XICOR X40421S14I-B

New Features
•
•
•
•
Monitor Voltages: 5V to 1.6V
Memory Security
Battery Switch Backup
VOUT 5mA to 50mA
Preliminary Datasheet
X40420/X40421
4kbit EEPROM
Dual Voltage Monitor with Integrated CPU Supervisor and System Battery Switch
R
Y
APPLICATIONS
• Communications Equipment
—Routers, Hubs, Switches
—Disk arrays
• Industrial Systems
—Process Control
—Intelligent Instrumentation
• Computer Systems
—Desktop Computers
—Network Servers
X40420/21
IN
A
Standard VTRIP1 Level Standard VTRIP2 Level Suffix
4.6V (+/-1%)
2.9V(+/-1.7%)
-A
4.6V (+/-1%)
2.6V (+/-2%)
-B
2.9V(+/-1.7%)
1.6V (+/-3%)
-C
See “Ordering Information” for more details
For Custom Settings, call Xicor.
DESCRIPTION
PR
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FEATURES
• Dual voltage detection and reset assertion
—Three standard reset threshold settings
(4.6V/2.9V, 4.6V/2.6V, 2.9V/1.6V)
—VTRIP2 Programmable down to 0.9V
—Adjust low voltage reset threshold voltages
using special programming sequence
—Reset signal valid to VCC = 1V
—Monitor two voltages or detect power fail
• Battery Switch Backup
• VOUT: 5mA to 50mA from VCC; or 250µA from
VBATT
• Fault detection register
• Selectable power on reset timeout
(0.05s, 0.2s, 0.4s, 0.8s)
• Selectable watchdog timer interval
(25ms, 200ms, 1.4s, off)
• Debounced manual reset input
• Low power CMOS
—25µA typical standby current, watchdog on
—6µA typical standby current, watchdog off
—1µA typical battery current in backup mode
• 4Kbits of EEPROM
—16 byte page write mode
—Self-timed write cycle
—5ms write cycle time (typical)
• Built-in inadvertent write protection
—Power-up/power-down protection circuitry
—Block lock protect 0 or 1/2, of EEPROM
• 400kHz 2-wire interface
• 2.7V to 5.5V power supply operation
• Available packages
—14-lead SOIC, TSSOP
The X40420/21 combines power-on reset control,
watchdog timer, supply voltage supervision, and secondary supervision, manual reset, and Block Lock™
protect serial EEPROM in one package. This combination lowers system cost, reduces board space requirements, and increases reliability.
Applying voltage to VCC activates the power on reset
circuit which holds RESET/RESET active for a period of
time. This allows the power supply and system oscillator
to stabilize before the processor can execute code.
BLOCK DIAGRAM
VOUT
+
V2MON
SDA
WP
SCL
V2 Monitor
Logic
V2FAIL
VTRIP2
-
Fault Detection
Register
Data
Register
VBATT
REV 1.2.14 7/12/02
VOUT
EEPROM
Array
+
VCC
(V1MON)
WDO
Status
Register
Command
Decode Test
& Control
Logic
VOUT
BATT-ON
VOUT
Watchdog
and
Reset Logic
VCC Monitor
Logic
VTRIP1
-
System
Battery
Switch
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MR
RESET
X40420
Power on,
Manual Reset
Low Voltage
Reset
Generation
RESET
X40421
LOWLINE
Characteristics subject to change without notice.
1 of 25
X40420/X40421 – Preliminary
Y
The device utilizes Xicor’s proprietary Direct Write™
cell, providing a minimum endurance of 100,000 cycles
and a minimum data retention of 100 years.
Example Application
Unreg.
Supply
5V
REG
IN
A battery switch circuit compares VCC with VBATT input
and connects VOUT to whichever is higher. This provides voltage to external SRAM or other circuits in the
event of main power failure. The X40420/21 can drive
50mA from VCC to 250µA from VBATT. The device only
switches to VBATT when VCC drops below the low VCC
voltage threshold and VBATT.
The memory portion of the device is a CMOS Serial
EEPROM array with Xicor’s Block Lock protection. The
array is internally organized as x 8. The device features
an 2-wire interface and software protocol allowing
operation on a two-wire bus.
R
A manual reset input provides debounce circuitry for
minimum reset component count.
selected, the interval does not change, even after
cycling the power.
A
Low VCC detection circuitry protects the user’s system
from low voltage conditions, resetting the system when
VCC falls below the minimum VTRIP1 point. RESET/
RESET is active until VCC returns to proper operating
level and stabilizes. A second voltage monitor circuit
tracks the unregulated supply to provide a power fail
warning or monitors different power supply voltage.
Three common low voltage combinations are available,
however, Xicor’s unique circuits allows the threshold for
either voltage monitor to be reprogrammed to meet
special needs or to fine-tune the threshold for applications requiring higher precision.
14
13
12
11
10
9
8
Addr
X40420/21
Addr
V2MON
uC
V2FAIL
VDO
RESET
MR
SCL SDA
IM
EL
PR
1
2
3
4
5
6
7
Enable
SRAM
VOUT
NMI
VCC
IRQ
RESET
Manual
Reset
I2C
X40421
14-Pin SOIC, TSSOP
X40420
14-Pin SOIC, TSSOP
V2FAIL
V2MON
LOWLINE
WDO
MR
RESET
VSS
VBATT
+
The Watchdog Timer provides an independent protection mechanism for microcontrollers. When the microcontroller fails to restart a timer within a selectable time
out interval, the device activates the WDO signal. The
user selects the interval from three preset values. Once
PIN CONFIGURATION
BATT-ON
VCC
VCC
BATT-ON
VOUT
VBATT
WP
SCL
SDA
V2FAIL
V2MON
LOWLINE
WDO
MR
RESET
VSS
1
2
3
4
5
6
7
14
13
12
11
10
9
8
VCC
BATT-ON
VOUT
VBATT
WP
SCL
SDA
PIN DESCRIPTION
Pin
Name
Function
1
V2FAIL
V2 Voltage Fail Output. This open drain output goes LOW when V2MON is less than VTRIP2 and
goes HIGH when V2MON exceeds VTRIP2. There is no power up reset delay circuitry on this pin.
2
V2MON
V2 Voltage Monitor Input. When the V2MON input is less than the VTRIP2 voltage, V2FAIL goes
LOW. This input can monitor an unregulated power supply with an external resistor divider or can
monitor a second power supply with no external components. Connect V2MON to VSS or VCC
when not used.
3
LOWLINE
REV 1.2.14 7/12/02
Early Low VCC Detect. This open drain output signal goes LOW when VCC < VTRIP1.
When VCC > VTRIP1, this pin is pulled high with the use of an external pull up resistor.
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Characteristics subject to change without notice.
2 of 25
X40420/X40421 – Preliminary
PIN DESCRIPTION (Continued)
Name
Function
4
WDO
WDO Output. WDO is an active LOW, open drain output which goes active whenever the watchdog timer goes active.
5
MR
Manual Reset Input. Pulling the MR pin LOW initiates a system reset. The RESET/RESET pin will remain HIGH/LOW until the pin is released and for the tPURST thereafter. It has an internal pull up resistor.
6
RESET/
RESET
RESET Output. (X40421) This open drain pin is an active LOW output which goes LOW whenever
VCC falls below VTRIP1 voltage or if manual reset is asserted. This output stays active for the programmed time period (tPURST) on power up. It will also stay active until manual reset is released
and for tPURST thereafter.
RESET Output. (X40420) This pin is an active HIGH open drain output which goes HIGH whenever VCC falls below VTRIP1 voltage or if manual reset is asserted. This output stays active for the
programmed time period (tPURST) on power up. It will also stay active until manual reset is released
and for tPURST thereafter.
7
VSS
Ground
8
SDA
Serial Data. 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. This pin
requires a pull up resistor and the input buffer is always active (not gated).
Watchdog Input. A HIGH to LOW transition on the SDA (while SCL is toggled from HIGH to LOW
and followed by a stop condition) restarts the Watchdog timer. The absence of this transition within
the watchdog time out period results in WDO going active.
9
SCL
Serial Clock. The Serial Clock controls the serial bus timing for data input and output.
10
WP
Write Protect. WP HIGH prevents writes to any location in the device (including all the registers).
It has an internal pull down resistor. (>10MΩ typical)
11
VBATT
Battery Supply Voltage. This input provides a backup supply in the event of a failure of the
primary VCC voltage. The VBATT voltage typically provides the supply voltage necessary to
maintain the contents of SRAM and also powers the internal logic to “stay awake.” If the battery is
not used, connect VBATT to ground.
12
VOUT
Output Voltage. (V)
VOUT = VCC if VCC > VTRIP1.
IF VCC < VTRIP1
then VOUT = VCC if VCC > VBATT + 0.03V
else VOUT = VBATT (ie if VCC < VBATT – 0.03V)
Note: There is hysteresis around VBATT ± 0.03V point to avoid oscillation at or near the
switchover voltage. A capacitance of 0.1µF must be connected to VOUT to ensure stability.
13
BATT-ON
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IN
A
R
Y
Pin
Battery On. This CMOS output goes HIGH when the VOUT switches to VBATT and goes LOW
when VOUT switches to VCC. It is used to drive an external PNP pass transistor when VCC = VOUT
and current requirements are greater than 50mA.
The purpose of this output is to drive an external transistor to get higher operating currents when
the VCC supply is fully functional. In the event of a VCC failure, the battery voltage is applied to the
VOUT pin and the external transistor is turned off. In this “backup condition,” the battery only needs
to supply enough voltage and current to keep SRAM devices from losing their data–there is no
communication at this time.
14
VCC
REV 1.2.14 7/12/02
Supply Voltage
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Characteristics subject to change without notice.
3 of 25
X40420/X40421 – Preliminary
– It prevents the processor from operating prior to stabilization of the oscillator.
– It allows time for an FPGA to download its configuration prior to initialization of the circuit.
– It prevents communication to the EEPROM, greatly
reducing the likelihood of data corruption on power up.
V2MON voltage monitor is powered by VOUT. If VCC
and VBATT go away, V2MON cannot be monitored.
Figure 2. Two Uses of Multiple Voltage Monitoring
IN
When VCC exceeds the device VTRIP1 threshold value
for tPURST (selectable) the circuit releases the RESET
(X40421) and RESET (X40420) pin allowing the system
to begin operation.
Y
– It prevents the system microprocessor from starting
to operate with insufficient voltage.
R
Power On Reset
Applying power to the X40420/21 activates a Power On
Reset Circuit that pulls the RESET/RESET pins active.
This signal provides several benefits.
Low Voltage V2 Monitoring
The X40420/21 also monitors a second voltage level
and asserts V2FAIL if the voltage falls below a preset
minimum VTRIP2. The V2FAIL signal is either ORed
with RESET to prevent the microprocessor from operating in a power fail or brownout condition or used to
interrupt the microprocessor with notification of an
impending power failure. The V2FAIL signal remains
active until the VCC drops below 1V (VCC falling). It
also remains active until V2MON returns and exceeds
VTRIP2.
A
PRINCIPLES OF OPERATION
System
Reset
IM
X40420/21
RESET
MR
X40420
5V
Reg
Unreg.
Supply
R
Figure 1. Connecting a Manual Reset Push-Button
VOUT
EL
PR
REV 1.2.14 7/12/02
System
Reset
V2MON
V2FAIL
Resistors selected so 3V appears on V2MON when unregulated
supply reaches 6V.
VOUT
X40421
Unreg.
Supply
Low Voltage V1 Monitoring
During operation, the X40420/21 monitors the VCC
level and asserts RESET if supply voltage falls below a
preset minimum VTRIP1. The RESET signal prevents
the microprocessor from operating in a power fail or
brownout condition. The V1FAIL signal remains active
until the voltage drops below 1V. It also remains active
until VCC returns and exceeds VTRIP1 for tPURST.
RESET
R
Manual
Reset
Manual Reset
By connecting a push-button directly from MR to
ground, the designer adds manual system reset capability. The MR pin is LOW while the push-button is
closed and RESET/RESET pin remains LOW for
tPURST or till the push-button is released and for tPURST
thereafter. A weak pull up resistor is connected to the
MR pin.
VCC
5V
Reg
VCC
3V
Reg
V2MON
RESET
System
Reset
V2FAIL
Notice: No external components required to monitor two voltages.
WATCHDOG TIMER
The Watchdog Timer circuit monitors the microprocessor activity by monitoring the SDA and SCL pins. A
standard read or write sequence to any slave address
byte restarts the watchdog timer and prevents the
WDO signal to go active. A minimum sequence to
reset the watchdog timer requires four microprocessor
instructions namely, a Start, Clock Low, Clock High and
Stop. The state of two nonvolatile control bits in the
Status Register determine the watchdog timer period.
The microprocessor can change these watchdog bits
by writing to the X40420/21 control register.
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Characteristics subject to change without notice.
4 of 25
X40420/X40421 – Preliminary
Figure 3. VTRIPX Set/Reset Conditions
VTRIPX
(X = 1, 2)
VCC/V2MON
VP
WDO
0
7
0
7
Y
7
0
SCL
SDA
Data Byte in order to program VTRIPx. The STOP bit
following a valid write operation initiates the programming
sequence. Pin WDO must then be brought LOW to
complete the operation.
Figure 4. Watchdog Restart
.6µs
A
1.3µs
SDA
WDT Reset
Stop
IM
V1 AND V2 THRESHOLD PROGRAM PROCEDURE
(OPTIONAL)
EL
The X40420/21 is shipped with standard V1 and V2
threshold (VTRIP1, VTRIP2) voltages. These values will not
change over normal operating and storage conditions.
However, in applications where the standard thresholds
are not exactly right, or if higher precision is needed in the
threshold value, the X40420 trip points may be adjusted.
The procedure is described below, and uses the application of a high voltage control signal.
CASE A
Now if the desired VTRIPX is greater than the VTRIPX
(actual), then add the difference between VTRIPX
(desired) – VTRIPX (actual) to the original VTRIPX desired.
This is your new VTRIPX that should be applied to
VXMON and the whole sequence should be repeated
again (see Figure 5).
CASE B
PR
Setting a VTRIPx Voltage (x=1, 2)
There are two procedures used to set the threshold voltages (VTRIPx), depending if the threshold voltage to be
stored is higher or lower than the present value. For
example, if the present VTRIPx is 2.9 V and the new
VTRIPx is 3.2 V, the new voltage can be stored directly
into the VTRIPx cell. If however, the new setting is to be
lower than the present setting, then it is necessary to
“reset” the VTRIPx voltage before setting the new value.
Setting a Higher VTRIPx Voltage (x=1, 2)
To set a VTRIPx threshold to a new voltage which is higher
than the present threshold, the user must apply the
desired VTRIPx threshold voltage to the corresponding
input pin (Vcc(V1MON) or V2MON). Then, a programming voltage (Vp) must be applied to the WDO pin before
a START condition is set up on SDA. Next, issue on the
SDA pin the Slave Address A0h, followed by the Byte
Address 01h for VTRIP1, and 09h for VTRIP2, and a 00h
REV 1.2.14 7/12/02
To check if the VTRIPX has been set, set VXMON to a
value slightly greater than VTRIPX (that was previously
set). Slowly ramp down VXMON and observe when the
corresponding outputs (LOWLINE and V2FAIL) switch.
The voltage at which this occurs is the VTRIPX (actual).
IN
SCL
Start
tWC
R
00h
A0h
Now if the VTRIPX (actual), is higher than the VTRIPX
(desired), perform the reset sequence as described in the
next section. The new VTRIPX voltage to be applied to
VXMON will now be: VTRIPX (desired) – (VTRIPX (actual)
– VTRIPX (desired)).
Note: 1. This operation does not corrupt the memory
array.
2. Set VCC = 5V, when VTRIP2 is being programmed
Setting a Lower VTRIPx Voltage (x=1, 2)
In order to set VTRIPx to a lower voltage than the
present value, then VTRIPx must first be “reset” according to the procedure described below. Once VTRIPx
has been “reset”, then VTRIPx can be set to the desired
voltage using the procedure described in “Setting a
Higher VTRIPx Voltage”.
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Characteristics subject to change without notice.
5 of 25
X40420/X40421 – Preliminary
Normal Operation
VCC > VTRIP1 &
VBATT = 0
Normal Operation without battery
backup capability
0 ≤ VCC ≤ VTRIP1
and VCC < VBATT
Battery Backup mode; RESET
signal is asserted. No communication to the device is allowed.
Control Register
The Control Register provides the user a mechanism for
changing the Block Lock and Watchdog Timer settings.
The Block Lock and Watchdog Timer bits are nonvolatile
and do not change when power is removed.
The Control Register is accessed with a special preamble
in the slave byte (1011) and is located at address 1FFh. It
can only be modified by performing a byte write operation
directly to the address of the register and only one data
byte is allowed for each register write operation. Prior to
writing to the Control Register, the WEL and RWEL bits
must be set using a two step process, with the whole
sequence requiring 3 steps. See "Writing to the Control
Registers" on page 8.
EL
IM
IN
System Battery Switch
As long as VCC exceeds the low voltage detect threshold
VTRIP, VOUT is connected to VCC through a 5 Ohm (typical) switch. When the VCC has fallen below V1TRIP, then
VCC is applied to VOUT if VCC is or equal to or greater
than VBATT – 0.03V. When VCC drops to less than VBATT
– 0.03V, then VOUT is connected to VBATT through an 80
Ohm (typical) switch. VOUT typically supplies the system
static RAM voltage, so the switchover circuit operates to
protect the contents of the static RAM during a power failure. Typically, when VCC has failed, the SRAMs go into a
lower power state and draw much less current than in
their active mode. When VCC returns, VOUT switches
back to VCC when VCC exceeds VBATT + 0.03V. There is
a 60mV hysteresis around this battery switch threshold to
prevent oscillations between supplies.
VCC > VTRIP1
Y
Note: This operation does not corrupt the memory array.
Mode of Operation
R
After being reset, the value of VTRIPx becomes a nominal
value of 1.7V or lesser.
Condition
A
Resetting the VTRIPx Voltage
To reset a VTRIPx voltage, apply the programming voltage
(Vp) to the WDO pin before a START condition is set up
on SDA. Next, issue on the SDA pin the Slave Address
A0h followed by the Byte Address 03h for VTRIP1 and
0Bh for VTRIP2, followed by 00h for the Data Byte in order
to reset VTRIPx. The STOP bit following a valid write operation initiates the programming sequence. Pin WDO must
then be brought LOW to complete the operation.
PR
While VCC is connected to VOUT the BATT-ON pin is
pulled LOW. The signal can drive an external PNP transistor to provide additional current to the external circuits
during normal operation.
Operation
The device is in normal operation with VCC as long as
VCC > VTRIP1. It switches to the battery backup mode
when VCC goes away.
The user must issue a stop, after sending this byte to the
register, to initiate the nonvolatile cycle that stores WD1,
WD0, PUP1, PUP0, and BP. The X40420 will not
acknowledge any data bytes written after the first byte is
entered.
The state of the Control Register can be read at any time
by performing a random read at address 01Fh, using the
special preamble. Only one byte is read by each register
read operation. The master should supply a stop condition to be consistent with the bus protocol, but a stop is
not required to end this operation.
7
6
PUP1 WD1
5
4
3
WD0
BP
0
2
1
0
RWEL WEL PUP0
RWEL: Register Write Enable Latch (Volatile)
The RWEL bit must be set to “1” prior to a write to the
Control Register.
Figure 5. Sample VTRIP Reset Circuit
VP
Adjust
V2FAIL
RESET
VTRIP1
Adj.
µC
14
6
13
X40420
2
9
7
VTRIP2
Adj.
REV 1.2.14 7/12/02
1
8
4.7K
Run
SCL
SDA
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Characteristics subject to change without notice.
6 of 25
X40420/X40421 – Preliminary
Figure 6. VTRIPX Set/Reset Sequence (X = 1, 2)
Vx = VCC, VxMON
Note: X = 1, 2
Let: MDE = Maximum Desired Error
VTRIPX Programming
Desired
VTRIPX<
Present Value
No
MDE+
Acceptable
Desired Value
YES
Y
Error Range
MDE–
Error = Actual - Desired
A
Set VX = desired VTRIPX
R
Execute
VTRIPX Reset Sequence
IN
Execute
Set Higher VX Sequence
New VX applied =
Old VX applied + | Error |
NO
Execute Reset VTRIPX
Sequence
IM
Apply VCC and Voltage
> Desired VTRIPX to VX
New VX applied =
Old VX applied - | Error |
Decrease VX
EL
Output Switches?
PR
Error < MDE–
YES
Actual VTRIPX Desired VTRIPX
| Error | < | MDE |
DONE
WEL: Write Enable Latch (Volatile)
The WEL bit controls the access to the memory and to
the Register 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 any address,
including any control registers will be ignored (no
acknowledge will be issued after the Data Byte). The
WEL bit is set by writing a “1” to the WEL bit and
zeroes to the other bits of the control register.
REV 1.2.14 7/12/02
Error > MDE+
Once set, WEL remains set until either it is reset to 0
(by writing a “0” to the WEL bit and zeroes to the other
bits of the control register) or until the part powers up
again. Writes to the WEL bit do not cause a high voltage write cycle, so the device is ready for the next
operation immediately after the stop condition.
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Characteristics subject to change without notice.
7 of 25
X40420/X40421 – Preliminary
0
None
None
1
100h – 1FFh (256 bytes)
Upper Half of
Memory Array
PUP1, PUP0: Power Up Bits (Nonvolatile)
The Power Up bits, PUP1 and PUP0, determine the
tPURST time delay. The nominal power up times are
shown in the following table.
PUP1
PUP0
Power on Reset Delay (tPURST)
0
0
50ms
0
1
200ms (default)
1
0
400ms
1
1
800ms
IN
IM
EL
WD0
0
0
0
1
200 milliseconds
1
0
25 milliseconds
1
1
disabled (factory default)
Watchdog Time Out Period
PR
1.4 seconds
Writing to the Control Registers
Changing any of the nonvolatile bits of the control and
trickle registers requires the following steps:
– Write a 02H to the Control 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).
– Write a 06H to the Control Register to set 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).
REV 1.2.14 7/12/02
– A read operation occurring between any of the previous operations will not interrupt the register write
operation.
– The RWEL bit cannot be reset without writing to the
nonvolatile control bits in the control register, power
cycling the device or attempting a write to a write
protected block.
WD1, WD0: Watchdog Timer Bits
The bits WD1 and WD0 control the period of the
Watchdog Timer. The options are shown below.
WD1
Y
Memory
Array Lock
R
Protected Addresses
(Size)
– Write a one byte value to the Control Register that
has all the control bits set to the desired state. The
Control register can be represented as qxys 001r in
binary, where xy are the WD bits, and st are the BP
bits and qr are the power up bits. This operation proceeded by a start and ended with a stop bit. Since
this is a nonvolatile write cycle it will take up to 10ms
to complete. The RWEL bit is reset by this cycle and
the sequence must be repeated to change the nonvolatile bits again. If bit 2 is set to ‘1’ in this third step
(qxys 011r) then the RWEL bit is set, but the WD1,
WD0, PUP1, PUP0, and BP bits remain unchanged.
Writing a second byte to the control register is not
allowed. Doing so aborts the write operation and
returns a NACK.
A
BP
BP: Block Protect Bit (Nonvolatile)
The Block Protect Bits BP determines which blocks of
the array are write protected. A write to a protected
block of memory is ignored. The block protect bit will
prevent write operations to half the array segment.
To illustrate, a sequence of writes to the device consisting of [02H, 06H, 02H] will reset all of the nonvolatile
bits in the Control Register to 0. A sequence of [02H,
06H, 06H] will leave the nonvolatile bits unchanged
and the RWEL bit remains set.
Note: 1. tPURST is set to 200ms as factory default.
2. Watchdog timer bits are shipped disabled.
Fault Detection Register (FDR)
The Fault Detection Register provides the user the status of what causes the system reset active. The Manual Reset Fail, Watchdog Timer Fail and Three Low
Voltage Fail bits are volatile
7
6
5
4
3
2
1
0
LV1F
LV2F
0
WDF
MRF
0
0
0
The FDR is accessed with a special preamble in the
slave byte (1011) and is located at address 0FFh. It
can only be modified by performing a byte write operation directly to the address of the register and only one
data byte is allowed for each register write operation.
There is no need to set the WEL or RWEL in the control register to access this fault detection register.
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Characteristics subject to change without notice.
8 of 25
X40420/X40421 – Preliminary
Figure 7. Valid Data Changes on the SDA Bus
SCL
SDA
R
Interface Conventions
The device supports a bidirectional bus oriented protocol. The protocol defines any device that sends data
onto the bus as a transmitter, and the receiving device
as the receiver. The device controlling the transfer is
called the master and the device being controlled is
called the slave. The master always initiates data
transfers, and provides the clock for both transmit and
receive operations. Therefore, the devices in this family
operate as slaves in all applications.
IM
IN
At power-up, the Fault Detection Register is defaulted
to all “0”. The system needs to initialize this register to
all “1” before the actual monitoring take place. In the
event of any one of the monitored sources failed. The
corresponding bits in the register will change from a “1”
to a “0” to indicate the failure. At this moment, the system should perform a read to the register and noted
the cause of the reset. After reading the register the
system should reset the register back to all “1” again.
The state of the Fault Detection Register can be read
at any time by performing a random read at address
0FFh, using the special preamble.
Data Stable
Y
Data Change
A
Data Stable
The FDR can be read by performing a random read at
0FFh address of the register at any time. Only one byte
of data is read by the register read operation.
EL
MRF, Manual Reset Fail Bit (Volatile)
The MRF bit will set to “0” when Manual Reset input
goes active.
PR
WDF, Watchdog Timer Fail Bit (Volatile)
The WDF bit will set to “0” when WDO goes active.
LV1F, Low VCC Reset Fail Bit (Volatile)
The LV1F bit will be set to “0” when VCC (V1MON) falls
below VTRIP1.
LV2F, Low V2MON Reset Fail Bit (Volatile)
The LV2F bit will be set to “0” when V2MON falls below
VTRIP2.
REV 1.2.14 7/12/02
Serial 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 7.
Serial Start Condition
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 8.
Serial Stop Condition
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 8.
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Characteristics subject to change without notice.
9 of 25
X40420/X40421 – Preliminary
Figure 8. Valid Start and Stop Conditions
SCL
SDA
Stop
R
detected. The master must then issue a stop condition
to return the device to Standby mode and place the
device into a known state.
A
Serial Write Operations
Byte Write
For a write operation, the device requires the Slave
Address Byte and a Word Address Byte. This gives the
master access to any one of the words in the array.
After receipt of the Word Address Byte, the device
responds with an acknowledge, and awaits the next
eight bits of data. After receiving the 8 bits of the Data
Byte, the device again responds with an acknowledge.
The master then terminates the transfer by generating
a stop condition, at which time the device begins the
internal write cycle to the nonvolatile memory. During
this 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 12.
IN
Serial 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
eight bits. During the ninth clock cycle, the receiver will
pull the SDA line LOW to acknowledge that it received
the eight bits of data. See Figure 9.
Y
Start
EL
IM
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 eight bit word. The device
will acknowledge all incoming data and address bytes,
except for the Slave Address Byte when the Device
Identifier and/or Select bits are incorrect.
PR
In the read mode, the device will transmit eight 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
A write to a protected block of memory will suppress
the acknowledge bit.
Figure 9. Acknowledge Response From Receiver
SCL from
Master
1
8
9
Data Output
from Transmitter
Data Output
from Receiver
Start
REV 1.2.14 7/12/02
Acknowledge
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Characteristics subject to change without notice.
10 of 25
X40420/X40421 – Preliminary
Figure 10. Byte Write Sequence
S
t
a
r
t
Signals from
the Master
Byte
Address
Slave
Address
SDA Bus
S
t
o
p
Data
0
A
C
K
A
R
This means that the master can write 16 bytes to the
page starting at any location on that page. If the master begins writing at location 10, and loads 12 bytes,
then the first 6 bytes are written to locations 10 through
15, and the last 6 bytes are written to locations 0
through 5. Afterwards, the address counter would point
to location 6 of the page that was just written. If the
master supplies more than 16 bytes of data, then new
data over-writes the previous data, one byte at a time.
IM
IN
Page Write
The device is capable of 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
an unlimited number of 8-bit bytes. After the receipt of
each byte, the device will respond with an acknowledge, and the address is internally incremented by
one. The page address remains constant. When the
counter reaches the end of the page, it “rolls over” and
goes back to ‘0’ on the same page.
A
C
K
Y
A
C
K
Signals from
the Slave
Figure 11. Page Write Operation
SDA Bus
1 0 1
PR
Signals from
the Slave
Slave
Address
EL
Signals from
the Master
S
t
a
r
t
0 0
(1 ≤ n ≤ 16)
Byte
Address
S
t
o
p
Data
(n)
Data
(1)
0
A
C
K
A
C
K
A
C
K
A
C
K
Figure 12. Writing 12 bytes to a 16-byte page starting at location 10.
6 Bytes
address
=5
6 Bytes
address pointer
ends here
Addr = 6
The master terminates the Data Byte loading by issuing
a stop condition, which causes the device to begin the
nonvolatile write cycle. As with the byte write operation,
REV 1.2.14 7/12/02
address
10
address
n-1
all inputs are disabled until completion of the internal
write cycle. See Figure 11 for the address, acknowledge, and data transfer sequence.
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Characteristics subject to change without notice.
11 of 25
X40420/X40421 – Preliminary
Byte Load Completed
by Issuing STOP.
Enter ACK Polling
Issue START
R
Y
Issue Slave Address
Byte (Read or Write)
ACK
Returned?
IM
IN
Acknowledge Polling
The disabling of the inputs during high voltage cycles
can be used to take advantage of the typical 5ms write
cycle time. Once the stop condition is issued to indicate the end of the master’s byte load operation, the
device initiates the internal high voltage cycle.
Acknowledge polling can be initiated immediately. To
do this, the master issues a start condition followed by
the Slave Address Byte for a write or read operation. If
the device is still busy with the high voltage cycle then
no ACK will be returned. If the device has completed
the write operation, an ACK will be returned and the
host can then proceed with the read or write operation.
See Figure 13.
Figure 13. Acknowledge Polling Sequence
A
Stops and Write Modes
Stop conditions that terminate write operations must
be sent by the master after sending at least 1 full data
byte plus the subsequent ACK signal. If a stop is
issued in the middle of a data byte, or before 1 full data
byte plus its associated ACK is sent, then the device
will reset itself without performing the write. The contents of the array will not be effected.
EL
PR
Upon receipt of the Slave Address Byte with the R/W
bit set to one, the device issues an acknowledge and
then transmits the eight bits of the Data Byte. The master terminates the read operation when it does not
respond with an acknowledge during the ninth clock
and then issues a stop condition. See Figure 14 for the
address, acknowledge, and data transfer sequence.
REV 1.2.14 7/12/02
NO
YES
High Voltage Cycle
Complete. Continue
Command Sequence?
Issue STOP
NO
YES
Continue Normal
Read or Write
Command Sequence
Serial Read Operations
Read operations are initiated in the same manner as
write operations with the exception that the R/W bit of
the Slave Address Byte is set to one. There are three
basic read operations: Current Address Reads, Random Reads, and Sequential Reads.
Current Address Read
Internally the device 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 address of the
address counter is undefined, requiring a read or write
operation for initialization.
Issue STOP
PROCEED
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.
Random Read
Random read operation allows the master to access any
memory location in the array. Prior to issuing the Slave
Address Byte with the R/W bit set to one, the master must
first perform a “dummy” write operation. The master
issues the start condition and the Slave Address Byte,
receives an acknowledge, then issues the Word Address
Bytes. After acknowledging receipts of the Word Address
Bytes, 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 eight bit word. The master terminates the
read operation by not responding with an acknowledge
and then issuing a stop condition. See Figure 15 for the
address, acknowledge, and data transfer sequence.
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Characteristics subject to change without notice.
12 of 25
X40420/X40421 – Preliminary
A similar operation called “Set Current Address” where
the device will perform this operation if a stop is issued
instead of the second start shown in Figure 15. The
device will go 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.
SERIAL DEVICE ADDRESSING
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.
General Purpose Memory Array Configuration
Memory Address Map
CR, Control Register, CR7: CR0
Address: 1FFhex
FDR, Fault DetectionRegister, FDR7: FDR0
Address: 0FFhex
R
Memory Address
A8:A0
000h
Y
General Purpose Memory Organization, A8:A0
Address: 00h to 1FFh
Lower 256 bytes
A
0FFh
100h
Upper 256 bytes
Block Protect Option
IN
1FFh
Slave Address Byte
Following a start condition, the master must output a
Slave Address Byte. This byte consists of several parts:
EL
IM
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 address 0000H and the device continues to output data for each acknowledge received. See Figure 17
for the acknowledge and data transfer sequence.
– a device type identifier that is always “1010” when
accessing the array and “1011” when accessing the
control register and fault detection register.
– two bits of “0”.
– one bit that becomes the MSB of the memory
address X4.
PR
– last bit of the slave command byte is a R/W bit. The
R/W bit of the Slave Address Byte defines the operation to be performed. When the R/W bit is a one, then
a read operation is selected. A zero selects a write
operation. See Figure 16.
Figure 14. Current Address Read Sequence
.
Signals from
the Master
SDA Bus
Signals from
the Slave
REV 1.2.14 7/12/02
S
t
a
r
t
Slave
Address
1 0 1
0 0
S
t
o
p
1
A
C
K
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Data
Characteristics subject to change without notice.
13 of 25
X40420/X40421 – Preliminary
Figure 15. Random Address Read Sequence
S
t
a
r
t
Signals from
the Master
SDA Bus
1 01
0 0
S
t
a
r
t
Byte
Address
Slave
Address
1
0
A
C
K
A
C
K
A
C
K
Figure 16. X40410/11 Addressing
0
0
1
1
0
1
0
0
0
0
Fault Detection Register
1
0
1
1
0
0
A8 R/W
1 R/W
0
R/W
Word Address
General Purpose Memory A7 A6 A5 A4 A3 A2 A1
Control Register
1
1
1
1
1
1
1
1
1
1
1
1
1
1
A0
1
1
IM
Fault Detection Register
A
1
1
IN
Control Register
R
Slave Byte
General Purpose Memory
Data
Y
Signals from
the Slave
S
t
o
p
Slave
Address
Word Address
The word address is either supplied by the master or
obtained from an internal counter.
EL
Operational Notes
The device powers-up in the following state:
Data Protection
The following circuitry has been included to prevent
inadvertent writes:
– The WEL bit must be set to allow write operations.
– The proper clock count and bit sequence is required
prior to the stop bit in order to start a nonvolatile write
cycle.
– The device is in the low power standby state.
PR
– The WEL bit is set to ‘0’. In this state it is not possible
to write to the device.
– SDA pin is the input mode.
– A three step sequence is required before writing into
the Control Register to change Watchdog Timer or
Block Lock settings.
– The WP pin, when held HIGH, prevents all writes to
the array and all the Register.
– RESET/RESET Signal is active for tPURST.
Figure 17. Sequential Read Sequence
Signals from
the Master
SDA Bus
Signals from
the Slave
Slave
Address
A
C
K
A
C
K
S
t
o
p
A
C
K
1
A
C
K
Data
(1)
Data
(2)
Data
(n-1)
Data
(n)
(n is any integer greater than 1)
REV 1.2.14 7/12/02
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Characteristics subject to change without notice.
14 of 25
X40420/X40421 – Preliminary
ABSOLUTE MAXIMUM RATINGS
COMMENT
Temperature under bias ................... –65°C to +135°C
Storage temperature ........................ –65°C to +150°C
Voltage on any pin with
respect to VSS ......................................–1.0V to +7V
D.C. output current ............................................... 5mA
Lead temperature (soldering, 10 seconds)........ 300°C
Stresses above those listed under “Absolute Maximum
Ratings” may cause permanent damage to the device.
This is a stress rating only; functional operation of the
device (at these or any other conditions above those
listed in the operational sections of this specification) is
not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
Temperature
Min.
Y
RECOMMENDED OPERATING CONDITIONS
Max.
0°C
70°C
Industrial
–40°C
+85°C
-A or -B
Monitored
Voltages*
2.7V to 5.5V
2.6 to 5.5V
2.7V to 5.5V
1.6V to 3.6V
A
-C
R
Commercial
Version Chip Supply Voltage
*See ordering Info
Symbol
(1)
IN
D.C. OPERATING CHARACTERISTICS
(Over the recommended operating conditions unless otherwise specified)
Parameter
Min.
Active Supply Current (VCC) Read
(Excludes IOUT)
ICC2(1)
Active Supply Current (VCC) Write Non
Volatile Memory (Excludes IOUT)
IM
ICC1
Standby Current (VCC) AC (WDT off)
ISB2(2)(7)
Standby Current (VCC) DC (WDT on)
EL
ISB1(1)(7)
IBATT1(3)(7) VBATT Current (Excludes IOUT)
Typ.(5)
Max.
Unit
Test Conditions
1.5
mA
3.0
mA
6
10
µA
VIL = VCC x 0.1
VIH = VCC x 0.9
fSCL, fSDA = 400kHz
25
30
µA
VSDA = VSCL = VCC
Others = GND or VCC
0.4
1
µA
VOUT = VCC
6
µA
VBATT = 2.8V
VOUT = Open
VIL = VCC x 0.1
VIH = VCC x 0.9,
fSCL = 400kHz
VBATT Current (Excludes IOUT)
(Battery Backup Mode)
VOUT1(7)
Output Voltage (VCC > VBATT + 0.03V or
VCC > VTRIP1)
VCC–0.05V
VCC–0.5V
V
IOUT = 5mA (4.5–5.5V)
IOUT = 50mA (4.5–
5.5V)
VOUT2(7)
Output Voltage (VCC < VBATT – 0.03V and
VCC < VTRIP1) {Battery Backup}
VBATT–0.2
V
IOUT = 250µA
V
IOL = 3.0mA (4.5–5.5V)
V
IOH = -0.4mA (4.5–
5.5V)
PR
IBATT2(7)
VOLB
Output (BATT-ON) LOW Voltage
VOHB
Output (BATT-ON) HIGH Voltage
VBSH(7)
0.4
VOUT–0.8
30
-30
Battery Switch Hysteresis
(VCC < VTRIP1)
mV
Power Up
Power Down
ILI
Input Leakage Current (SCL, MR, WP)
10
µA
VIL = GND to VCC
ILO
Output Leakage Current (SDA, V2FAIL,
WDO, RESET)
10
µA
VSDA = GND to VCC
Device is in Standby(2)
VIL(3)
Input LOW Voltage (SDA, SCL, MR, WP)
-0.5
VCC x 0.3
V
(3)
Input HIGH Voltage (SDA, SCL, MR, WP)
VCC x 0.7
VCC + 0.5
V
VIH
REV 1.2.14 7/12/02
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Characteristics subject to change without notice.
15 of 25
X40420/X40421 – Preliminary
D.C. OPERATING CHARACTERISTICS (Continued)
(Over the recommended operating conditions unless otherwise specified)
Symbol
(7)
VHYS
VOL
Parameter
Typ.(5)
Min.
Schmitt Trigger Input Hysteresis
• Fixed input level
• VCC related level
Max.
0.2
.05 x VCC
0.4
Output LOW Voltage (SDA, RESET/
RESET, LOWLINE, V2FAIL, WDO)
2.85
2.9
VTRIP1 to LOWLINE
V2MON Reset Trip Point Voltage Range
0.9
(7)
VTRIP2 to V2FAIL
C Version
5
µS
3.5
V
2.95
A Version
2.55
2.6
2.65
B Version
1.55
1.6
1.65
C Version
5
µS
IM
tRPD2
2.95
A, B Version
2.9
IN
2.85
IOL = 3.0mA (2.7–5.5V)
IOL = 1.8mA (2.4–3.6V)
V
4.65
R
4.6
Second Supply Monitor
VTRIP2(6)
4.75
4.55
V
Y
2.0
A
tRPDL(7)
VCC Reset Trip Point Voltage Range
Test Conditions
V
V
VCC Supply
VTRIP1(6)
Unit
EL
Notes: (1) The device enters the Active state after any start, and remains active until: 9 clock cycles later if the Device Select Bits in the Slave
Address Byte are incorrect; 200ns after a stop ending a read operation; or tWC after a stop ending a write operation.
(2) The device goes into Standby: 200ns after any stop, except those that initiate a high voltage write cycle; tWC after a stop that initiates a high voltage cycle; or 9 clock cycles after any start that is not followed by the correct Device Select Bits in the Slave Address
Byte.
(3) Negative numbers indicate charging current, positive numbers indicate discharge current.
(4) VIL Min. and VIH Max. are for reference only and are not tested.
(5) At 25°C, VCC = 3V.
(6) See ordering information for standard programming levels. For custom programming levels, contact factory.
(7) Based on characterization data only.
∆V
PR
EQUIVALENT INPUT CIRCUIT FOR VxMON (x = 1, 2)
VREF
∆V = 100mV
R
VxMON
+
C
VREF
Output
–
tRPDX = 5µs worst case
REV 1.2.14 7/12/02
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Characteristics subject to change without notice.
16 of 25
X40420/X40421 – Preliminary
CAPACITANCE
Symbol
(1)
COUT
CIN(1)
Max.
Unit
Test Conditions
Output Capacitance (SDA, RESET, RESET/LOWLINE,
V2FAIL, WDO)
8
pF
VOUT = 0V
Input Capacitance (SCL, WP)
6
pF
VIN = 0V
(1) This parameter is not 100% tested.
Y
Note:
Parameter
WAVEFORM
4.6KΩ
4.6KΩ
2.06KΩ
RESET
WDO/LOWLINE
V2FAIL
30pF
30pF
30pF
A.C. TEST CONDITIONS)
IM
SDA
A
V2MON
IN
VOUT
5V
SYMBOL TABLE
R
EQUIVALENT A.C. OUTPUT LOAD CIRCUIT FOR
VCC = 5V
VCC x 0.1 to VCC x 0.9
Input rise and fall times
10ns
OUTPUTS
Must be
steady
Will be
steady
May change
from LOW
Will change
from LOW
to HIGH
May change
from HIGH
to LOW
Will change
from HIGH
to LOW
Don’t Care:
Changes
Allowed
Changing:
State Not
Known
N/A
Center Line
is High
Impedance
EL
Input pulse levels
INPUTS
VCC x 0.5
Output load
Standard output load
PR
Input and output timing levels
REV 1.2.14 7/12/02
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Characteristics subject to change without notice.
17 of 25
X40420/X40421 – Preliminary
A.C. CHARACTERISTICS
400kHz
Symbol
fSCL
Parameter
Min.
SCL Clock Frequency
Max.
Unit
400
kHz
tIN
Pulse width Suppression Time at inputs
50
tAA
SCL LOW to SDA Data Out Valid
0.1
tBUF
Time the bus free before start of new transmission
1.3
µs
tLOW
Clock LOW Time
1.3
µs
tHIGH
Clock HIGH Time
0.6
µs
0.6
µs
0.6
µs
100
ns
0
µs
0.6
µs
50
ns
tSU:DAT
Data In Setup Time
tHD:DAT
Data In Hold Time
tSU:STO
Stop Condition Setup Time
SDA and SCL Rise Time
tR
SDA and SCL Fall Time
tF
WP Setup Time
WP Hold Time
Cb
µs
20
+.1Cb(1)
300
ns
20
+.1Cb(1)
300
ns
IM
tSU:WP
tHD:WP
0.6
µs
0
µs
Capacitive load for each bus line
400
pF
(1) Cb = total capacitance of one bus line in pF.
TIMING DIAGRAMS
Bus Timing
EL
Note:
IN
Data Output Hold Time
tDH
0.9
Y
Start Condition Hold Time
R
Start Condition Setup Time
A
tSU:STA
tHD:STA
ns
tHIGH
SCL
PR
tF
tSU:STA
SDA IN
tHD:STA
tLOW
tR
tSU:DAT
tHD:DAT
tSU:STO
tAA
tDH
tBUF
SDA OUT
REV 1.2.14 7/12/02
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Characteristics subject to change without notice.
18 of 25
X40420/X40421 – Preliminary
WP Pin Timing
START
SCL
Clk 1
Clk 9
Slave Address Byte
SDA IN
tSU:WP
tHD:WP
Y
WP
R
Write Cycle Timing
IN
IM
Nonvolatile Write Cycle Timing
Symbol
Parameter
tWC(1)
Write Cycle Time
tWC
Stop
Condition
Min.
EL
Note:
ACK
8th Bit of Last Byte
SDA
A
SCL
Start
Condition
Typ.(1)
Max.
Unit
5
10
ms
(1) tWC is the time from a valid stop condition at the end of a write sequence to the end of the self-timed internal nonvolatile write cycle.
It is the minimum cycle time to be allowed for any nonvolatile write by the user, unless Acknowledge Polling is used.
PR
Power Fail Timings
VTRIPX
VCC or
tRPDL
tRPDL
tRPDX
tRPDL
tRPDX
V2MON
LOWLINE or
V2FAIL
tRPDX
tF
tR
VRVALID
X = 1, 2
REV 1.2.14 7/12/02
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Characteristics subject to change without notice.
19 of 25
X40420/X40421 – Preliminary
RESET/RESET/MR Timings
VTRIP1
VCC
tPURST
tPURST
tRPD1
tF
VRVALID
R
RESET
Y
tR
MR
A
RESET
IN
tMD
LOW VOLTAGE AND WATCHDOG TIMINGS PARAMETERS (@25°C, VCC = 5V)
Symbol
tRPD1
tRPDL
tLR(1)
(1)
Parameters
Min.
Typ.
VTRIP1 to RESET/RESET (Power down only)
VTRIP1 to LOWLINE
IM
(1)
LOWLINE to RESET/RESET delay (Power down only) [= tRPD1-tRPDL]
VTRIP2 to V2FAIL
tPURST
Power On Reset delay:
PUP1=0, PUP0=0
PUP1=0, PUP0=1 (factory default)
PUP1=1, PUP0=0
PUP1=1, PUP0=1
EL
tRPD2
Max.
Unit
5
µs
500
ns
5
50(1)
200
400(1)
800(1)
µs
tF
VCC, V2MON Fall Time
20
mV/µs
tR
PR
ms
ms
ms
ms
VCC, V2MON Rise Time
20
mV/µs
Reset Valid VCC
1
V
VRVALID
t MD
MR to RESET/ RESET delay (activation only)
500
ns
tin1
Pulse width Suppression Time for MR
50
ns
tWDO
Watchdog Timer Period:
WD1=0, WD0=0
WD1=0, WD0=1
WD1=1, WD0=0
WD1=1, WD0=1 (factory default)
tRST1
Watchdog Reset Time Out Delay
WD1=0, WD0=0
WD1=0, WD0=1
100
200
300
ms
tRST2
Watchdog Reset Time Out Delay WD1=1, WD0=0
12.5
25
37.5
ms
tRSP
Watchdog timer restart pulse width
Note:
1.4(1)
200(1)
25
OFF
s
ms
ms
1
µs
(1) Based on characterization data.
REV 1.2.14 7/12/02
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Characteristics subject to change without notice.
20 of 25
X40420/X40421 – Preliminary
Watchdog Time Out For 2-Wire Interface
Start
Start
Clockin (0 or 1)
tRSP
< tWDO
Y
SCL
SDA
WDO
WDT
Restart
IN
Minimum Sequence to Reset WDT
SCL
IM
SDA
VTRIPX Set/Reset Conditions
VCC/V2MON
tTSU
WDO
PR
tVPS
EL
(VTRIPX)
SCL
tRST
A
Start
tWDO
R
tRST
0
tTHD
VP
tVPH
7
0
7
0
tVPO
7
SDA
00h
A0h
tWC
Start
01h* sets VTRIP1
09h* sets VTRIP2
03h* resets VTRIP1
0Bh* resets VTRIP2
* all others reserved
REV 1.2.14 7/12/02
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Characteristics subject to change without notice.
21 of 25
X40420/X40421 – Preliminary
VTRIP1, VTRIP2 Programming Specifications: VCC = 2.0–5.5V; Temperature = 25°C
Parameter
Description
Min.
Max.
Unit
tVPS
WDO Program Voltage Setup time
10
µs
tVPH
WDO Program Voltage Hold time
10
µs
VTRIPX Level Setup time
10
µs
VTRIPX Level Hold (stable) time
10
µs
tWC
VTRIPX Program Cycle
10
ms
tVPO
Program Voltage Off time before next cycle
1
ms
VTRAN1
VTRIP1 Set Voltage Range
VTRAN2
VTRIP2 Set Voltage Range
Vtv
tVPS
VTRIPX Set Voltage variation after programming (0-75°C).
WDO Program Voltage Setup time
R
Programming Voltage
A
VP
Y
tTSU
tTHD
15
18
V
2.0
4.75
V
0.9
3.5
V
-25
+25
mV
10
µs
PR
EL
IM
IN
VTRIPX programming parameters are periodically sampled and are not 100% tested.
REV 1.2.14 7/12/02
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Characteristics subject to change without notice.
22 of 25
X40420/X40421 – Preliminary
PACKAGING INFORMATION
Y
14-Lead Plastic Small Outline Gullwing Package Type S
R
0.150 (3.80) 0.228 (5.80)
0.158 (4.00) 0.244 (6.20)
Pin 1 Index
A
Pin 1
IN
0.014 (0.35)
0.020 (0.51)
0.336 (8.55)
0.345 (8.75)
PR
0.050 (1.27)
EL
IM
(4X) 7°
0.010 (0.25)
0.020 (0.50)
0° – 8°
0.053 (1.35)
0.069 (1.75)
0.004 (0.10)
0.010 (0.25)
0.050"Typical
X 45°
0.050"Typical
0.0075 (0.19)
0.010 (0.25)
0.250"
0.016 (0.410)
0.037 (0.937)
0.030"Typical
14 Places
FOOTPRINT
NOTE: ALL DIMENSIONS IN INCHES (IN PARENTHESES IN MILLIMETERS)
REV 1.2.14 7/12/02
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Characteristics subject to change without notice.
23 of 25
X40420/X40421 – Preliminary
PACKAGING INFORMATION
14-Lead Plastic, TSSOP, Package Type V
Y
.025 (.65) BSC
IM
IN
.193 (4.9)
.200 (5.1)
A
R
.169 (4.3)
.252 (6.4) BSC
.177 (4.5)
EL
.0075 (.19)
.0118 (.30)
.002 (.05)
.006 (.15)
.010 (.25)
Gage Plane
0° - 8°
PR
.047 (1.20)
Seating Plane
.019 (.50)
.029 (.75)
Detail A (20X)
.031 (.80)
.041 (1.05)
See Detail “A”
NOTE: ALL DIMENSIONS IN INCHES (IN PARENTHESES IN MILLIMETERS)
REV 1.2.14 7/12/02
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Characteristics subject to change without notice.
24 of 25
X40420/X40421 – Preliminary
ORDERING INFORMATION
Monitored
VCC Supplies
VTRIP1
Range
VTRIP2
Range
2.9-5.5
4.6V±50mV
2.9V±50mV
Package
Operating
Temperature
Range
Part Number
with RESET
Part Number
with RESET
14L SOIC
0oC - 70oC
X40420S14-A
X40421S14-A
X40420S14I-A
X40421S14I-A
o
o
-40 C - 85 C
o
X40420V14-A
X40421V14-A
X40420V14I-A
X40421V14I-A
4.6V±50mV
2.6V±50mV
0oC - 70oC
X40420S14-B
X40421S14-B
X40420S14I-B
X40421S14I-B
X40420V14-B
X40421V14-B
X40420V14I-B
X40421V14I-B
X40420S14-C
X40421S14-C
X40420S14I-C
X40421S14I-C
14L SOIC
o
o
Y
0 C - 70 C
-40oC - 85oC
14L TSSOP
2.6-5.5
o
-40 C - 85 C
o
o
R
0 C - 70 C
14L TSSOP
oC
-40
2.9V±50mV
1.6V±50mV
14L SOIC
0
-
oC
-40
70oC
oC
0
-
-
85oC
70oC
IN
14L TSSOP
-
A
1.6-3.6
oC
85oC
-40oC - 85oC
PART MARK INFORMATION
IM
14-Lead SOIC
LIMITED WARRANTY
X40421V14-C
X40421V14I-C
0/1
Package - S/V
A, B, or C
I – Industrial
Blank – Commercial
WW – Workweek
YY – Year
PR
EL
X4042XX
YYWWXX
X40420V14-C
X40420V14I-C
©Xicor, Inc. 2001 Patents Pending
Devices sold by Xicor, Inc. are covered by the warranty and patent indemnification provisions appearing in its Terms of Sale only. Xicor, Inc. makes no warranty,
express, statutory, implied, or by description regarding the information set forth herein or regarding the freedom of the described devices from patent infringement.
Xicor, Inc. makes no warranty of merchantability or fitness for any purpose. Xicor, Inc. reserves the right to discontinue production and change specifications and prices
at any time and without notice.
Xicor, Inc. assumes no responsibility for the use of any circuitry other than circuitry embodied in a Xicor, Inc. product. No other circuits, patents, or licenses are implied.
COPYRIGHTS AND TRADEMARKS
Xicor, Inc., the Xicor logo, E2POT, XDCP, XBGA, AUTOSTORE, Direct Write cell, Concurrent Read-Write, PASS, MPS, PushPOT, Block Lock, IdentiPROM,
E2KEY, X24C16, SecureFlash, and SerialFlash are all trademarks or registered trademarks of Xicor, Inc. All other brand and product names mentioned herein are
used for identification purposes only, and are trademarks or registered trademarks of their respective holders.
U.S. PATENTS
Xicor products are covered by one or more of the following U.S. Patents: 4,326,134; 4,393,481; 4,404,475; 4,450,402; 4,486,769; 4,488,060; 4,520,461; 4,533,846;
4,599,706; 4,617,652; 4,668,932; 4,752,912; 4,829,482; 4,874,967; 4,883,976; 4,980,859; 5,012,132; 5,003,197; 5,023,694; 5,084,667; 5,153,880; 5,153,691;
5,161,137; 5,219,774; 5,270,927; 5,324,676; 5,434,396; 5,544,103; 5,587,573; 5,835,409; 5,977,585. Foreign patents and additional patents pending.
LIFE RELATED POLICY
In situations where semiconductor component failure may endanger life, system designers using this product should design the system with appropriate error detection
and correction, redundancy and back-up features to prevent such an occurrence.
Xicor’s products are not authorized for use in critical components in life support devices or systems.
1. Life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b) support or sustain life, and whose failure to
perform, when properly used in accordance with instructions for use provided in the labeling, can be reasonably expected to result in a significant injury to the user.
2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life
support device or system, or to affect its safety or effectiveness.
REV 1.2.14 7/12/02
www.xicor.com
Characteristics subject to change without notice.
25 of 25