EMMICRO H6060V15SO8B

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EM MICROELECTRONIC - MARIN SA
H6060
Self Recovering Watchdog
Description
Features
The H6060 is a monolithic low-power CMOS device
combining a programmable timer and a series of voltage
comparators on the same chip. The device is specially
suited for watchdog functions such as microprocessor and
supply voltage monitoring. If the µP system malfunctions,
the watchdog will recover it by issuing repeated active
reset signals. The voltage monitoring part provides double
security by combining both the unregulated voltage (VIN)
and
the
regulated
voltage
(VDD)
monitoring
simultaneously. The H6060 initializes the power-on reset
after VIN reaches VSH (see table 4) and VDD rises above
3.V. If VIN drops below VSL (see table 4), the H6060 gives
an advanced warning signal for register saving and if the
voltage drops further below VRL (see table 4), RES and
RES go active. The H6060 functions at any supply
voltage down to 1.6 V and is therefore particularly suited
for start-up and shut-down control of microprocessor
systems.
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 if required
Unregulated DC monitoring (VIN) with 3 standard or
programmable trigger voltages for: power-on reset
initialization, advanced power-fail warning ( SAVE ),
reset at power-down ( RES )
Regulated DC monitoring (VDD): power-on reset
initialization enabled only if VDD ≥ 3.5 V
Internal voltage reference
Works down to 1.6 V supply voltage
Push-pull or Open drain outputs
Low current consumption
SO8 package
Applications
Pin Assignment
H6060
Typical Operating Configuration
Microprocessor and microcontroller systems
Point of sales equipment
Telecom products
Automotive subsystems
Fig. 2
Fig. 1
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H6060
Absolute Maximum Ratings
Parameter
Voltage VDD to VSS
Voltage at any pin to VSS
Voltage at any pin to VDD
(except VIN)
Voltage at VIN to VSS
Current at any output
Storage temperature
all terminal voltages are kept within the voltage range.
Unused inputs must always be tied to a defined logic
voltage level.
Symbol
VDD
VMIN
Conditions
− 0.3 to + 8 V
− 0.3
VINMAX
+ 0.3
Parameter
VMIN
+ 15 V
± 10 mA
-65°C to +150°C
Operating temperature
Industrial
Supply voltage
Comparator input voltage
Version 13, 14, 15, 16
Version 11,12
RC-oscillator programming (see Fig. 15)
External capacitance∗
External resistance
IMAX
TSTO
Operating Conditions
Table 1
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.
Handling Procedures
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
Symbol Min.
Max. Units
TAI
-40
+85
°C
VDD
1.6
5.5
V
VIN
VIN
0
0
VDD
12
V
V
C1
R1
1
10
µF
kΩ
Table 2
* Leakage < 1µA
Electrical Characteristics
VDD = 5.0 V, TA = −40 to +85 °C, unless otherwise specified
Parameter
Symbol
VON
VOFF
IDD
VDD activation threshold
VDD deactivation threshold
Supply current
Input VIN, TCL
Leakage current
IIP
Input current on pin VIN
TCL input low level
TCL input high level
SAVE , RES , RES outputs
Leakage currents
IIN
VIL
VIH
IOLK
Drive currents (all versions)
IOL
IOL
IOL
IOH
IOH
IOH
Drive currents
1)
(versions 14,16)
Test Conditions
Min.
TA = 25 °C
TA = 25 °C
RC open, TCL at VDD or VSS
Typ.
3
VON − 0.3
80
VSS ≤ VIP ≤ VDD;
TA = 85 °C
Version 12; VIN = 10 V
Max.
Units
3.5
V
V
µA
140
0.005
100
1
180
0.8
µA
µA
V
V
0.05
8
1
µA
mA
mA
µA
mA
mA
µA
2.4
Version 15;
VOUT = VDD
VOL = 0.4 V
VDD = 3.5 V; VOL = 0.4 V
VDD = 1.6 V; VOL = 0.4 V
VOH = 4.0 V
VDD = 3.5 V; VOH = 2.8 V
VDD = 1.6 V; VOH = 1.2 V
3.2
2
80
3.2
2
80
8
1) Versions: 15 = open drain outputs; 14, 16 = push-pull outputs
Table 3
VIN Surveillance
Voltage thresholds at TA = 25 °C
Version
14
15, 16
1)
Comparator
Reference
Input Resistance
on VIN (RVIN)
VDD
Band-gap reference
∼100MΩ
∼100MΩ
VSH
Threshold
VSL
VRL
2.25
2.00
2.00
1.95
1.75
1.90
2)
Thresholds
Tolerance
±5%
±10%
Ratio
Tolerance
3)
±2%
±2%
1)
Version: 15 = open drain outputs; 14, 16 = push-pull outputs
at VDD = 5 V
3)
Threshold ratio tolerance is defined as the tolerance of VSH / VSL and VSL / VRL.
2)
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Table 4
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H6060
Timing Characteristics
VDD = 5.0 V, TA = −40 °C to +85 °C, unless otherwise specified
Parameter
Symbol
Test Conditions
Min.
Typ.
Max.
Units
Propagation delays
TCL to output pins
VIN to output pins
TDIDO
TAIDO
Excluding debounce time TDB
250
4
500
10
ns
µs
Logic transition times on
all output pins
TTR
Load 10 kΩ, 100 pF
30
100
ns
RC open, unshielded, TA = 25 °C
RC open, unshielded (not tested)
100
160
200
TTCL input pulse width
TTO
TTO
TTCL
ms
ms
ns
Power-on reset debounce
VIN low pulse
TDB
TVINL
Timeout period
60
45
150
TTO/64
Where debounce time TDB
Is guaranteed
ms
µs
10
Table 5
Timing Waveforms
Voltage Reaction: VDD Monitoring
VDD
VON
VOFF
VIN monitoring enabled
Fig. 3
Voltage Reaction: VIN Monitoring
VIN
VSH
VSL
VRL
Conditions:
VDD > VON.
No timeout.
TTO
TVINL
TDB
0
TTO
TDB
SAVE
RES
RES
Timer
Start
Power-on Reset
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Timer
Stop Timer
Start
Power-on Reset
3
No Power-on Reset
(as VIN > VRL)
Fig. 4
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H6060
Timer Reaction
TTCL
Conditions:
VIN > VRL after
power-up sequence
TCL
RES
TTO
TTO
RES
S
Timer
Reset
TTO
TTO
Timer
Reset
Timeout
Timer
Reset
Fig. 5
Combined Voltage and Timer Reaction
VIN
VSH
VSL
VRL
TDB
SAVE
TTO
RES
RES
TTO
TTO
TCL
RES
Initialisation
RES
Timer
Stop
Timer
Reset
Timeout Recover
Fig. 6
Block Diagram
VDD
VIN
1
2
VSH
Band-Gap
Reference
+
+
VRL
RC
SAVE
Reset
Control
RES
+
VSL
VSS
Save
Control
+
RES
3
OSC
Timer
TCL
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Version Connections
11, 12
1 and 3
13, 14
1
15, 16
2
Fig. 7
4
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H6060
Pin Description
Pin Name
Function
1
2
3
4
5
VIN
TCL
RC
VSS
RES
Voltage sense input
Timer clear input signal
RC oscillator tuning input
GND terminal
Active low reset output
6
7
8
SAVE
RES
VDD
Save output
Active high reset output
Positive supply voltage terminal
Version 14: monitor the unregulated voltage and are
ideal for programming of the VIN voltage thresholds. Fixed
resistor values can be used for programming.
Table 6
Functional Description
Supply Lines
The circuit is powered through the VDD and VSS pins. It
monitors both its own VDD supply and a voltage applied to
the VIN input.
VDD Monitoring
During power-up the VIN monitoring is disabled and RES ,
RES and SAVE stay active low as long as VDD is below
VON (3.5 V). As soon as VDD reaches the VON level, the
state of the outputs depend on the watchdog timer and
the voltage at VIN relative to the thresholds (see Fig. 4). If
the supply voltage VDD falls back below VOFF (VON – 0.3 V)
the watchdog timer and the VIN monitoring are disabled
and the outputs RES , RES and SAVE become active.
The VDD line should be free of voltage spikes.
VIN Monitoring
The analog voltage comparators compare the voltage
applied to VIN (typically connected to the input of the
voltage regulator) with the stabilized supply voltage VDD
(version 14) or with the bandgap voltage (versions 15, 16)
(see Fig. 7). At power-up, when VDD reached VON and VIN
reaches the VSH level, the SAVE output goes inactive,
and the timer starts running, setting RES and RES in
active after the time TTO (see. Fig. 4). If VIN falls below VSL
, the SAVE output goes active and stays active until VIN
rises again above VSH . If VIN falls below the voltage VRL ,
RES and RES will become active and the on-chip timer
will stop. When VIN rises again above VSH, the timer will
initiate a power-up sequence. The RES and RES outputs
may however be influenced independently of the voltage
VIN by the timer action, see section ″Combined Voltage
and Timer Action”. Monitoring the rough DC side of the
regulator, as shown in Fig. 11, is the only way to have
advanced warning of power-down. Spikes on VIN should
be filtered if they are likely to exceed the value (VSL –
VRL).
The combination of VIN and VDD monitoring provide high
system security: if VIN rises much faster than VDD , then
the device starts the power-on sequence only when VDD
reached VON (Fig. 10). Short circuits on the regulated
supply voltage can be detected.
Version 15, 16: monitor the regulated voltage. They are
suited to applications where the unregulated voltage is
not available. (The tolerance is ± 10%, see table 4. For
tighter tolerances, trimming can be used, see Fig. 9).
Monitoring of the unregulated voltage requires version 14.
These versions are based on the principle that VDD rises
with VIN on power-up an VDD holds up for a certain time
after VIN starts dropping on power-down. The versions 11
and 12 have a 100 kΩ nominal resistance from VIN to VSS
(internal voltage divider). The versions 14, 15 and 16
have high impedance VIN inputs (see Fig. 7 and Table 4)
for external threshold voltage programming by a voltage
divider on pin VIN. The levels obtained are proportional to
the internal levels VSH, VSL and VRL on the chip itself (see
Electrical Specifications).
Voltage Thresholds on VIN
The
H6060
is available with 3 different sets of
thresholds:
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H6060
Timer Programming
With pin RC unconnected, the on-chip RC oscillator
together with its divider chain give a timeout TTO of
typically 100 ms. To program different TTO, an
approximation for calculating component values is given
by the formula:
⎡
⎤
⎢
(32 + C1) ⋅ 2 ⎥
⎥ 8.192
TTO =⎢0.75 +
V −1⎥
⎢
5.5 + DD
⎢⎣
R1 ⎥⎦
R1 min. = 10 kΩ, C1 max. = 1 µF
If R1 is in MΩ and C1 in pF, TTO will be in ms.
A resistor decreases and a capacitor increases the
interval to timeout. Excellent temperature stability of TTO
can be achieved by using external components. A precise
square wave of period 2 × TTO is generated at the outputs
RES and RES when TCL is tied to either VDD or VSS.
The oscillator and watchdog timer start running when
both VIN is greater than VSH (see Fig. 6) and VDD is
greater than VON (see Fig. 3).
They will remain running while both VIN is greater than
VRL and VDD is greater than VOFF (see Fig. 3).
Timer Clearing and RES /RES Action
A negative edge or a negative pulse at the TCL input for
longer than 150 ns will reset the timer and set RES and
RES inactive. If a further TCL signal edge or pulse is
applied before TTO timeout, RES and RES will remain
inactive and the timer will again be reset to zero (see Fig.
5). If no TCL signal is applied before the TTO timeout,
RES and RES will start to generate square waves of
period 2 × TTO starting with the inactive state. The
watchdog will remain in this state until the next TCL
signal appears, or until a fresh power-up sequence.
Combined Voltage and Timer Action
The combination of voltage and timer actions is illustrated
by the sequence of events shown in Fig. 6. One timeout
period after VIN reaches VSH, during power-up, RES and
RES go inactive. A TCL pulse will have no effect until
this power-on reset delay is completed. After completing
the power-up sequence the watchdog timer starts acting.
If no TCL pulse occurs, RES and RES go active after
one timeout period TTO. After each subsequent timeout
period, without a timer clear pulse at TCL , RES and
RES change polarity providing square wave signals. A
TCL pulse clears the watchdog timer and causes RES
and RES to go inactive. A voltage drop below the VRL
level overrides the timer and immediately forces RES ,
RES and SAVE active. Any further TCL pulse has no
effect until the next power-up sequence is completed.
Typical Applications
Microprocessor Watchdog with Power-On Reset and Voltage Monitor
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H6060
Voltage Monitor with Spike Suppression
1) R/F shields for
noisy environments.
2.7 kΩ
1)
1)
Z-15
330 nF
VIN
1)
RC
VSS
VDD
H6060 11
+12 VDC
rough
5 VDC
Voltage
Regulator
SAVE
RES
TCL
Fig. 11
Watchdog and Power-On Reset
External Programming of RC Oscillator
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H6060
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.15
14
Fig.
Ordering Information
When ordering please specify complete part number.
Part Number
H6060V15SO8A
H6060V15SO8B
H6060V14SO8A
H6060V14SO8B
H6060V16SO8A
H6060V16SO8B
Version
Threshold
(see Table 4)
Output
Package
Delivery Form
Package Marking
(first line)
V15
1.95
Open
drain
8-pin SOIC
Stick
606015
8-pin SOIC
Tape&Reel
606015
8-pin SOIC
Stick
606014
8-pin SOIC
Tape&Reel
606014
8-pin SOIC
Stick
606016
8-pin SOIC
Tape&Reel
606016
V14
2.00
Push-pull
V16
1.95
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. I
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