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DS1486DALLASN/a331avaiRAMified Watchdog Timekeeper
DS1486DALLAS特价N/a50avaiRAMified Watchdog Timekeeper


DS1486 ,RAMified Watchdog TimekeeperFEATURES ORDERING INFORMATION TEMP PIN- TOP 128 kbytes of User NV RAM PART RANGE PACKAGE MARK* ..
DS1486 ,RAMified Watchdog Timekeeper DS1486/DS1486P RAMified Watchdog Timekeepers
DS1486-120 ,RAMified Watchdog TimekeeperDS1486/DS1486PRAMified Watchdog Timekeeper
DS1486-120 ,RAMified Watchdog TimekeeperFEATURES PIN ASSIGNMENT 128 kbytes of user NV RAMINTB (INTB)1 32 VCC Integrated NV SRAM, real-tim ..
DS1486-120+ ,RAMified Watchdog TimekeeperFEATURES ORDERING INFORMATION TEMP PIN- TOP 128 kbytes of User NV RAM PART RANGE PACKAGE MARK* ..
DS1486P-120 ,RAMified Watchdog TimekeeperFEATURES PIN ASSIGNMENT 128 kbytes of user NV RAMINTB (INTB)1 32 VCC Integrated NV SRAM, real-tim ..
DTC143ZET1 ,Bias Resistor TransistorELECTRICAL CHARACTERISTICS (T = 25°C unless otherwise noted)ACharacteristic Symbol Min Typ Max Unit ..
DTC143ZET1G ,Bias Resistor TransistorFeatures(OUTPUT)PIN 1R1• Simplifies Circuit DesignBASE(INPUT)• Reduces Board SpaceR2• Reduces Compo ..
DTC143ZKA T146 , NPN 100mA 50V Digital Transistors
DTC143ZKA T146 , NPN 100mA 50V Digital Transistors
DTC143ZKAT146 , NPN 100mA 50V Digital Transistors
DTC143ZKAT146 , NPN 100mA 50V Digital Transistors


DS1486
RAMified Watchdog Timekeeper
FEATURES
128 kbytes of User NV RAM
Integrated NV SRAM, Real-Time Clock,
Crystal, Power-Fail Control Circuit and
Lithium Energy Source
Totally Nonvolatile with Over 10 years of
Operation in the Absence of Power
Watchdog Timer Restarts an Out-of-Control
Processor
Alarm Function Schedules Real-Time-Related
Activities such as System Wakeup
Programmable Interrupts and Square-Wave
Output
All Registers are Individually Addressable
Through the Address and Data Bus
Interrupt Signals Active in Power-Down
Mode
PIN CONFIGURATIONS
ORDERING INFORMATION
PART TEMP
RANGE
PIN-
PACKAGE
TOP
MARK**
DS1486-120
0°C to
+70°C 32 EDIP (0.740”) DS1486-120
DS1486-120+ 0°C to
+70°C 32 EDIP (0.740”) DS1486-120
DS1486P-120
0°C to
+70°C 34 PowerCap®* DS1486P-
120
DS1486P-120+ 0°C to
+70°C 34 PowerCap* DS1486P-
120
DS9034PCX
0°C to
+70°C PowerCap DS9034PC
DS9034PCX+ 0°C to
+70°C PowerCap DS9034PC
*DS9034PCX PowerCap required (must be ordered separately).
**A ‘+’ indicates lead-free. The top mark will include a ‘+’ symbol
on lead-free devices.
PowerCap is a registered trademark of Dallas Semiconductor.
DS1486/DS1486P
RAMified Watchdog Timekeepers

INTB (INTB)
13
10
11
12
14
128k x 8
32-Pin Encapsulated Package
(32 PIN 740)

A14
DQ1
DQ0
VCC
A15
INTA/SQW
WE
A13
A8
A9
A11
OE
A10
CE
DQ7
DQ5
DQ6
A16
A12
DQ2
GND
15
16
DQ4
DQ3
DS1486
341 INTB(INTB)2 3 A15A16PFOVCC
WEOECEDQ7
DQ6DQ5
DQ4
DQ3DQ2
DQ1DQ0
GND6 8 9
10 11
12 13
14 15
16
17
SQW
A14
32 31302827 2522 19
A13A12A11
A10A8A5A3A0
INTA
X1 GNDVBAT X2
34-Pin PowerCap Module Board
(Uses DS9034PCX PowerCap)
DS1486P

TOPVIEW
DS1486/DS1486P
PIN DESCRIPTION
PIN
PDIP PowerCap NAME FUNCTION

1 1 INTB (INTB) Active-Low Interrupt B, Output, Push-Pull
2 3 A16
3 32 A14
4 30 A12
5 25 A7
6 24 A6
7 23 A5
8 22 A4
9 21 A3
10 20 A2
11 19 A1
12 18 A0
23 28 A10
25 29 A11
26 27 A9
27 26 A8
28 31 A13
31 2 A15
Address Input
13 16 DQ0
14 15 DQ1
15 14 DQ2
17 13 DQ3
18 12 DQ4
19 11 DQ5
20 10 DQ6
21 9 DQ7
Data Input/Output
16 17 GND Ground
22 8 CE Active-Low Chip Enable
24 7 OE Active-Low Output Enable
29 6 WE Active-Low Write Enable
30 — INTA/SQW
Active-Low, Interrupt A, Open-Drain Output and Square-Wave
Output, Shared. Note: Both functions must not be enabled at the same
time, or a conflict could occur.
32 5 VCC Power-Supply Input
— 4 PFO Active-Low Power-Fail Output, Open Drain. Requires a pullup
resistor for proper operation.
— 33 SQW Square-Wave Output
— 34 INTA Active-Low Interrupt A, Output, Open Drain. Requires a pullup
resistor for proper operation. X1, X2, VBAT Crystal Connections and Battery Connection
DS1486/DS1486P
DESCRIPTION

The DS1486 is a nonvolatile static RAM with a full-function real-time clock (RTC), alarm, watchdog
timer, and interval timer, which are all accessible in a byte-wide format. The DS1486 contains a lithium
energy source and a quartz crystal, which eliminate the need for any external circuitry. Data contained
within 128K by 8-bit memory and the timekeeping registers can be read or written in the same manner as
byte-wide static RAM. The timekeeping registers are located in the first 14 bytes of memory space. Data
is maintained in the RAMified timekeeper by intelligent control circuitry, which detects the status of VCC
and write-protects memory when VCC is out of tolerance. The lithium energy source can maintain data and
real time for over 10 years in the absence of VCC. Timekeeper information includes hundredths of
seconds, seconds, minutes, hours, day, date, month, and year. The date at the end of the month is
automatically adjusted for months with fewer than 31 days, including correction for leap year. The
RAMified timekeeper operates in either 24-hour or 12-hour format with an AM/PM indicator. The
watchdog timer provides alarm interrupts and interval timing between 0.01 seconds and 99.99 seconds.
The real time alarm provides for preset times of up to one week. Interrupts for both watchdog and RTC
will operate when the system is powered down. Either can provide system “wake-up” signals.
PACKAGES

The DS1486 is available in two packages: a 32-pin DIP module and 34-pin PowerCap module. The 32-
pin DIP-style module integrates the crystal, lithium energy source, and silicon all in one package. The 32-
pin PowerCap Module Board is designed with contacts for connection to a separate PowerCap
(DS90934PCX) that contains the crystal and battery. The design allows the PowerCap to be mounted on
top of the DS1486P after the completion of the surface mount process. Mounting the PowerCap after the
surface mount process prevents damage to the crystal and battery due to high temperatures required for
solder reflow. The PowerCap is keyed to prevent reverse insertion. The PowerCap Module Board and
PowerCap are ordered separately and shipped in separate containers. The part number for the PowerCap
is DS9034PCX.
Table 1. Truth Table
VCC
CE OE WE MODE DQ POWER
VIH X X Deselect High-Z Standby
X X X Deselect High-Z Standby
VIL X VIL Write Data In Active
VIL VIL VIH Read Data Out Active
5V 10%
VIL VIH VIH Read High-Z Active
<4.5V > VBAT X X X Deselect High-Z CMOS Standby

OPERATION—READ REGISTERS
The DS1486 executes a read cycle whenever WE (Write Enable) is inactive (High), CE (Chip Enable)
and OE (Output Enable) are active (Low). The unique address specified by the address inputs (A0–A16)
defines which of the registers is to be accessed. Valid data will be available to the eight data output
drivers within tACC (Access Time) after the last address input signal is stable, providing that CE and OE
access times are also satisfied. If OE and CE access times are not satisfied, then data access must be
measured from the latter occurring signal (CE or OE) and the limiting parameter is either tCO for CE or
tOE for OE rather than address access.
DS1486/DS1486P
OPERATION—WRITE REGISTERS

The DS1486 is in the write mode whenever the WE (Write Enable) and CE (Chip Enable) signals are in
the active (Low) state after the address inputs are stable. The latter occurring falling edge of CE or WE
will determine the start of the write cycle. The write cycle is terminated by the earlier rising edge of CE
or WE. All address inputs must be kept valid throughout the write cycle. WE must return to the high state
for a minimum recovery state (tWR) before another cycle can be initiated. Data must be valid on the data
bus with sufficient Data Set-Up (tDS) and Data Hold Time (tDH) with respect to the earlier rising edge of
CE or WE. The OE control signal should be kept inactive (High) during write cycles to avoid bus
contention. However, if the output bus has been enabled (CE and OE active), then WE will disable the
outputs in tODW from its falling edge.
DATA RETENTION

The RAMified Timekeeper provides full functional capability when VCC is greater than 4.5V. When VCC
falls below the power fail trip-point (VTP), the internal CE signal is forced high, blocking access (Write-
Protect). While in the data retention mode, all inputs are “don’t cares,” SQW and DQ0–DQ7 go to a high-
impedance state. The two interrupts INTA and INTB (INTB) and the internal clock and timers continue
to run regardless of the level of VCC. However, it is important to insure that the pull-up resistors used with
the interrupt pins are never pulled up to a value that is greater than VCC + 0.3V. As VCC falls below
approximately 3.0V, a power switching circuit turns the internal lithium energy source on to maintain the
clock and timer data functionality. It is also required to ensure that during this time (battery-backup
mode), that the voltage present at INTA and INTB (INTB) never exceeds VBAT. During power-up, when
VCC rises above VBAT, the power-switching circuit connects external VCC and disconnects the internal
lithium energy source. Normal operation can resume after VCC exceeds 4.5V for a period of 200ms.
RAMIFIED TIMEKEEPER REGISTERS

The RAMified timekeeper has 14 registers that are 8 bits wide that contain all the timekeeping, alarm,
watchdog, and control information. The clock, calendar, alarm, and watchdog registers are memory
locations that contain external (user-accessible) and internal copies of the data. The external copies are
independent of internal functions, except that they are updated periodically by the simultaneous transfer
of the incremented internal copy (see Figure 1). The Command Register bits are affected by both internal
and external functions. This register will be discussed later. Registers 0, 1, 2, 4, 6, 8, 9, and A contain
time-of-day and date information (see Figure 2). Time-of-day information is stored in BCD. Registers 3,
5, and 7 contain the Time-of-Day Alarm information. Time-of-Day Alarm information is stored in BCD.
Register B is the Command Register and information in this register is binary. Registers C and D are the
Watchdog Alarm Registers and information that is stored in these two registers is in BCD. Registers E
through 1FFFF are user bytes and can be used to maintain data at the user’s discretion.
CLOCK ACCURACY (DIP MODULE)

The DS1486 is guaranteed to keep time accuracy to within 1 minute per month at +25C.
CLOCK ACCURACY (PowerCap MODULE)

The DS1486P and DS9034PCX are each individually tested for accuracy. Once mounted together, the
module is guaranteed to keep time accuracy to within ±1.53 minutes per month (35ppm) at +25°C.
DS1486/DS1486P
Figure 1. Block Diagram

DS1486/DS1486P
TIME-OF-DAY REGISTERS

Registers 0, 1, 2, 4, 6, 8, 9, and A contain Time-of-Day data in BCD. Ten bits within these eight registers
are not used and will always read 0 regardless of how they are written. Bits 6 and 7 in the Months
Register (9) are binary bits. When set to logic 0, EOSC (Bit 7) enables the real-time clock oscillator. This
bit is set to logic 1 as shipped from Dallas Semiconductor to prevent lithium energy consumption during
storage and shipment (DIP Module only). This bit will normally be turned on by the user during device
initialization. However, the oscillator can be turned on and off as necessary by setting this bit to the
appropriate level. The INTA and Square Wave Output signals are tied together at pin 30 on the 32-pin
DIP module. With this package, ESQW (Bit 6) of the Months Register (9) controls the function of this
pin. When set to logic 0, the pin will output a 1024 Hz square wave signal. When set to logic 1, the pin is
available for interrupt A output (INTA) only. The INTA and Square Wave Output signals are separated
on the 34-pin PowerCap module. With this package, ESQW controls only the Square Wave Output (pin
33). When set to logic 0, pin 33 will output a 1024 Hz square wave signal. When set to logic 1, pin 33 is
in a high impedance state. Pin 34 (INTA) is not affected by the setting of bit 6. Bit 6 of the Hours register
is defined as the 12- or 24-hour select bit. When set to logic 1, the 12-hour format is selected. In the 12-
hour format, bit 5 is the AM/PM bit with logic 1 being PM. In the 24-hour mode, bit 5 is the second 10-
hour bit (20-23 hours). The Time-of-Day registers are updated every 0.01 seconds from the real-time
clock, except when the TE bit (bit 7 of Register B) is set low or the clock oscillator is not running. The
preferred method of synchronizing data access to and from the RAMified Timekeeper is to access the
Command register by doing a write cycle to address location B and setting the TE bit (Transfer Enable
bit) to a logic 0. This will freeze the External Time-of-Day registers at the present recorded time,
allowing access to occur without danger of simultaneous update. When the watch registers have been read
or written, a second write cycle to location B setting the TE bit to a logic 1 will put the Time-of-Day
Registers back to being updated every 0.01 second. No time is lost in the real-time clock because the
internal copy of the Time-of-Day register buffers is continually incremented while the external memory
registers are frozen. An alternate method of reading and writing the Time-of-Day registers is to ignore
synchronization. However, any single reading may give erroneous data as the real-time clock may be in
the process of updating the external memory registers as data is being read. The internal copies of seconds
through years are incremented and the Time-of-Day Alarm is checked during the period that hundreds of
seconds reads 99. The copies are transferred to the external register when hundredths of seconds roll from
99 to 00. A way of making sure data is valid is to do multiple reads and compare. Writing the registers
can also produce erroneous results for the same reasons. A way of making sure that the write cycle has
caused a proper update is to perform read verifies and re-execute the write cycle if data is not correct.
While the possibility of erroneous results from read and write cycles has been stated, it is worth noting
that the probability of an incorrect result is kept to a minimum due to the redundant structure of the
RAMified Timekeeper.
TIME-OF-DAY ALARM REGISTERS

Registers 3, 5, and 7 contain the Time-of-Day Alarm Registers. Bits 3, 4, 5, and 6 of Register 7 will
always read 0 regardless of how they are written. Bit 7 of Registers 3, 5, and 7 are mask bits (Figure 3).
When all of the mask bits are logic 0, a Time-of-Day Alarm will only occur when Registers 2, 4, and 6
match the values stored in Registers 3, 5, and 7. An alarm will be generated every day when bit 7 of
Register 7 is set to a logic 1. Similarly, an alarm is generated every hour when bit 7 of Registers 7 and 5
is set to a logic 1. When bit 7 of Registers 7, 5, and 3 is set to a logic 1, an alarm will occur every minute
when Register 1 (seconds) rolls from 59 to 00.
Time-of-Day Alarm Registers are written and read in the same format as the Time-of-Day Registers. The
DS1486/DS1486P
WATCHDOG ALARM REGISTERS

Registers C and D contain the time for the Watchdog Alarm. The two registers contain a time count from
00.01 to 99.99 seconds in BCD. The value written into the Watchdog Alarm Registers can be written or
read in any order. Any access to Register C or D will cause the Watchdog Alarm to reinitialize and clears
the Watchdog Flag bit and the Watchdog Interrupt Output. When a new value is entered or the Watchdog
Registers are read, the Watchdog Timer will start counting down from the entered value to 0. When 0 is
reached, the Watchdog Interrupt Output will go to the active state. The Watchdog Timer Countdown is
interrupted and reinitialized back to the entered value every time either of the registers is accessed. In this
manner, controlled periodic accesses to the Watchdog Timer can prevent the Watchdog Alarm from
going to an active level. If access does not occur, countdown alarm will be repetitive. The Watchdog
Alarm Registers always read the entered value. The actual countdown register is internal and is not
readable. Writing registers C and D to 0 will disable the Watchdog Alarm feature.
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