___________________________________________________________________Selector Guide
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________________General Description
The MAX6316–MAX6322 family of microprocessor (µP)
supervisory circuits monitors power supplies and
microprocessor activity in digital systems. It offers sev-
eral combinations of push/pull, open-drain, and bidirec-
tional (such as Motorola 68HC11) reset outputs, along
with watchdog and manual-reset features. The
Selector
Guide
below lists the specific functions available from
each device. These devices are specifically designed
to ignore fast negative transients on VCC. Resets are
guaranteed valid for VCC down to 1V.
These devices are available in 26 factory-trimmed reset
threshold voltages (from 2.5V to 5V, in 100mV incre-
ments), featuring four minimum power-on reset timeout
periods (from 1ms to 1.12sec), and four watchdog time-
out periods (from 6.3ms to 25.6sec). Nine standard ver-
sions are available with an order increment requirement
of 2500 pieces (see
Standard Versions
table); contact
the factory for availability of other versions, which have
an order increment requirement of 10,000 pieces.
The MAX6316–MAX6322 are offered in a miniature
5-pin SOT23 package.
________________________Applications
Portable Computers
Computers
Controllers
Intelligent Instruments
Portable/Battery-Powered Equipment
Embedded Control Systems
____________________________Features
Small 5-Pin SOT23 Package
Available in 26 Reset Threshold Voltages
2.5V to 5V, in 100mV Increments
Four Reset Timeout Periods
1ms, 20ms, 140ms, or 1.12sec (min)
Four Watchdog Timeout Periods
6.3ms, 102ms, 1.6sec, or 25.6sec (typ)
Four Reset Output Stages
Active-High, Push/Pull
Active-Low, Push/Pull
Active-Low, Open-Drain
Active-Low, Bidirectional
Guaranteed Reset Valid to VCC = 1V
Immune to Short Negative VCC Transients
Low Cost
No External Components
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
________________________________________________________________
Maxim Integrated Products
1
19-0496; Rev 3; 1/99
PART
MAX6316LUK____-T
MAX6316MUK____-T -40°C to +85°C
-40°C to +85°C
TEMP. RANGE PIN-PACKAGE
5 SOT23-5
5 SOT23-5
_______________Ordering Information
Ordering Information continued at end of data sheet.
MAX6317HUK____-T -40°C to +85°C 5 SOT23-5
MAX6318HUK____-T -40°C to +85°C 5 SOT23-5
ACTIVE-LOW
OPEN-DRAIN
MAX6316L
MAX6316M
MAX6317H
MAX6321HP
MAX6318LH
MAX6318MH**
MAX6319LH
MAX6319MH**
MAX6320P
ACTIVE-LOW
PUSH/PULL
ACTIVE-HIGH
PUSH/PULL
ACTIVE-LOW
BIDIRECTIONAL
PART WATCHDOG
INPUT
MANUAL
RESET
INPUT
MAX6322HP
RESET OUTPUTS*
*
The MAX6318/MAX6319/MAX6321/MAX6322 feature two types of reset output on each device.
**
Future product—contact factory for availability.
MAX6318MHUK____-T -40°C to +85°C 5 SOT23-5
Typical Operating Circuit and Pin Configurations appear at
end of data sheet.
ELECTRICAL CHARACTERISTICS
(VCC = 2.5V to 5.5V, TA= -40°C to +85°C, unless otherwise noted. Typical values are at TA= +25°C.) (Note 1)
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
2 _______________________________________________________________________________________
ABSOLUTE MAXIMUM RATINGS
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
Voltage (with respect to GND)
VCC......................................................................-0.3V to +6V
RESET (MAX6320/MAX6321/MAX6322 only)...... -0.3V to +6V
All Other Pins.........................................-0.3V to (VCC + 0.3V)
Input/Output Current, All Pins .............................................20mA
Continuous Power Dissipation (TA= +70°C)
SOT23-5 (derate 7.1mW/°C above +70°C)...............571mW
Operating Temperature Range............................-40°C to +85°C
Junction Temperature......................................................+150°C
Storage Temperature Range..............................-65°C to +160°C
Lead Temperature (soldering, 10sec)..............................+300°C
VCC - 1.5
0.8 x VCC
VOH
0.4
0.3
0.3
V
0.3
VOL
RESET Output Voltage
µs40tRD
VCC to RESET Delay 1120 1600 2240
140 200 280
20 28 40 ms
1 1.4 2
tRP
Reset Active Timeout Period
mV3Reset Threshold Hysteresis
V1 5.5VCC
Operating Voltage Range
VTH -2.5% VTH VTH+2.5% V
VTH -1.5% VTH VTH+1.5%
VRST
Reset Threshold (Note 2)
ppm/°C40
VTH/°C
Reset Threshold Temperature
Coefficient
UNITSMIN TYP MAXSYMBOLPARAMETER
VCC 4.5V, ISOURCE = 800µA
VCC 2.7V, ISOURCE = 500µA
VCC 4.5V, ISINK = 3.2mA
VCC 2.7V, ISINK = 1.2mA
VCC 1.2V, ISINK = 100µA
VCC 1.0V, ISINK = 50µA
TA= -40°C to +85°C
VCC falling at 1mV/µs
MAX63_ _D_-T
TA= -40°C to +85°C
TA= +25°C
MAX63_ _C_-T
MAX63_ _B_-T
MAX63_ _A_-T
CONDITIONS
V
0.3
VOL
RESET Output Voltage
VCC 2.7V, ISINK = 1.2mA 0.4VCC 4.5V, ISINK = 3.2mA 0.8 x VCC
VOH
VCC 1.8V, ISOURCE = 150µA 0.8 x VCC
VCC 2.7V, ISOURCE = 500µA VCC - 1.5VCC 4.5V, ISOURCE = 800µA
Note 1: Over-temperature limits are guaranteed by design, not production tested.
Note 2: A factory-trimmed voltage divider programs the nominal reset threshold (VTH). Factory-trimmed reset thresholds are
available in 100mV increments from 2.5V to 5V (see Table 1 at end of data sheet).
MAX6316/MAX6317/MAX6318/
MAX6320/MAX6321:
MR and WDI unconnected µA
10 20
ICC
Supply Current
VCC = 5.5V
512VCC = 3.6V
MAX6319/MAX6322:
MR unconnected 512VCC = 5.5V 38VCC = 3.6V
PUSH/PULL RESET OUTPUT (MAX6316L/MAX6317H/MAX6318_H/MAX6319_H/MAX6321HP/MAX6322HP)
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
_______________________________________________________________________________________ 3
Note 3: This is the minimum time RESET must be held low by an external pull-down source to set the active pull-up flip-flop.
Note 4: Measured from RESET VOL to (0.8 x VCC), RLOAD = .
Note 5: WDI is internally serviced within the watchdog period if WDI is left unconnected.
Note 6: The WDI input current is specified as the average input current when the WDI input is driven high or low. The WDI input is
designed for a three-stated-output device with a 10µA maximum leakage current and capable of driving a maximum capaci-
tive load of 200pF. The three-state device must be able to source and sink at least 200µA when active.
µA1.0ILKG
Open-Drain Reset Output
Leakage Current
ns400tS
Transition Flip-Flop Setup Time
333 ns
333
tR
RESET Output Rise Time
(Note 4)
UNITSMIN TYP MAXSYMBOLPARAMETER
(Note 3)
VCC = 5.0V, CL= 200pF
VCC = 3.0V, CL= 120pF
CONDITIONS
ELECTRICAL CHARACTERISTICS (continued)
(VCC = 2.5V to 5.5V, TA= -40°C to +85°C, unless otherwise noted. Typical values are at TA= +25°C.) (Note 1)
666
666
VCC = 5.0V, CL= 400pF
VCC = 3.0V, CL= 250pF
V0.4 0.65VPTH
Active Pull-Up Enable Threshold VCC = 5.0V mA20
RESET Active Pull-Up Current VCC = 5.0V k
4.2 4.7 5.2
RESET Pull-Up Resistance
V
0.3
VOL
RESET Output Voltage
VCC 1.0V, ISINK = 50µA 0.3VCC 1.2V, ISINK = 100µA 0.3VCC 2.7V, ISINK = 1.2mA 0.4VCC 4.5V, ISINK = 3.2mA
ms
4.3 6.3 9.3
tWD
Watchdog Timeout Period
MAX63_ _ _ W-T 71 102 153MAX63_ _ _ X-T
sec
1.12 1.6 2.4MAX63_ _ _ Y-T 17.9 25.6 38.4MAX63_ _ _ Z-T ns50tWDI
WDI Pulse Width VIL = 0.3 x VCC, VIH = 0.7 x VCC
V
0.3 x VCC
VIL
WDI Input Threshold (Note 5) 0.7 x VCC
120 160
IWDI
WDI Input Current
(Note 6) WDI = VCC, time average -20 -15VWDI = 0, time average
VIH
V
0.8VIL
MR Input Threshold VTH > 4.0V 2.0VIH 0.3 x VCC
VIL VTH < 4.0V 0.7 x VCC
VIH µs1
MR Input Pulse Width ns100
MR Glitch Rejection k
35 52 75
MR Pull-Up Resistance ns230
MR to Reset Delay VCC = 5V
µA
BIDIRECTIONAL RESET OUTPUT (MAX6316M/MAX6318MH/MAX6319MH)
OPEN-DRAIN RESET OUTPUT (MAX6320P/MAX6321HP/MAX6322HP)
WATCHDOG INPUT (MAX6316/MAX6317H/MAX6318_H/MAX6320P/MAX6321HP)
MANUAL-RESET INPUT (MAX6316_/MAX6317H/MAX6319_H/MAX6320P/MAX6322HP)
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
4 _______________________________________________________________________________________
__________________________________________Typical Operating Characteristics
(TA = +25°C, unless otherwise noted.)
0
2
1
4
3
8
7
6
5
10
9
-40 0 20-20 40 60 80 100
MAX6316/17/18/20/21
SUPPLY CURRENT vs. TEMPERATURE
MAX6316toc01
TEMPERATURE (°C)
SUPPLY CURRENT (µA)
VCC = 5V
VCC = 3V
VCC = 1V
0
30
20
10
50
40
90
80
70
60
100
-40 -20 0 20 40 60 80 100
VCC FALLING TO RESET PROPAGATION
DELAY vs. TEMPERATURE
MAX6316toc03
TEMPERATURE (°C)
RESET PROPAGATION DELAY (µs)
VCC FALLING AT 1mV/µs
VRST - VCC = 100mV
140
180
160
240
220
200
300
280
260
320
-40 0 20-20 40 60 80 100
MAX6316/17/19/20/22
MANUAL-RESET TO RESET
PROPAGATION DELAY vs. TEMPERATURE
MAX6316toc04
TEMPERATURE (°C)
PROPAGATION DELAY (ns)
VCC = 5V
0.95
0.98
0.97
0.96
1.00
0.99
1.04
1.03
1.02
1.01
1.05
-40 -20 0 20 40 60 80 100
NORMALIZED RESET TIMEOUT
PERIOD vs. TEMPERATURE
MAX6316toc05
TEMPERATURE (°C)
NORMALIZED RESET TIMEOUT PERIOD
0.95
0.98
0.97
0.96
1.00
0.99
1.04
1.03
1.02
1.01
1.05
-40 -20 0 20 40 60 80 100
MAX6316/17/18/20/21
NORMALIZED WATCHDOG TIMEOUT
PERIOD vs. TEMPERATURE
MAX6316toc06
TEMPERATURE (°C)
NORMALIZED WATCHDOG TIMEOUT PERIOD
80
010 100 1000
MAXIMUM VCC TRANSIENT DURATION
vs. RESET THRESHOLD OVERDRIVE
20
10
MAX6316toc08
RESET THRESHOLD OVERDRIVE (mV) VRST - VCC
TRANSIENT DURATION (µs)
30
50
60
40
70 VRST = 3.3V
VRST = 4.63V
VRST = 2.63V
RESET OCCURS ABOVE LINES
PASSIVE
4.7k
PULL-UP
2V/div
RESET, ACTIVE
PULL-UP
2V/div
RESET
INPUT
5V/div
200ns/div
MAX6316M/6318MH/6319MH
BIDIRECTIONAL
PULL-UP CHARACTERISTICS
MAX6316toc09
100pF
4.7k
+5V
74HC05
74HC05 VCC
GND
MR
100pF
INPUT
INPUT
+5V
RESET
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
_______________________________________________________________________________________ 5
______________________________________________________________Pin Description
11
MAX6316M/MAX6318MH/MAX6319MH:
Bidirectional, Active-Low, Reset Output.
Intended to interface directly to microprocessors
with bidirectional resets such as the Motorola
68HC11.
MAX6320P/MAX6321HP/MAX6322HP:
Open-Drain, Active-Low, Reset Output. NMOS out-
put (sinks current only). Connect a pull-up resistor
from RESET to any supply voltage up to 6V.
MAX6316L/MAX6318LH/MAX6319LH:
Active-Low, Reset Output. CMOS push/pull
output (sources and sinks current).
RESET
1
4
5
3
2
MAX6319LH
MAX6319MH
MAX6322HP
PIN
4
5
3
2
MAX6318LH
MAX6318MH
MAX6321HP
3
4
5
1
2
MAX6317H
Active-Low, Manual Reset Input. Pull low to force a
reset. Reset remains asserted for the duration of
the Reset Timeout Period after MR transitions from
low to high. Leave unconnected or connected to
VCC if not used.
MR
3
Watchdog Input. Triggers a reset if it remains
either high or low for the duration of the watchdog
timeout period. The internal watchdog timer clears
whenever a reset asserts or whenever WDI sees a
rising or falling edge. To disable the watchdog fea-
ture, leave WDI unconnected or three-state the dri-
ver connected to WDI.
WDI4
Supply Voltage. Reset is asserted when VCC
drops below the Reset Threshold Voltage (VRST).
Reset remains asserted until VCC rises above
VRST and for the duration of the Reset Timeout
Period (tRP) once VCC rises above VRST.
VCC
5
Active-High, Reset Output. CMOS push/pull output
(sources and sinks current). Inverse of RESET.
RESET
GroundGND2
MAX6316L
MAX6316M
MAX6320P
FUNCTIONNAME
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
6 _______________________________________________________________________________________
_______________Detailed Description
A microprocessor’s (µP) reset input starts or restarts the
µP in a known state. The reset output of the MAX6316–
MAX6322 µP supervisory circuits interfaces with the
reset input of the µP, preventing code-execution errors
during power-up, power-down, and brownout condi-
tions (see the
Typical Operating Circuit
). The MAX6316/
MAX6317/MAX6318/MAX6320/MAX6321 are also capa-
ble of asserting a reset should the µP become stuck in
an infinite loop.
Reset Output
The MAX6316L/MAX6318LH/MAX6319LH feature an
active-low reset output, while the MAX6317H/
MAX6318_H/MAX6319_H/MAX6321HP/MAX6322HP
feature an active-high reset output. RESET is guaran-
teed to be a logic low and RESET is guaranteed to be a
logic high for VCC down to 1V.
The MAX6316–MAX6322 assert reset when VCC is below
the reset threshold (VRST), when MR is pulled low
(MAX6316_/MAX6317H/MAX6319_H/MAX6320P/
MAX6322HP only), or if the WDI pin is not serviced within
the watchdog timeout period (tWD). Reset remains assert-
ed for the specified reset active timeout period (tRP) after
VCC rises above the reset threshold, after MR transitions
low to high, or after the watchdog timer asserts the reset
(MAX6316_/MAX6317H/MAX6318_H/MAX6320P/
MAX6321HP). After the reset active timeout period (tRP)
expires, the reset output deasserts, and the watchdog
timer restarts from zero (Figure 2).
MAX6316–MAX6322
VCC
VCC
WDI
(ALL EXCEPT
MAX6319/MAX6322)
1.23V
52k
52k
GND
RESET
(ALL EXCEPT
MAX6316/MAX6320P)
RESET
(ALL EXCEPT MAX6317)
MR
(ALL EXCEPT
MAX6318/MAX6321)
RESET
GENERATOR
WATCHDOG
TIMER
WATCHDOG
TRANSITION
DETECTOR
Figure 1. Functional Diagram
VCC 1V
1V
tRD
VRST VRST
tRD
RESET
GND
RESET
tRP
tRP
GND
Figure 2. Reset Timing Diagram
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
_______________________________________________________________________________________ 7
Bidirectional
RREESSEETT
Output
The MAX6316M/MAX6318MH/MAX6319MH are designed
to interface with µPs that have bidirectional reset pins,
such as the Motorola 68HC11. Like an open-drain output,
these devices allow the µP or other devices to pull the
bidirectional reset (RESET) low and assert a reset condi-
tion. However, unlike a standard open-drain output, it
includes the commonly specified 4.7kpull-up resistor
with a P-channel active pull-up in parallel.
This configuration allows the MAX6316M/MAX6318MH/
MAX6319MH to solve a problem associated with µPs
that have bidirectional reset pins in systems where sev-
eral devices connect to RESET (Figure 3). These µPs
can often determine if a reset was asserted by an exter-
nal device (i.e., the supervisor IC) or by the µP itself
(due to a watchdog fault, clock error, or other source),
and then jump to a vector appropriate for the source of
the reset. However, if the µP does assert reset, it does
not retain the information, but must determine the
cause after the reset has occurred.
The following procedure describes how this is done in
the Motorola 68HC11. In all cases of reset, the µP pulls
RESET low for about four external-clock cycles. It then
releases RESET, waits for two external-clock cycles,
then checks RESET’s state. If RESET is still low, the µP
concludes that the source of the reset was external
and, when RESET eventually reaches the high state, it
jumps to the normal reset vector. In this case, stored-
state information is erased and processing begins from
scratch. If, on the other hand, RESET is high after a
delay of two external-clock cycles, the processor
knows that it caused the reset itself and can jump to a
different vector and use stored-state information to
determine what caused the reset.
A problem occurs with faster µPs; two external-clock
cycles are only 500ns at 4MHz. When there are several
devices on the reset line, and only a passive pull-up resis-
tor is used, the input capacitance and stray capacitance
can prevent RESET from reaching the logic high state (0.8
x VCC) in the time allowed. If this happens, all resets will
be interpreted as external. The µP output stage is guaran -
teed to sink 1.6mA, so the rise time can not be reduced
considerably by decreasing the 4.7kinternal pull-up
resistance. See Bidirectional Pull-Up Characteristics in the
Typical Operating Characteristics
.
The MAX6316M/MAX6318MH/MAX6319MH overcome
this problem with an active pull-up FET in parallel with the
4.7kresistor (Figures 4 and 5). The pull-up transistor
holds RESET high until the µP reset I/O or the supervisory
circuit itself forces the line low. Once RESET goes below
VPTH, a comparator sets the transition edge flip-flop, indi-
cating that the next transition for RESET will be low to
high. When RESET is released, the 4.7kresistor pulls
RESET up toward VCC. Once RESET rises above VPTH
but is below (0.85 x VCC), the active P-channel pull-up
turns on. Once RESET rises above (0.85 x VCC) or the
2µs one-shot times out, the active pull-up turns off. The
parallel combination of the 4.7kpull-up and the
4.7k
MR**
CIN
RESET
RESET
CIRCUITRY
RESET***
WDI*
VCC
MAX6316M
MAX6318MH
MAX6319MH
CSTRAY
68HC11
RESET
CIRCUITRY
CIN
RESET
VCC
OTHER DEVICES
CIN
RESET
MAX6316M/MAX6318MH
MAX6316M/MAX6319MH
ACTIVE-HIGH PUSH/PULL MAX6318MH/MAX6319MH
*
**
***
Figure 3. MAX6316M/MAX6318MH/MAX6319MH Supports Additional Devices on the Reset Bus
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
8 _______________________________________________________________________________________
VCC
MAX6316M
MAX6318MH
MAX6319MH
LASER-
TRIMMED
RESISTORS
VREF
VCC
52k
MR
WDI
(MAX6316M/
MAX6318MH)
(MAX6316M/
MAX6319MH)
RESET
GENERATOR
2µs ONE SHOT
2µs ONE SHOT
WATCHDOG ON
CIRCUITRY
TRANSITION
FLIP-FLOP
RQ
SFF
VCC
4.7k
RESET
ACTIVE PULL-UP
ENABLE COMPARATOR
0.65V 0.85VCC
GND
Figure 4. MAX6316/MAX6318MH/MAX6319MH Bidirectional Reset Output Functional Diagram
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
_______________________________________________________________________________________ 9
P-channel transistor on-resistance quickly charges
stray capacitance on the reset line, allowing RESET to
transition from low to high within the required two elec-
tronic-clock cycles, even with several devices on the
reset line. This process occurs regardless of whether
the reset was caused by VCC dipping below the reset
threshold, the watchdog timing out, MR being asserted,
or the µP or other device asserting RESET. The parts do
not require an external pull-up. To minimize supply cur-
rent consumption, the internal 4.7kpull-up resistor
disconnects from the supply whenever the MAX6316M/
MAX6318MH/MAX6319MH assert reset.
Open-Drain
RREESSEETT
Output
The MAX6320P/MAX6321HP/MAX6322HP have an
active-low, open-drain reset output. This output struc-
ture will sink current when RESET is asserted. Connect
a pull-up resistor from RESET to any supply voltage up
to 6V (Figure 6). Select a resistor value large enough to
register a logic low (see
Electrical Characteristics
), and
small enough to register a logic high while supplying all
input current and leakage paths connected to the RESET
line. A 10kpull-up is sufficient in most applications.
Manual-Reset Input
The MAX6316_/MAX6317H/MAX6319_H/MAX6320P/
MAX6322HP feature a manual-reset input. A logic low on
MR asserts a reset. After MR transitions low to high, reset
remains asserted for the duration of the reset timeout peri-
od (tRP). The MR input is connected to VCC through an
internal 52kpull-up resistor and therefore can be left
unconnected when not in use. MR can be driven with
TTL-logic levels in 5V systems, with CMOS-logic levels in
3V systems, or with open-drain or open-collector output
devices. A normally-open momentary switch from MR to
ground can also be used; it requires no external
debouncing circuitry. MR is designed to reject fast,
negative-going transients (typically 100ns pulses). A
0.1µF capacitor from MR to ground provides additional
noise immunity.
The MR input pin is equipped with internal ESD-protection
circuitry that may become forward biased. Should MR be
driven by voltages higher than VCC, excessive current
would be drawn, which would damage the part. For
example, assume that MR is driven by a +5V supply other
than VCC. If VCC drops lower than +4.7V, MR’s absolute
maximum rating is violated [-0.3V to (VCC + 0.3V)], and
undesirable current flows through the ESD structure from
MR to VCC. To avoid this, use the same supply for MR as
the supply monitored by VCC. This guarantees that the
voltage at MR will never exceed VCC.
Watchdog Input
The MAX6316_/MAX6317H/MAX6318_H/MAX6320P/
MAX6321HP feature a watchdog circuit that monitors
the µP’s activity. If the µP does not toggle the watchdog
input (WDI) within the watchdog timeout period (tWD),
reset asserts. The internal watchdog timer is cleared by
reset or by a transition at WDI (which can detect pulses
as short as 50ns). The watchdog timer remains cleared
while reset is asserted. Once reset is released, the
timer begins counting again (Figure 7).
The WDI input is designed for a three-stated output
device with a 10µA maximum leakage current and the
capability of driving a maximum capacitive load of 200pF.
The three-state device must be able to source and sink at
least 200µA when active. Disable the watchdog function
by leaving WDI unconnected or by three-stating the driver
connected to WDI. When the watchdog timer is left open
circuited, the timer is cleared internally at intervals equal
to 7/8 of the watchdog period.
MAX6320
MAX6321
MAX6322
VCC
GND
RESET
WDI**
MR*
RESET***
MAX6320/MAX6322
MAX6320/MAX6321
MAX6321/MAX6322
*
**
***
5V SYSTEM
+5.0V+3.3V
10k
Figure 6. MAX6320P/MAX6321HP/MAX6322HP Open-Drain
RESET Output Allows Use with Multiple Supplies
tR
tS
RESET
RESET PULLED LOW
BY µC OR
RESET GENERATOR
ACTIVE
PULL-UP
TURNS ON
VCC
0.7V
0.8 x VCC
tRP
OR
µC RESET DELAY
Figure 5. Bidirectional RESET Timing Diagram
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
10 ______________________________________________________________________________________
Applications Information
Watchdog Input Current
The WDI input is internally driven through a buffer and
series resistor from the watchdog counter. For minimum
watchdog input current (minimum overall power con-
sumption), leave WDI low for the majority of the watch-
dog timeout period. When high, WDI can draw as much
as 160µA. Pulsing WDI high at a low duty cycle will
reduce the effect of the large input current. When WDI
is left unconnected, the watchdog timer is serviced
within the watchdog timeout period by a low-high-low
pulse from the counter chain.
Negative-Going V
CC
Transients
These supervisors are immune to short-duration, nega-
tive-going VCC transients (glitches), which usually do
not require the entire system to shut down. Typically,
200ns large-amplitude pulses (from ground to VCC) on
the supply will not cause a reset. Lower amplitude puls-
es result in greater immunity. Typically, a VCC transient
that goes 100mV under the reset threshold and lasts
less than 4µs will not trigger a reset. An optional 0.1µF
bypass capacitor mounted close to VCC provides addi-
tional transient immunity.
Ensuring Valid Reset Outputs
Down to V
CC
= 0
The MAX6316_/MAX6317H/MAX6318_H/MAX6319_H/
MAX6321HP/MAX6322HP are guaranteed to operate
properly down to VCC = 1V. In applications that require
valid reset levels down to VCC = 0, a pull-down resistor
to active-low outputs (push/pull and bidirectional only,
Figure 8) and a pull-up resistor to active-high outputs
(push/pull only, Figure 9) will ensure that the reset line
is valid while the reset output can no longer sink or
source current. This scheme does not work with the
open-drain outputs of the MAX6320/MAX6321/MAX6322.
The resistor value used is not critical, but it must be
large enough not to load the reset output when VCC is
above the reset threshold. For most applications,
100kis adequate.
Watchdog Software Considerations
(MAX6316/MAX6317/MAX6318/
MAX6320/MAX6321)
One way to help the watchdog timer monitor software
execution more closely is to set and reset the watchdog
input at different points in the program, rather than
pulsing the watchdog input high-low-high or low-high-
low. This technique avoids a stuck loop, in which the
watchdog timer would continue to be reset inside the
loop, keeping the watchdog from timing out.
VCC
tWD tRP
tRP
tRST
WDI
RESET
MAX6316/MAX6317
MAX6318/MAX6320
MAX6321
Figure 7. Watchdog Timing Relationship
GND
*THIS SCHEMATIC DOES NOT WORK ON THE OPEN-DRAIN
OUTPUTS OF THE MAX6321/MAX6322.
100k
VCC
VCC
RESET
MAX6317
MAX6318
MAX6319
MAX6321*
MAX6322*
Figure 9. Ensuring RESET Valid to V
CC
= 0 on Active-High
Push/Pull Outputs
GND
100k
VCC
VCC
RESET
MAX6316
MAX6318
MAX6319
Figure 8. Ensuring RESET Valid to V
CC
= 0 on Active-Low
Push/Pull and Bidirectional Outputs
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
______________________________________________________________________________________ 11
Figure 10 shows an example of a flow diagram where
the I/O driving the watchdog input is set high at the
beginning of the program, set low at the end of every
subroutine or loop, then set high again when the pro-
gram returns to the beginning. If the program should
hang in any subroutine, the problem would be quickly
corrected, since the I/O is continually set low and the
watchdog timer is allowed to time out, causing a reset
or interrupt to be issued. As described in the
Watchdog
Input Current
section, this scheme results in higher time
average WDI current than does leaving WDI low for the
majority of the timeout period and periodically pulsing it
low-high-low.
START
SET WDI
HIGH
PROGRAM
CODE
SUBROUTINE OR
PROGRAM LOOP
SET WDI LOW
RETURN
POSSIBLE
INFINITE LOOP PATH
Figure 10. Watchdog Flow Diagram
GND
WDIMR
15VCC
RESET
MAX6316
MAX6320
SOT23-5
TOP VIEW
2
34
GND
WDIMR
15VCC
RESET
MAX6317
SOT23-5
2
34
GND
WDIRESET
15VCC
RESET
MAX6318
MAX6321
SOT23-5
2
34
GND
MRRESET
15VCC
RESET
MAX6319
MAX6322
SOT23-5
2
34
__________________Pin Configurations
MAX6316
GND
MANUAL
RESET
I/O
WDIMR GND
µP
VCC
VIN
VCC
RESET RESET
Typical Operating Circuit
Table 2. Standard Versions
Table 1. Factory-Trimmed Reset Thresholds
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
12 ______________________________________________________________________________________
2.438 2.5632.463 2.500 2.538MAX63___25_ _-T 2.564 2.6962.591 2.630 2.669MAX63___26_ _-T 2.633 2.7682.660 2.700 2.741MAX63___27_ _-T 2.730 2.8702.758 2.800 2.842MAX63___28_ _-T 2.857 3.0002.886 2.930 2.974MAX63___29_ _-T 2.925 3.0752.955 3.000 3.045MAX63___30_ _-T 3.003 3.1573.034 3.080 3.126MAX63___31_ _-T 3.120 3.2803.152 3.200 3.248MAX63___32_ _-T 3.218 3.3833.251 3.300 3.350MAX63___33_ _-T 3.315 3.4853.349 3.400 3.451MAX63___34_ _-T 3.413 3.5883.448 3.500 3.553MAX63___35_ _-T 3.510 3.6903.546 3.600 3.654MAX63___36_ _-T 3.608 3.7933.645 3.700 3.756MAX63___37_ _-T 3.705 3.8953.743 3.800 3.857MAX63___38_ _-T 3.803 3.9983.842 3.900 3.959MAX63___39_ _-T 3.900 4.1003.940 4.000 4.060MAX63___40_ _-T 3.998 4.2034.039 4.100 4.162MAX63___41_ _-T 4.095 4.3054.137 4.200 4.263MAX63___42_ _-T 4.193 4.4084.236 4.300 4.365MAX63___43_ _-T 4.270 4.4904.314 4.390 4.446MAX63___44_ _-T 4.388 4.6134.433 4.500 4.568MAX63___45_ _-T 4.514 4.7464.561 4.630 4.699MAX63___46_ _-T 4.583 4.8184.630 4.700 4.771MAX63___47_ _-T 4.680 4.9204.728 4.800 4.872MAX63___48_ _-T 4.778 5.0237.827 4.900 4.974MAX63___49_ _-T
MIN MAXMIN TYP MAX 4.875 5.125
TA= -40°C to +85°CTA= +25°C
4.925 5.000 5.075MAX63___50_ _-T
PART
1.6MAX6316LUK46CY-T
MAX6316LUK29CY-T
MAX6316MUK46CY-T 4.63
2.93
4.63
MAX6320PUK29CY-T 2.93
140
140
140
MAX6316MUK29CY-T 2.93 140
MAX6317HUK46CY-T 4.63 140
MAX6318LHUK46CY-T 4.63 140
MAX6319LHUK46C-T4.63 140
MAX6320PUK46CY-T 4.63 140
1.6
1.6
1.6
1.6
1.6
1.6
TYPICAL
WATCHDOG
TIMEOUTS (sec)
1.6
ACDD
ACDE
ACDF
ACDG
ACDQ
ACDH
ACDK
ACDN
SOT
TOP MARK
ACDO
PART RESET
THRESHOLD
(V)
MINIMUM RESET
TIMEOUT
(ms)
140
Note: Nine standard versions are available, with a required order increment of 2500 pieces. Sample stock is generally held on standar d
versions only. The required order increment for nonstandard versions is 10,000 pieces. Contact factory for availability.
Contact factory for availability of these versions.
Table 3. Reset/Watchdog Timeout Periods
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
______________________________________________________________________________________ 13
__Ordering Information (continued)
Note:
These devices are available with factory-set V
CC
reset
thresholds from 2.5V to 5V, in 0.1V increments. Insert the
desired nominal reset threshold (25 to 50, from Table 1) into the
blanks following the letters UK. All devices offer factory-pro-
grammed reset timeout periods. Insert the letter corresponding
to the desired reset timeout period (A, B, C, or D from Table 3)
into the blank following the reset threshold suffix. Parts that offer
a watchdog feature (see Selector Guide) are factory-trimmed to
one of four watchdog timeout periods. Insert the letter corre-
sponding to the desired watchdog timeout period (W, X, Y, or Z
from Table 3) into the blank following the reset timeout suffix.
PART
MAX6319LHUK____-T
MAX6319MHUK____-T
MAX6320PUK____-T -40°C to +85°C
-40°C to +85°C
-40°C to +85°C
TEMP. RANGE PIN-PACKAGE
5 SOT23-5
5 SOT23-5
5 SOT23-5
MAX6321HPUK____-T -40°C to +85°C 5 SOT23-5
MAX6322HPUK____-T -40°C to +85°C 5 SOT23-5
W 4.3 6.3 9.3 ms
X71 102 153
Y 1.12 1.6 2.4
Z 17.9 25.6 38.4 sec
RESET TIMEOUT PERIODS
WATCHDOG TIMEOUT
TRANSISTOR COUNT: 191
SUBSTRATE IS INTERNALLY CONNECTED TO V+
Chip Information
sec2.241.601.12D
280200140C
403020B
21.61A
UNITSMAXTYPMINSUFFIX
ms
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
14 ______________________________________________________________________________________
Package Information
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
______________________________________________________________________________________ 15
NOTES
MAX6316–MAX6322
5-Pin µP Supervisory Circuits with
Watchdog and Manual Reset
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
16
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© 1999 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products.
NOTES