ON ASM690AESAF Power supply supervisor Datasheet

ASM690A/692A,
ASM802L/802M, ASM805L
mP Power Supply Supervisor
with Battery Backup Switch
Description
The ASM690A / ASM692A / ASM802L / ASM802M / ASM805L
offers complete single chip solutions for power supply monitoring and
control battery functions in microprocessor systems. Each device
implements four functions: Reset control, watchdog monitoring,
battery−backup switching and power failure monitoring. In addition to
microprocessor reset under power−up and power−down conditions,
these devices provide battery−backup switching to maintain control in
power loss and brown−out situations. Additional monitoring
capabilities can provide an early warning of unregulated power supply
loss before the voltage regulator drops out. The important features of
these four functions are:
• 1.6 second watchdog timer to keep microprocessor responsive
• 4.40 V or 4.65 V VCC threshold for microprocessor reset at
power−up and power−down
• SPDT (Single−pole, Double−throw) PMOS switch connects backup
power to RAM if VCC fails
• 1.25 V threshold detector for power loss or general purpose voltage
monitoring
These features are pin−compatible with the industry standard
power−supply supervisors. Short−circuit and thermal protection have
also been added. The ASM690A / ASM802L / ASM805L generate a
reset pulse when the supply voltage drops below 4.65 V and the
ASM692A / ASM802M generate a reset below 4.40 V. The ASM802L
/ ASM802M have power−fail accuracy to ±2%. The ASM805L is the
same as the ASM690A except that RESET is provided instead of
RESET.
Features
PDIP−8
P SUFFIX
CASE 646AA
SOIC−8
S SUFFIX
CASE 751BD
PIN CONFIGURATIONS
VOUT
1
VCC
GND
PFI
VOUT
VCC
GND
VBATT
ASM690A,
ASM692A,
ASM802L,
ASM802M
1
RESET
WDI
PFO
VBATT
ASM805L
PFI
RESET
WDI
PFO
(Top Views)
ORDERING INFORMATION
• Two Precision Supply−voltage Monitor Options
•
•
•
•
•
•
•
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See detailed ordering and shipping information in the package
dimensions section on page 11 of this data sheet.
4.65 V (ASM690A / ASM802L / ASM805L)
4.40 V (ASM692A / ASM802M)
Battery−backup Power Switch On−chip
Watchdog Timer: 1.6 Second Timeout
Power Failure / Low Battery Detection
Short Circuit Protection and Thermal Limiting
Small 8−pin SO and 8−pin PDIP Packages
No External Components
Specified Over Full Temperature Range
Applications
•
•
•
•
•
•
•
•
Embedded Control Systems
Portable/Battery Operated Systems
Intelligent Instruments
Wireless Instruments
© Semiconductor Components Industries, LLC, 2011
August, 2011 − Rev. 3
1
Wireless Communication Systems
PDAs and Hand−held Equipments
mP / mC Power Supply Monitoring
Safety System
Publication Order Number:
ASM690A/D
ASM690A/692A, ASM802L/802M, ASM805L
Figure 1. Typical Operating Circuit
Figure 2. Block Diagram
Table 1. PIN DESCRIPTION
Pin Number
ASM690A/ASM692A
ASM802L/ASM802M
ASM805L
Name
Function
1
1
VOUT
Voltage supply for RAM. When VCC is above the reset threshold, VOUT connects
to VCC through a P−Channel MOS device. If VCC falls below the reset threshold,
this output will be connected to the backup supply at VBATT (or VCC, whichever is
higher) through the MOS switch to provide continuous power to the CMOS RAM.
2
2
VCC
+5 V power supply input.
3
3
GND
Ground.
4
4
PFI
Power failure monitor input. PFI is connected to the internal power fail comparator which is referenced to 1.25 V. The power fail output (PFO) is active LOW but
remains HIGH if PFI is above 1.25 V. If this feature is unused, the PFI pin should
be connected to GND or VOUT.
5
5
PFO
Power−fail output. PFO is active LOW whenever the PFI pin is less than 1.25 V.
6
6
WDI
Watchdog input. The WDI input monitors microprocessor activity. An internal
timer is reset with each transition of the WDI input. If the WDI is held HIGH or
LOW for longer than the watchdog timeout period, typically 1.6 seconds, RESET
(or RESET) is asserted for the reset pulse width time, tRS, of 140 ms, minimum.
7
−
RESET
Active−LOW reset output. When triggered by VCC falling below the reset
threshold or by watchdog timer timeout, RESET pulses low for the reset pulse
width tRS, typically 200 ms. It will remain low if VCC is below the reset threshold
(4.65 V in ASM690A / ASM802L and 4.4 V in the ASM692A / ASM802L) and
remains low for 200 ms after VCC rises above the reset threshold.
−
7
RESET
Active−HIGH reset output. The inverse of RESET.
8
8
VBATT
Auxiliary power or backup−battery input. VBATT should be connected to GND if
the function is not used. The input has about 40 mV of hysteresis to prevent rapid
toggling between VCC and VBATT.
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2
ASM690A/692A, ASM802L/802M, ASM805L
Table 2. ABSOLUTE MAXIMUM RATINGS
Parameter
Pin Terminal Voltage with Respect to Ground
VCC
VBATT
All other inputs (Note 1)
Min
Max
Unit
−0.3
−0.3
−0.3
6.0
6.0
VCC + 0.3
V
Input Current at VCC
200
mA
Input Current at VBATT
50
mA
Input Current at GND
20
mA
Output Current
VOUT
Short circuit protected
All other inputs
20
mA
Rate of Rise: VBATT and VCC
100
V/ms
Continuous Power Dissipation
Plastic DIP (derate 9 mW/°C above 70°C)
SO (derate 5.9 mW/°C above 70°C)
mW
800
500
Operating Temperature Range (C Devices)
0
70
°C
Operating Temperature Range (E Devices)
−40
85
°C
Storage Temperature Range
−65
160
°C
Lead Temperature (Soldering, 10 sec)
300
°C
ESD rating
HBM
MM
1
100
KV
V
Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the
Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect
device reliability.
1. The input voltage limits on PFI and WDI may be exceeded if the current is limited to less than 10 mA.
Table 3. ELECTRICAL CHARACTERISTICS (Unless otherwise noted, VCC = 4.75 V to 5.5 V for the ASM690A / ASM802L /
ASM805L and VCC = 4.5 V to 5.5 V for the ASM692A / ASM802M; VBATT = 2.8 V; and TA = TMIN to TMAX.)
Parameter
Symbol
Conditions
Min
VCC, VBATT Voltage
Range (Note 2)
Supply Current
Excluding IOUT
ISUPPLY in Battery
Backup Mode
(Excluding IOUT)
VBATT Standby
Current (Note 3)
VOUT Output
VOUT in Battery
Backup Mode
Typ
1.1
IS
35
VCC = 0 V, VBATT = 2.8 V
TA = 25°C
TA = 25°C
TA = TMIN to TMAX
−0.1
−1.0
VCC−0.025
VCC−
0.010
IOUT = 50 mA
VCC−0.25
VCC−
0.10
IOUT = 250 mA, VCC < VBATT − 0.2 V
VBATT− 0.1
VBATT
−
0.001
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3
V
100
mA
mA
0.02
0.02
IOUT = 5 mA
WDI input impedance is 50 kW. WDI is biased to 0.3 VCC.
5.5
5.0
2. If VCC or VBATT is 0 V, the other must be greater than 2.0 V.
3. Battery charging−current is “−”. Battery discharge current is “+”.
4. WDI is guaranteed to be in an intermediate level state if WDI is floating and VCC is within the operating voltage range.
NOTE:
Unit
1.5
TA = TMIN to TMAX
5.5 V > VCC > VBATT + 0.2 V
Max
mA
V
V
ASM690A/692A, ASM802L/802M, ASM805L
Table 3. ELECTRICAL CHARACTERISTICS (Unless otherwise noted, VCC = 4.75 V to 5.5 V for the ASM690A / ASM802L /
ASM805L and VCC = 4.5 V to 5.5 V for the ASM692A / ASM802M; VBATT = 2.8 V; and TA = TMIN to TMAX.) (continued)
Parameter
Symbol
Battery Switch
Threshold,
VCC to VBATT
Conditions
VCC < VRT
Min
Power Up
Power Down
Battery Switch over
Hysteresis
Reset Threshold
VRT
mV
40
mV
4.50
4.65
4.75
ASM692A, ASM802M
4.25
4.40
4.50
ASM802L, TA = 25°C, VCC falling
4.55
4.70
ASM802M, TA = 25°C, VCC falling
4.30
4.45
tRS
140
ISOURCE = 800 mA
200
ASM69_AC, ASM802_C, VCC = 1.0 V, ISINK = 50 mA
0.3
ASM69_AE, ASM802_E, VCC = 1.2 V, ISINK = 100 mA
0.3
ASM805LE, ISOURCE = 4 mA, VCC = 1.2 V
0.9
ASM805L, ISOURCE = 800 mA
VCC − 1.5
tWD
WDI Pulse Width
tWP
PFI Input Threshold
50
−150
150
mA
0.8
V
V
VCC = 5 V, Logic HIGH
3.5
ASM69_A, ASM805L, VCC = 5 V
1.20
1.25
1.30
ASM802_C/E, VCC = 5 V
1.225
1.250
1.275
−25
0.01
25
ISOURCE = 800 mA
VCC − 1.5
2. If VCC or VBATT is 0 V, the other must be greater than 2.0 V.
3. Battery charging−current is “−”. Battery discharge current is “+”.
4. WDI is guaranteed to be in an intermediate level state if WDI is floating and VCC is within the operating voltage range.
WDI input impedance is 50 kW. WDI is biased to 0.3 VCC.
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4
sec
−50
ISINK = 3.2 mA
NOTE:
2.25
ns
VCC = 5 V, Logic LOW
PFI Input Current
PFO Output Voltage
1.60
50
WDI = VCC
WDI = 0 V
WDI Input Threshold
(Note 4)
0.4
1.00
VIL = 0.4 V, VIH = 0.8 VCC
ms
V
0.4
ASM805L, ISINK = 3.2 mA
Watchdog Timeout
280
VCC − 1.5
0.8
V
mV
ISINK = 3.2 mA
ASM805LC, ISOURCE = 4 mA, VCC = 1.1 V
Unit
20
−20
40
Reset Output
Voltage
WDI Input Current
Max
ASM690A/802L/805L
Reset Threshold
Hysteresis
Reset Pulse Width
Typ
nA
V
0.4
ASM690A/692A, ASM802L/802M, ASM805L
Application Information
Detailed Description
It is important to initialize a microprocessor to a known
state in response to specific events that could create code
execution errors and “lock−up”. The reset output of these
supervisory circuits send a reset pulse to the microprocessor
in response to power−up, power−down/power−loss or a
watchdog time−out.
Microprocessor Interface
The ASM690 has logic−LOW RESET output while the
ASM805 has an inverted logic−HIGH RESET output.
Microprocessors with bidirectional reset pins can pose a
problem when the supervisory circuit and the
microprocessor output pins attempt to go to opposite logic
states. The problem can be resolved by placing a 4.7 kW
resistor between the RESET output and the microprocessor
reset pin. This is shown in Figure 4. Since the series resistor
limits drive capabilities, the reset signal to other devices
should be buffered.
RESET/RESET Timing
Power−up reset occurs when a rising VCC reaches the
reset threshold, VRT, forcing a reset condition in which the
reset output is asserted in the appropriate logic state for the
duration of tRS. The reset pulse width, tRS, is typically
around 200 ms and is LOW for the ASM690A, ASM692A,
ASM802 and HIGH for the ASM805L. Figure 3 shows the
reset pin timing.
Power−loss or “brown−out” reset occurs when VCC dips
below the reset threshold resulting in a reset assertion for the
duration of tRS. The reset signal remains asserted as long as
VCC is between VRT and 1.1 V, the lowest VCC for which
these devices can provide a guaranteed logic−low output. To
ensure logic inputs connected to the ASM690A /
ASM692A/ASM802 RESET pin are in a known state when
VCC is under 1.1 V, a 100 kW pull−down resistor at RESET
is needed: the logic−high ASM805L will need a pull−up
resistor to VCC.
Watchdog Timer
A Watchdog time−out reset occurs when a logic “1” or
logic “0” is continuously applied to the WDI pin for more
than 1.6 seconds. After the duration of the reset interval, the
watchdog timer starts a new 1.6 second timing interval; the
microprocessor must service the watchdog input by
changing states or by floating the WDI pin before this
interval is finished. If the WDI pin is held either HIGH or
LOW, a reset pulse will be triggered every 1.8 seconds (the
1.6 second timing interval plus the reset pulse width tRS).
Figure 3. RESET/RESET Timing
Figure 4. Interfacing with Bi−directional
Microprocessor Reset Inputs
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ASM690A/692A, ASM802L/802M, ASM805L
Watchdog Input
Table 5. PIN CONNECTIONS
IN BATTERY BACKUP MODE
As discussed in the Reset section, the Watchdog input is
used to monitor microprocessor activity. It can be used to
insure that the microprocessor is in a continually responsive
state by requiring that the WDI pin be toggled every second.
If the WDI pin is not toggled within the 1.6 second window
(minimum tWD + tRS), a reset pulse will be asserted to return
the microprocessor to the initial start−up state. Pulses as
short as 50 ns can be applied to the WDI pin. If this feature
is not used, the WDI pin should be open circuited or the logic
placed into a high−impedance state to allow the pin to float.
Pin
VOUT
Connected to VBATT through internal
PMOS switch
VBATT
Connected to VOUT
PFI
Disabled
PFO
Logic−LOW
RESET
Backup−Battery Switchover
WDI
A power loss can be made less severe if the system RAM
contents are preserved. This is achieved in the ASM690/
692/802/805 by switching from the failed VCC to an
alternate power source connected at VBATT when VCC is less
than the reset threshold voltage (VCC < VRT), and VCC is less
than VBATT. The VOUT pin is normally connected to VCC
through a 2 W PMOS switch but a brown−out or loss of VCC
will cause a switchover to VBATT by means of a 20 W PMOS
switch. Although both conditions (VCC < VRT and VCC <
VBATT) must occur for the switchover to VBATT to occur,
VOUT will be switched back to VCC when VCC exceeds VRT
irrespective of the voltage at VBATT. It should be noted that
an internal device diode (D1 in Figure 5) will be forward
biased if VBATT exceeds VCC by more than a diode drop
when VCC is switched to VOUT. Because of this it is
recommended that VBATT be no greater than VRT + 0.6 V.
Connection
Logic−LOW (except on ASM805 where it
is HIGH)
Watchdog timer disabled
During the backup power mode, the internal circuitry of
the supervisory circuit draws power from the battery supply.
While VCC is still alive, the comparator circuits remain alive
and the current drawn by the device is typically 35 mA.
When VCC drops more than 1.1 V below VBATT, the internal
switchover comparator, the PFI comparator and WDI
comparator will shut off, reducing the quiescent current
drawn by the IC to less than 1 mA.
Backup Power Sources − Batteries
Battery voltage selection is important to insure that the
battery does not discharge through the parasitic device diode
D1 (see Figure 5) when VCC is less than VBATT and VCC >
VRT.
Table 6. MAXIMUM BATTERY VOLTAGES
Table 4.
Part Number
Maximum Battery Voltage (V)
Condition
SW1/SW2
SW3/SW4
ASM690A
4.80
VCC > Reset Threshold
Open
Closed
ASM802L
4.80
VCC < Reset Threshold
VCC > VBATT
Open
Closed
ASM805L
4.80
ASM692A
4.55
VCC < Reset Threshold
VCC < VBATT
Closed
Open
ASM802M
4.55
Although most batteries that meet the requirements of
Table 6 are acceptable, lithium batteries are very effective
backup source due to their high−energy density and very low
self−discharge rates.
ASM690A/802A/805L Reset Threshold = 4.65 V
ASM692A/ASM802M Reset Threshold = 4.4 V
Battery Replacement while Powered
Batteries can be replaced even when the device is in a
powered state as long as VCC remains above the reset
threshold voltage VRT. In the ASM devices, a floating
VBATT pin will not cause a power supply switchover as can
occur in some other supervisory circuits. If VBATT is not
used, the pin should be grounded.
Backup Power Sources − SuperCapt
Capacitor storage, with very high values of capacitance,
can be used as a back−up power source instead of batteries.
SuperCap are capacitors with capacities in the fractional
farad range. A 0.1 farad SuperCap would provide a useful
backup power source. Like the battery supply, it is important
Figure 5. Internal Device Configuration of Battery
Switch−over Function
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6
ASM690A/692A, ASM802L/802M, ASM805L
Power−Fail Comparator
that the capacitor voltage remain below the maximum
voltages shown in Table 6. Although the circuit of Figure 6
shows the most simple way to connect the SuperCap, this
circuit cannot insure that an over voltage condition will not
occur since the capacitor will ultimately charge up to VCC.
To insure that an over voltage condition does not occur, the
circuit of Figure 7 is preferred. In this circuit configuration,
the diode−resistor pair clamps the capacitor voltage at one
diode drop below VCC. VCC itself should be regulated
within ±5% of 5 V for the ASM692A/802M or within ±10%
of 5 V for the ASM690A/802L/805L to insure that the
storage capacitor does not achieve an over voltage state.
The Power Fail feature is an independent voltage
monitoring function that can be used for any number of
monitoring activities. The PFI function can provide an early
sensing of power supply failure by sensing the voltage of the
unregulated DC ahead of the regulated supply sensing seen
by the backup−battery switchover circuitry. The PFI pin is
compared to a 1.25 V internal reference. If the voltage at the
PFI pin is less than this reference voltage, the PFO pin goes
low. By sensing the voltage of the raw DC power supply, the
microprocessor system can prepare for imminent
power−loss, especially if the battery backup supply is not
enabled. The input voltage at the PFI pin results from a
simple resistor voltage divider as shown in Figure 8.
Figure 6. Capacitor as a Backup Power Source
Figure 8. Simple Voltage Divider Sets PFI Trip Point
Power Fail Hysteresis
A noise margin can be added to the simple monitoring
circuit of Figure 8 by adding positive feedback from the
PFO pin. The circuit of Figure 9 adds this positive “latching”
effect by means of an additional resistor R3 connected
between PFO and PFI which helps in pulling PFI in the
direction of PFO and eliminating an indecision at the trip
point. Resistor R3 is normally about 10 times higher in
resistance than R2 to keep the hysteresis band reasonable
and should be larger than 10 kW to avoid excessive loading
on the PFO pin. The calculations for the correct values of
resistors to set the hysteresis thresholds are given in
Figure 9. A capacitor can be added to offer additional noise
rejection by low−pass filtering.
Figure 7. Capacitor as a Backup Power Source
Voltage Clamped to 0.5 V below VCC
Operation without a Backup Power Source
When operating without a back−up power source, the
VBATT pin should be connected to GND and VOUT should
be connected to VCC, since power source switchover will not
occur. Connecting VOUT to VCC eliminates the voltage drop
due to the ON−resistance of the PMOS switch.
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ASM690A/692A, ASM802L/802M, ASM805L
Monitoring Capabilities of the Power−fail Input:
Although designed for power supply failure monitoring,
the PFI pin can be used for monitoring any voltage condition
that can be scaled by means of a resistive divider. An
example is the negative power supply monitor configured in
Figure 10. In this case a good negative supply will hold the
PFI pin below 1.25 V and the PFO pin will be at logic “0”.
As the negative voltage declines, the voltage at the PFI pin
will rise until it exceeds 1.25 V and the PFO pin will go to
logic “1”.
Figure 9. Hysteresis Added to PFI Pin
Figure 10. Using PFI to Monitor Negative Supply
Voltage
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ASM690A/692A, ASM802L/802M, ASM805L
PACKAGE DIMENSIONS
PDIP−8, 300 mils
CASE 646AA−01
ISSUE A
SYMBOL
MIN
NOM
A
E1
5.33
A1
0.38
A2
2.92
3.30
4.95
b
0.36
0.46
0.56
b2
1.14
1.52
1.78
c
0.20
0.25
0.36
D
9.02
9.27
10.16
E
7.62
7.87
8.25
E1
6.10
6.35
7.11
e
PIN # 1
IDENTIFICATION
MAX
2.54 BSC
eB
7.87
L
2.92
10.92
3.30
3.80
D
TOP VIEW
E
A2
A
A1
c
b2
L
e
eB
b
SIDE VIEW
END VIEW
Notes:
(1) All dimensions are in millimeters.
(2) Complies with JEDEC MS-001.
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ASM690A/692A, ASM802L/802M, ASM805L
PACKAGE DIMENSIONS
SOIC 8, 150 mils
CASE 751BD−01
ISSUE O
SYMBOL
E1
E
MIN
MAX
A
1.35
1.75
A1
0.10
0.25
b
0.33
0.51
c
0.19
0.25
D
4.80
5.00
E
5.80
6.20
E1
3.80
4.00
1.27 BSC
e
PIN # 1
IDENTIFICATION
NOM
h
0.25
0.50
L
0.40
1.27
θ
0º
8º
TOP VIEW
D
h
A1
θ
A
c
e
b
L
END VIEW
SIDE VIEW
Notes:
(1) All dimensions are in millimeters. Angles in degrees.
(2) Complies with JEDEC MS-012.
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ASM690A/692A, ASM802L/802M, ASM805L
Table 7. ORDERING INFORMATION − Tin − Lead Devices
Part Number (Note 5)
Reset Threshold (V)
Temperature (5C)
Pins−Package
Package Marking
ASM690ACPA
4.5 to 4.75
0 to +70
8−Plastic DIP
ASM690ACPA
ASM690ACSA
4.5 to 4.75
0 to +70
8−SO
ASM690ACSA
ASM690AEPA
4.5 to 4.75
−40 to +85
8−Plastic DIP
ASM690AEPA
ASM690AESA
4.5 to 4.75
−40 to +85
8−SO
ASM690AESA
ASM692ACPA
4.25 to 4.50
0 to +70
8−Plastic DIP
ASM692ACPA
ASM692ACSA
4.25 to 4.50
0 to +70
8−SO
ASM692ACSA
ASM692AEPA
4.25 to 4.50
−40 to +85
8−Plastic DIP
ASM692AEPA
ASM692AESA
4.25 to 4.50
−40 to +85
8−SO
ASM692AESA
ASM802LCPA
4.5 to 4.75
0 to +70
8−Plastic DIP
ASM802LCPA
ASM802LCSA
4.5 to 4.75
0 to +70
8−SO
ASM802LCSA
ASM802LEPA
4.5 to 4.75
−40 to +85
8−Plastic DIP
ASM802LEPA
ASM802LESA
4.5 to 4.75
−40 to +85
8−SO
ASM802LESA
ASM802MCPA
4.25 to 4.50
0 to +70
8−Plastic DIP
ASM802MCPA
ASM802MCSA
4.25 to 4.50
0 to +70
8−SO
ASM802MCSA
ASM802MEPA
4.25 to 4.50
−40 to +85
8−Plastic DIP
ASM802MEPA
ASM802MESA
4.25 to 4.50
−40 to +85
8−SO
ASM802MESA
ASM805LCPA
4.5 to 4.75
0 to +70
8−Plastic DIP
ASM805LCPA
ASM805LCSA
4.5 to 4.75
0 to +70
8−SO
ASM805LCSA
ASM805LEPA
4.5 to 4.75
−40 to +85
8−Plastic DIP
ASM805LEPA
ASM805LESA
4.5 to 4.75
−40 to +85
8−SO
ASM805LESA
ASM690A
ASM692A
ASM802L
ASM802M
ASM805L
5. For parts to be packed in Tape and Reel, add “−T” at the end of the part number. ON Semiconductor lead free parts are RoHS compliant.
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ASM690A/692A, ASM802L/802M, ASM805L
Table 8. ORDERING INFORMATION − Lead Free Devices
Part Number (Note 6)
Reset Threshold (V)
Temperature (5C)
Pins−Package
Package Marking
ASM690ACPAF
4.5 to 4.75
0 to +70
8−Plastic DIP
ASM690ACPAF
ASM690ACSAF
4.5 to 4.75
0 to +70
8−SO
ASM690ACSAF
ASM690AEPAF
4.5 to 4.75
−40 to +85
8−Plastic DIP
ASM690AEPAF
ASM690AESAF
4.5 to 4.75
−40 to +85
8−SO
ASM690AESAF
ASM692ACPAF
4.25 to 4.50
0 to +70
8−Plastic DIP
ASM692ACPAF
ASM692ACSAF
4.25 to 4.50
0 to +70
8−SO
ASM692ACSAF
ASM692AEPAF
4.25 to 4.50
−40 to +85
8−Plastic DIP
ASM692AEPAF
ASM692AESAF
4.25 to 4.50
−40 to +85
8−SO
ASM692AESAF
ASM802LCPAF
4.5 to 4.75
0 to +70
8−Plastic DIP
ASM802LCPAF
ASM802LCSAF
4.5 to 4.75
0 to +70
8−SO
ASM802LCSAF
ASM802LEPAF
4.5 to 4.75
−40 to +85
8−Plastic DIP
ASM802LEPAF
ASM802LESAF
4.5 to 4.75
−40 to +85
8−SO
ASM802LESAF
ASM802MCPAF
4.25 to 4.50
0 to +70
8−Plastic DIP
ASM802MCPAF
ASM802MCSAF
4.25 to 4.50
0 to +70
8−SO
ASM802MCSAF
ASM802MEPAF
4.25 to 4.50
−40 to +85
8−Plastic DIP
ASM802MEPAF
ASM802MESAF
4.25 to 4.50
−40 to +85
8−SO
ASM802MESAF
ASM805LCPAF
4.5 to 4.75
0 to +70
8−Plastic DIP
ASM805LCPAF
ASM805LCSAF
4.5 to 4.75
0 to +70
8−SO
ASM805LCSAF
ASM805LEPAF
4.5 to 4.75
−40 to +85
8−Plastic DIP
ASM805LEPAF
ASM805LESAF
4.5 to 4.75
−40 to +85
8−SO
ASM805LESAF
ASM690A
ASM692A
ASM802L
ASM802M
ASM805L
6. For parts to be packed in Tape and Reel, add “−T” at the end of the part number. ON Semiconductor lead free parts are RoHS compliant.
SuperCap is a trademark of Baknor Industries.
ON Semiconductor and
are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice
to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability
arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages.
“Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All
operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights
nor the rights of others. SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications
intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death may occur. Should
Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees, subsidiaries, affiliates,
and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death
associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture of the part. SCILLC is an Equal
Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner.
PUBLICATION ORDERING INFORMATION
LITERATURE FULFILLMENT:
Literature Distribution Center for ON Semiconductor
P.O. Box 5163, Denver, Colorado 80217 USA
Phone: 303−675−2175 or 800−344−3860 Toll Free USA/Canada
Fax: 303−675−2176 or 800−344−3867 Toll Free USA/Canada
Email: [email protected]
N. American Technical Support: 800−282−9855 Toll Free
USA/Canada
Europe, Middle East and Africa Technical Support:
Phone: 421 33 790 2910
Japan Customer Focus Center
Phone: 81−3−5773−3850
http://onsemi.com
12
ON Semiconductor Website: www.onsemi.com
Order Literature: http://www.onsemi.com/orderlit
For additional information, please contact your local
Sales Representative
ASM690A/D
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