can last from a few days to two weeks (with >1F).
A simple silicon or Schottky barrier diode can be used in series
B. Also the AL0E bit must be set as follows:
with V to charge the SuperCap, which is connected to the
DD
V
pin. Try to use Schottky diodes with very low leakages,
BAT
BIT
<1µA desirable. Do not use the diode to charge a battery
(especially lithium batteries!)
CONTROL
REGISTER
7
6
5
4
3
2
1
0
HEX DESCRIPTION
There are two possible modes for battery backup operation;
Standard and Legacy mode. In Standard mode, there are no
operational concerns when switching over to battery backup
since all other devices functions are disabled. Battery drain is
INT
0
0
1
0
0
0
0
0
x0h Enable Alarm
After these registers are set, an alarm will be generated when the
RTC advances to exactly 11:30am on January 1 (after seconds
changes from 59 to 00) by setting the AL0 bit in the status register
minimal in Standard mode, and return to Normal V powered
DD
operations is predictable. In Legacy mode, the V
pin can
BAT
to “1” and also bringing the IRQ/F
output low.
OUT
power the chip if the voltage is above V and less than V
DD
.
TRIP
EXAMPLE 2
In this mode, it is possible to generate the alarm and
Pulsed interrupt once per minute (IM = ”1”)
communicate with the device, unless SBI = 1, but the supply
current drain is much higher than the Standard mode and
backup time is reduced. In this case, if alarms are used in
Interrupts at one minute intervals when the seconds register is
at 30 seconds.
backup mode, the IRQ/F
pull-up resistor must be
OUT
A. Set Alarm 0 registers as follows:
B. Set the Interrupt register as follows:
connected to V
voltage source.
BAT
FN8231 Rev 9.00
November 30, 2010
Page 21 of 24
ISL12026, ISL12026A
• Mode A - In this mode, selection bits indicate a Standard
BIT
Mode switchover combined with I2C operation in battery
ALARM0
REGISTER 7
6
5
4
3
2
1
0 HEX
DESCRIPTION
backup mode. When the V voltage drops below the lower
DD
of V
or V , then the device will enter battery backup
TRIP
BAT
SCA0
1
0
1
1
0
0
0
0
B0h Seconds set to 30,
enabled
mode. If the microcontroller and bus pull-ups are also
powered by the battery, then the ISL12026 can communicate
in battery backup mode.
MNA0
HRA0
DTA0
MOA0
DWA0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
00h Minutes disabled
00h Hours disabled
00h Date disabled
• Mode B - In this mode, selection bits indicate Legacy mode
switchover combined with I2C operation in battery backup
mode. When the V voltage drops below V , the device
will enter battery backup mode. If the microcontroller and bus
pull-ups are also powered by the battery, then the ISL12026
can communicate in battery backup mode. This mode places
the ISL12026 device in the same operating mode as the
X1226 legacy device.
DD
BAT
00h Month disabled
00h Day of week disabled
BIT
CONTROL
REGISTER 7
6
5
4
3
2
1
0 HEX
DESCRIPTION
• Mode C - This mode combines Standard mode battery
switchover with no I2C operation in battery backup mode.
When the V
INT
1
0
1
0
0
0
0
0
x0h Enable Alarm and Int
Mode
voltage drops below the lower of V
or
DD
TRIP
V
, then the device will enter battery backup mode and the
BAT
I2C interface will be disabled, minimizing V
current drain.
Once the registers are set, the following waveform will be seen
at IRQ/F
BAT
:
OUT
• Mode D - This mode combines Legacy mode battery
switchover with no I2C operation in battery backup mode.
RTC AND ALARM REGISTERS ARE BOTH “30” SEC
When the V
voltage drops below V , the device will
DD
BAT
enter battery backup mode and the I2C interface will be
disabled, minimizing V current drain.
BAT
Note that the IRQ/F
open drain output pin is active in
OUT
battery backup for all modes, allowing clocking of devices while
in battery backup mode. The pull-up on the pin will need to go
60s
Note that the status register AL0 bit will be set each time the
alarm is triggered, but does not need to be read or cleared.
to V , and thus battery mode current draw will increase
BAT
accordingly.
I2C Communications During Battery Backup
Operation in Battery Backup mode is affected by the BSW and
SBIB bits as described earlier. These bits allow flexible
operation of the serial bus and EEPROM in battery backup
mode, but certain operational details need to be clear before
utilizing the different modes. Table 9 describes 4 different
modes possible with using the BSW and SBIB bits, and how
they are affect the serial interface and battery backup
operation.
TABLE 9.
I2CACTIVEIN EE PROM WRITE/
V
BAT
SWITCHOVER
VOLTAGE
BATTERY READINBATTERY
FREQ/IRQ
ACTIVE?
MODE
SBIB BIT BSW BIT
BACKUP?
BACKUP?
NOTES
A
0
0
Standard Mode,
Yes
NO
YES, needs
pull-up to V
V
V
switchover at lower of V
or
BAT
BAT
V
= 2.2V typ
. Pull-ups needed on I2C to
TRIP
BAT TRIP
V
to operate in Battery Backup.
BAT
B (X1226
Mode)
0
1
Legacy Mode,
< V
Yes
NO
YES, needs
pull-up to V
V
switchover at <V . Pull-ups
DD
BAT
V
needed on I2C to V
Battery Backup.
to operate in
DD
BAT
BAT
BAT
C
D
1
1
0
1
Standard Mode,
= 2.2V typ
NO
NO
NO
NO
YES, needs
pull-up to V
V
switchover at lower of V
V .
BAT TRIP
or
BAT
BAT
V
TRIP
Legacy Mode,
< V
YES, needs
pull-up to V
BAT
V
switchover at <V
.
DD
BAT
V
DD
BAT
FN8231 Rev 9.00
November 30, 2010
Page 22 of 24
ISL12026, ISL12026A
Small Outline Plastic Packages (SOIC)
M8.15 (JEDEC MS-012-AA ISSUE C)
N
8 LEAD NARROW BODY SMALL OUTLINE PLASTIC PACKAGE
INDEX
AREA
0.25(0.010)
M
B M
H
INCHES
MILLIMETERS
E
SYMBOL
MIN
MAX
MIN
1.35
0.10
0.33
0.19
4.80
3.80
MAX
1.75
0.25
0.51
0.25
5.00
4.00
NOTES
-B-
A
A1
B
C
D
E
e
0.0532
0.0040
0.013
0.0688
0.0098
0.020
-
-
1
2
3
L
9
SEATING PLANE
A
0.0075
0.1890
0.1497
0.0098
0.1968
0.1574
-
-A-
3
h x 45°
D
4
-C-
0.050 BSC
1.27 BSC
-
H
h
0.2284
0.0099
0.016
0.2440
0.0196
0.050
5.80
0.25
0.40
6.20
0.50
1.27
-
e
A1
C
5
B
0.10(0.004)
L
6
0.25(0.010) M
C
A M B S
N
8
8
7
NOTES:
0°
8°
0°
8°
-
1. Symbols are defined in the “MO Series Symbol List” in Section 2.2 of
Publication Number 95.
Rev. 1 6/05
2. Dimensioning and tolerancing per ANSI Y14.5M-1982.
3. Dimension “D” does not include mold flash, protrusions or gate burrs.
Mold flash, protrusion and gate burrs shall not exceed 0.15mm (0.006
inch) per side.
4. Dimension “E” does not include interlead flash or protrusions. Inter-
lead flash and protrusions shall not exceed 0.25mm (0.010 inch) per
side.
5. The chamfer on the body is optional. If it is not present, a visual index
feature must be located within the crosshatched area.
6. “L” is the length of terminal for soldering to a substrate.
7. “N” is the number of terminal positions.
8. Terminal numbers are shown for reference only.
9. The lead width “B”, as measured 0.36mm (0.014 inch) or greater
above the seating plane, shall not exceed a maximum value of
0.61mm (0.024 inch).
10. Controlling dimension: MILLIMETER. Converted inch dimensions
are not necessarily exact.
© Copyright Intersil Americas LLC 2005-2010. All Rights Reserved.
All trademarks and registered trademarks are the property of their respective owners.
For additional products, see www.intersil.com/en/products.html
Intersil products are manufactured, assembled and tested utilizing ISO9001 quality systems as noted
in the quality certifications found at www.intersil.com/en/support/qualandreliability.html
Intersil products are sold by description only. Intersil may modify the circuit design and/or specifications of products at any time without notice, provided that such
modification does not, in Intersil's sole judgment, affect the form, fit or function of the product. Accordingly, the reader is cautioned to verify that datasheets are
current before placing orders. Information furnished by Intersil is believed to be accurate and reliable. However, no responsibility is assumed by Intersil or its
subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Intersil or its subsidiaries.
For information regarding Intersil Corporation and its products, see www.intersil.com
FN8231 Rev 9.00
November 30, 2010
Page 23 of 24
ISL12026, ISL12026A
Package Outline Drawing
M8.173
8 LEAD THIN SHRINK SMALL OUTLINE PACKAGE (TSSOP)
Rev 2, 01/10
A
2
4
3.0 ±0.5
SEE DETAIL "X"
8
5
6.40
C
4.40 ±0.10
L
3
4
PIN 1
ID MARK
1
4
0.20 CBA
B
0.09-0.20
0.65
TOP VIEW
END VIEW
1.00 REF
0.05
H
C
0.90 +0.15/-0.10
1.20 MAX
6
SEATING
PLANE
GAUGE
PLANE
0.25
0.25 +0.05/-0.06
0.10 C B A
0.10 C
0°-8°
0.60 ±0.15
0.05 MIN
0.15 MAX
DETAIL "X"
SIDE VIEW
(1.45)
NOTES:
1. Dimensions are in millimeters.
Dimensions in ( ) for Reference Only.
2. Dimension does not include mold flash, protrusions or
gate burrs. Mold flash, protrusions or gate burrs shall
not exceed 0.15 per side.
(5.65)
PACKAGE BODY
OUTLINE
3. Dimension does not include interlead flash or protrusion.
Interlead flash or protrusion shall not exceed 0.15 per side.
4. Dimensions are measured at datum plane H.
5. Dimensioning and tolerancing per ASME Y14.5M-1994.
6. Dimension on lead width does not include dambar protrusion.
Allowable protrusion shall be 0.08 mm total in excess of
dimension at maximum material condition. Minimum space
between protrusion and adjacent lead is 0.07mm.
(0.35 TYP)
(0.65 TYP)
TYPICAL RECOMMENDED LAND PATTERN
7. Conforms to JEDEC MO-153, variation AC. Issue E
FN8231 Rev 9.00
November 30, 2010
Page 24 of 24
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