EMMICRO H6061V25SO8B

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EM MICROELECTRONIC - MARIN SA
H6061
3V Self Recovering Watchdog
Description
Features
The H6061 is a combined initialiser, watchdog and voltage
monitor. The circuit is a low voltage low power monolithic
CMOS device combining a series of voltage comparators
and a programmable timer on the same chip. The device is
specially suited to telecommunications applications where 3
V working is expected, for functions such as supply voltage
and microprocessor monitoring. The reset outputs are self
recovering after a watchdog timeout, enabling the circuit to
work with standalone systems without any external pushswitch or control signal to restart after a watchdog timeout.
The circuit provides a reset signal of both polarities. The
state of the outputs is defined down to 1.6 V. An internal
debouncer ensures power-up performance for fast-rise
supply lines.
Watchdog fully operational from 2.7 to 5.25 V
Regulated DC voltage monitor, internal voltage
reference
Self recovering watchdog function: reset goes active
after the 1st timeout period, reset goes inactive again
after the 2nd timeout period, repeated active reset signal
until the system recovers
Standard timeout period and power-on reset time
(100 ms), externally programmable from 3 ms to 3 mins
if required
Works down to 1.6 V supply voltage
Low voltage alarm prior to reset on power-down
Reset outputs of both polarities
Open drain outputs
SO8 package
Applications
Microprocessor and microcontroller systems
Point of sales equipment
Telecom products
Automotive subsystems
Microcontroller 68HC05 applications
Pin Assignment
Typical Operating Configuration
5V
H6061
VIN
VDD
RES
SAVE
NMI
TCL
RES
RES
P
I/O
VSS
GND
Fig. 2
Fig. 1
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H6061
Absolute Maximum Ratings
Parameter
Voltage VDD to VSS
Voltage at any pin to VSS
Voltage at any pin to VDD
Voltage at VIN to VSS
Current at any output
Storage temperature
Electrostatic discharge max. to
MIL-STD-833C method 3014
Handling Procedures
Symbol
VDD
VMIN
VMAX
VINMAX
IMAX
TSTO
Conditions
− 0.3 to + 5.6 V
− 0.3
+ 0.3
+ 12 V
± 10 mA
-65°C to +150°C
VSmax
1000V
This device has built-in protection against high static
voltages or electric fields; however, anti-static precautions
must be taken as for any other CMOS component. Unless
otherwise specified, proper operation can only occur when
all terminal voltages are kept within the voltage range.
Unused inputs must always be tied to a defined logic
voltage level.
Operating Conditions
Parameter
Table 1
Symbol Min.
Operating temperature
Industrial
Supply voltage
Version 11,12
RC-oscillator programming
External capacitance∗
External resistance
Stresses above these listed maximum ratings may cause
permanent damages to the device. Exposure beyond
specified operating conditions may affect device reliability or
cause malfunction.
Max. Units
TAI
-40
+85
°C
VDD
VIN
2.7
0
5.25
12
V
V
C1
R1
1
10
µF
kΩ
* Leakage < 1µA
Table 2
Electrical Characteristics
VDD = 5.0 V, TA = −40 to +85 °C, unless otherwise specified
Parameter
Symbol
VDD activation threshold
VDD deactivation threshold
Supply current
Input VIN, TCL
Leakage current
VON
VOFF
IDD
TCL input low level
TCL input high level
Leakage on pins SAVE , RES , RES
VIL
VIH
IOLK
IOL
IOL
IOL
IP
O/P drive logic low
Test Conditions
TA = 25 °C
TA = 25 °C
RC open, TCL at VDD or VSS
Min.
Typ.
2.3
Max.
Units
2.7
VON-0.3
80
140
V
V
µA
0.005
1
µA
0.8
V
V
µA
mA
mA
µA
VSS < VIP <VDD
TA = 80 °C
2.4
VOUT = VDD
VOL = 0.4 V
VDD = 3.5 V; VOL = 0.4 V
VDD = 1.6 V; VOL = 0.4 V
0.050
8
4
2
80
1
Table 3
VIN Surveillance
Voltage thresholds at TA = 25 °C
Version No.
25
Thresholds
VSH
VSL
VRL
1.54
1.50
1.46
at VDD
Threshold Voltage
Tolerance
Threshold
Ratio*
Pin VIN
Input
2.7 – 5.0 V
±10%
±2%
∼100 MΩ
* Threshold ratio defined as VSH / VSL or VSL / VRL.
Table 4
Timing Characteristics
VDD = 5.0 V, TA = −40 °C to +85 °C, unless otherwise specified
Parameter
Propagation delays
TCL to output pins
VIN to output pins
Logic transition times on
all output pins
Timeout period
TTCL input pulse width
Power-on reset debounce
Fastest pulse VIN with debounce
Symbol Test Conditions
Min.
Typ.
Max.
Units
Excluding debounce time TDB
250
4
500
10
ns
µs
TTR
Load 10 kΩ, 100 pF
30
100
ns
TTO
RC open, unshielded, TA = 25 °C
60
150
100
160
TDB
TVINL
-40 to +85 °C
10
ms
ns
ms
µs
TDIDO
TAIDO
TTCL
TTO/64
Table 5
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H6061
Timing Waveforms
Voltage Reaction: VDD Monitoring
VDD
VON
VOFF
VIN monitoring enabled
Fig. 3
Voltage Reaction: VIN Monitoring
VIN
Conditions:
VDD > VON.
No timeout.
VSH
VSL
VRL
TVIN
TTO
TDB
0
TTO
TDB
SAVE
RES
RES
Timer
Start
Power-on Reset
Timer
Stop Timer
Start
Power-on Reset
No Power-on Reset
(as VIN > VRL)
Fig. 4
Timer Reaction
TTCL
Conditions:
VIN > VRL after
power-up sequence
TCL
RES
TTO
TTO
TTO
TTO
RES
Timer
Reset
Timeout
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Timer
Reset
3
Timer
Reset
Fig. 5
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H6061
Combined Voltage and Timer Reaction
VIN
VSH
VSL
VRL
TDB
SAVE
RES
RES
TTO
TTO
TTO
TCL
Initialisation
RES
RES
Timeout Recover
Timer
Stop
Timer
Reset
Fig. 6
Block Diagram
VIN
Band-Gap
Reference
VSH
+
Save
Control
SAVE
Reset
Control
RES
+
VSL
+
VRL
+
RES
VSS
RC
OSC
Timer
TCL
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Fig. 7
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H6061
Timer Programming
A single timeout period TTO is used for the initialization reset
duration and the watchdog timeout. With pin RC
unconnected, the on-chip RC oscillator and divider chain
give a timeout period TTO of typically 100 ms. A resistor to
VDD will shorten this time, and a capacitor to VSS will
lengthen it (see Fig. 11). An approximation for calculating
trial values given in milliseconds by the formula:
Pin Description
Pin Name
Function
1
2
3
4
5
VIN
TCL
RC
VSS
RES
Voltage monitoring input
Timer clear input signal
RC oscillator tuning input
GND terminal
Reset output, open drain
6
7
8
SAVE
RES
VDD
Save output, open drain
Positive reset output, open drain
Positive supply voltage
TTO =
Table 6
Functional Description
Thresholds and Outputs
The H6061 has open-drain outputs and voltage thresholds
on pin VIN of typically 1.5 V.
Internal Voltage Comparators
The voltage comparators detect the voltage applied to pin
VIN and compare it with thresholds VSH, VSL and VRL. The
H6061 is designed for monitoring regulated DC voltages
and has bandgap thresholds independent of VDD. The
reaction of the H6061 to voltage changes on pin VIN is given
in Fig. 4. During powering-up, the outputs are active. After
VIN reaches the VSH level, pin SAVE deactivates after a
short debounce time TDB to allow for fast ramp-ups. The
initialization time TTO then passes before the two reset
outputs go inactive. Thereafter, when the voltage on pin VIN
falls below the VSL level, pin SAVE goes active low as a
first warning. If VIN then drops below the VRL level, the reset
signals go active and are guaranteed down to 1.6 V. The
reset outputs react also to timeouts (see “Timer clearing”).
Note that when the supply voltage VDD is below the level
VOFF (about 2.2 V), all outputs are in the active state for any
allowed voltage of VIN.
Voltage Programming
The H6061 was designed to give the best compromise in
normal usage (see Table 3). Its voltage threshold can be
programmed by an external resistor divider or a
potentiometer to react at proportionally higher voltage levels
(see Fig. 8 below).
Voltage Programming
Copyright © 2004, EM Microelectronic-Marin SA
⎡
⎤
⎢
⎥
⎢0.75 + (32 + C1) • 1.6 ⎥ • 8.192
⎢
V − 0.8 ⎥
⎢
⎥
4.8 + DD
R1
⎣⎢
⎦⎥
R1 min. = 10 kΩ, C1 max. = 1 µF
If R1 is in MΩ and C1 in pF, TTO will be in ms.
Choice of component values must be determined in
practice. To have a square wave of period 2TTO, simply
connect pin TCL to VDD or VSS and take the signal output
from a reset pin.
Timer Clearing
A negative edge or pulse at the TCL input longer than 150
ns will clear the timer and deactivate the reset outputs under
normal running conditions (see Fig. 3). TCL will however
have no effect either when VDD < VOFF or during the
initialization period before the deactivation of the reset pins.
Combined Voltage and Timer Action
In Fig. 6 is a typical sequence of power-up, watchdog run,
and power-down. During initialization the SAVE pin
deactivates one debounce delay time TDB after VIN rises
above VSH, or when the power line VDD rises above VON,
whichever happens last. The reset pins only deactivate one
timeout period TTO afterwards to free the watchdog timer
and end the initialization. Note that either VIN falling below
VRL threshold or VDD below VON will cause an initialization
upon recovery. Following initialization, the watchdog timer
will time out after time TTO unless at least one TCL pulse
clears it. On timeout the reset pins reactivate for a further
TTO period before deactivating again for another try. A TCL
pulse will deactivate any timeout reset, and another TCL
pulse must follow within a time TTO to keep reset inactive. If
no TCL pulses come at all, the reset pins go square-wave.
Power-down overrides all this however. A falling voltage on
VIN gives a warning SAVE = 0 signal at VIN = VSL before
activating the reset pins as soon as VIN drops below VRL.
The H6061 has fixed thresholds and low hysteresis for
monitoring regulated DC lines. Additional protection is
provided in case VDD supply falls over about 10% below VON
which thereupon activates all outputs at once.
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H6061
Typical Applications
Microprocessor Watchdog with Voltage Monitor
Selection of Watchdogs for Each Application
The H6061 is designed for monitoring regulated DC
voltages anywhere between 2.7 and 5.25 V. Typically, it is
used to monitor VDD with pin VIN tied to the midpoint of a
voltage divider (see Fig. 8). This arrangement has the
advantage of being able to trigger at selectable voltage
limits, i. e. it can be used where the regulated voltage is
below 5 VDC.
Industrial Heavy-Duty Utilisation
The H6061 debounce protects against reactions due to fastrise power lines, but absolute maximum ratings must be
respected. With its flexibility of voltage programming and
supply voltage the H6061 can allow for voltage drops along
supply lines, so it can be placed remotely, like on plug-in
boards (see Fig. 9). The H6061 is suitable for supply
voltages down to 2.7 VDC. As the H6061 is designed to be
sensitive to voltage changes, fast switching lines, like
address/data bus lines should not be run between the VDD
and VSS supply lines near the H6061 without ground-plane
shielding. Tracks from components to pin RC must be kept
very short. Pin RC if left free should be shielded with a
ground ring in noisy environments.
Copyright © 2004, EM Microelectronic-Marin SA
The H6061 has only 40 mV hysteresis specially for
monitoring regulated DC. Pin VIN must be protected from
any significant mains ripple or RFI (see Fig. 10). It should be
placed as near as possible to the point where voltage is to
be monitored. Pin VIN is protected by an internal resistor
(nominal 15 kΩ) against voltages in excess of VDD. In some
environments this may however pick up enough mains
ripple or RFI to distort the voltage detection thresholds or
even cause unwanted sporadic resets in the absence of
adequate shielding or filtering on VIN.
The H6061 has sufficient immunity to ripple and interference
on the VDD supply line, but if it is important that a system
meet severe criteria for injected spikes and RFI, then care
must be taken also decouple VDD from these influences, as
system protection must continue even under these
conditions. With normal series voltage regulators, the
regulated 5 VDC output voltage follows the DC rough
voltage within 1.5 V on powering up. If the application has
pin VIN monitoring the DC rough, the internal inputs to the
on-chip comparators will not rise above VDD if the H6061 is
correctly programmed. With switched-mode power supplies
however, the DC-rough voltage on power-up rises almost to
its working level before the 5 VDC line starts to ramp up.
The H6061 has been specially designed to work under
these extreme conditions but care must be taken not to
exceed absolute maximum ratings. In addition to the voltage
monitoring on pin VIN, a final protection is given by the
H6061 monitoring its own VDD supply. If a system
malfunction causes VDD to fall below VOFF even though pin
VIN stays high, then all outputs go active at once.
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H6061
Combined Supply Monitor, Initializer and Watchdog
1)
VIN shield or
2)
depcoupling
optional against
interference
External Programming of RC Oscillator
VDD
TCL
RC
C1
VSS
R1
TO
RES
C1 increases TTO
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VDD
TCL
R1
TCL
TO
RC
C1
R1 shortens TTO
TO
RC
RES
VSS
VDD
VSS
RES
This circuit provides independent
programming of both timeout period
and power-on reset delay.
Fig. 11
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H6061
Package Information
Dimensions of 8-Pin SOIC Package
E
D
A1
e
4
3
2
5
6
7
C
A
0 - 8°
L
B
H
Dimensions in mm
Min Nom Max
A 1.35 1.63 1.75
A1 0.10 0.15 0.25
B 0.33 0.41 0.51
C 0.19 0.20 0.25
D 4.80 4.93 5.00
E 3.80 3.94 4.00
e
1.27
H 5.80 5.99 6.20
L 0.40 0.64 1.27
8
Fig. 12
12
Fig.
Ordering Information
When ordering, please specify the complete Part Number
Part Number
H6061V25SO8A
H6061V25SO8B
Package
Delivery
Form
Package Marking
(first line)
8-pin SOIC
Stick
606125
8-pin SOIC
Tape&Reel
606125
Version
V25
Temperature
-40°C to +85°C
Note: other versions are no longer available
EM Microelectronic-Marin SA cannot assume responsibility for use of any circuitry described other than circuitry entirely
embodied in an EM Microelectronic-Marin SA product. EM Microelectronic-Marin SA reserves the right to change the circuitry
and specifications without notice at any time. You are strongly urged to ensure that the information given has not been
superseded by a more up-to-date version.
© EM Microelectronic-Marin SA, 07/04, Rev. H
Copyright © 2004, EM Microelectronic-Marin SA
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