MAXIM ICL7665CTV

19-0001; Rev 2; 8/97
Microprocessor Voltage Monitor with
Dual Over/Undervoltage Detection
The ICL7665 warns microprocessors (µPs) of overvoltage and undervoltage conditions. It draws a typical
operating current of only 3µA. The trip points and hysteresis of the two voltage detectors are individually programmed via external resistors to any voltage greater
than 1.3V. The ICL7665 will operate from any supply
voltage in the 1.6V to 16V range, while monitoring voltages from 1.3V to several hundred volts. The Maxim
ICL7665A is an improved version with a 2%-accurate
V SET1 threshold and guaranteed performance over
temperature.
The 3µA quiescent current of the ICL7665 makes it
ideal for voltage monitoring in battery-powered systems. In both battery- and line-powered systems, the
unique combination of a reference, two comparators,
and hysteresis outputs reduces the size and component count of many circuits.
________________________Applications
µP Voltage Monitoring
Low-Battery Detection
Power-Fail and Brownout Detection
Battery Backup Switching
Power-Supply Fault Monitoring
Over/Undervoltage Protection
High/Low Temperature, Pressure, Voltage Alarms
____________________________Features
♦ µP Over/Undervoltage Warning
♦ Improved Second Source
♦ Dual Comparator with Precision Internal Reference
♦ 3µA Operating Current
♦ 2% Threshold Accuracy (ICL7665A)
♦ 1.6V to 16V Supply Voltage Range
♦ On-Board Hysteresis Outputs
♦ Externally Programmable Trip Points
♦ Monolithic, Low-Power CMOS Design
______________Ordering Information
PART
ICL7665CPA
TEMP. RANGE
PIN-PACKAGE
0°C to +70°C
8 Plastic DIP
ICL7665ACPA
0°C to +70°C
8 Plastic DIP
ICL7665BCPA
0°C to +70°C
8 Plastic DIP
ICL7665CSA
0°C to +70°C
8 SO
ICL7665ACSA
0°C to +70°C
8 SO
ICL7665BCSA
0°C to +70°C
8 SO
ICL7665CJA
0°C to +70°C
8 CERDIP
ICL7665ACJA
0°C to +70°C
8 CERDIP
ICL7665BCJA
0°C to +70°C
8 CERDIP
Ordering Information continued on last page.
_________________Pin Configurations
TOP VIEW
__________Typical Operating Circuit
VIN1
OVERVOLTAGE
DETECTION
V+
1 OUT1
OUT2
7
V+
2
7
OUT2
6
SET2
5
HYST2
ICL7665
UNDERVOLTAGE
DETECTION
DIP/SO
NMI
V+ (CASE)
8
OUT1
SET2
SET1
8
HYST1
GND 4
ICL7665
3
1
SET1 3
VIN2
8
V+
OUT1
6
GND
4
HYST1
1
2
SET1
7
5
4
SIMPLE THRESHOLD DETECTOR
6
ICL7665
3
OUT2
SET2
HYST2
GND
TO-99
________________________________________________________________ Maxim Integrated Products
1
For free samples & the latest literature: http://www.maxim-ic.com, or phone 1-800-998-8800.
For small orders, phone 408-737-7600 ext. 3468.
ICL7665
_______________General Description
ICL7665
Microprocessor Voltage Monitor with
Dual Over/Undervoltage Detection
ABSOLUTE MAXIMUM RATINGS
Supply Voltage (Note 1) .........................................-0.3V to +18V
Output Voltages OUT1 and OUT2
(with respect to GND) (Note 1) ..........................-0.3V to +18V
Output Voltages HYST1 and HYST2
(with respect to V+) (Note 1) .............................+0.3V to -18V
Input Voltages SET1 and SET2
(Note 1)........................................(GND - 0.3V) to (V+ + 0.3V)
Maximum Sink Output Current
OUT1 and OUT2.............................................................25mA
Maximum Source Output Current
HYST1 and HYST2 ........................................................-25mA
Continuous Power Dissipation (TA = +70°C)
Plastic DIP (derate 9.09mW/°C above +70°C) ............727mW
SO (derate 5.88mW/°C above +70°C) ........................471mW
CERDIP (derate 8.00mW/°C above +70°C) ................640mW
TO-99 (derate 6.67mW/°C above +70°C) ...................533mW
Operating Temperature Ranges
ICL7665C_ _.......................................................0°C to +70°C
ICL7665I_ _ .....................................................-20°C to +85°C
ICL7665E_ _....................................................-40°C to +85°C
Storage Temperature Range .............................-65°C to +160°C
Lead Temperature (soldering, 10sec) .............................+300°C
Note 1: Due to the SCR structure inherent in the CMOS process used to fabricate these devices, connecting any terminal to voltages greater than (V+ + 0.3V) or less than (GND - 0.3V) may cause destructive latchup. For this reason, we recommend
that inputs from external sources that are not operating from the same power supply not be applied to the device before its
supply is established, and that in multiple supply systems, the supply to the ICL7665 be turned on first. If this is not possible, currents into inputs and/or outputs must be limited to ±0.5mA and voltages must not exceed those defined above.
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.
ELECTRICAL CHARACTERISTICS
(V+ = 5V, TA = +25°C, unless otherwise noted.)
PARAMETER
SYMBOL
CONDITIONS
ICL7665
Operating Supply Voltage
V+
ICL7665A
ICL7665B
Supply Current
I+
GND ≤ VSET1,
VSET2 ≤ V+,
all outputs open
circuit
VSET
TA = TMIN to TMIN
1.8
16
TA = TMIN to TMIN
2.0
16
TA = +25°C
1.6
10
TA = TMIN to TMIN
1.8
10
ICL7665,
TA = +25°C;
ICL7665A,
TA = TMIN to TMAX
V+ = 2V
2.5
10
V+ = 9V
2.6
10
V+ = 15V
2.9
15
ICL7665B,
TA = +25°C
V+ = 2V
2.5
10
V+ = 9V
2.6
10
ICL7665A, TA = +25°C
VSET Tempco
2
MAX
16
ICL7665A, TA = TMIN to TMAX
Supply Voltage Sensitivity
of VSET1, VSET2
TYP
1.6
ICL7665, ICL7665B, TA = +25°C
Input Trip Voltage
MIN
TA = +25°C
ROUT1, ROUT2, RHYST1, RHYST2 = 1MΩ
VSET1
1.150
1.300
1.450
VSET2
1.200
1.300
1.400
VSET1
1.275
1.300
1.325
VSET2
1.225
1.300
1.375
VSET1
1.250
1.300
1.350
VSET2
1.215
1.300
1.385
UNITS
V
µA
V
100
ppm/°C
0.004
%/V
_______________________________________________________________________________________
Microprocessor Voltage Monitor with
Dual Over/Undervoltage Detection
(V+ = 5V, TA = +25°C, unless otherwise noted.)
SYMBOL
PARAMETER
Output Leakage Current
IOLK,
IHLK
VOUT1 Saturation
Voltage
CONDITIONS
TYP
MAX
All grades, VSET = 0V or
VSET ≥ 2V, TA = +25°C
OUT1, OUT2
10
200
HYST1, HSYT2
-10
-100
ICL7665, ICL7665A,
V+ = 15V,
TA = TMIN to TMAX
OUT1, OUT2
2000
HYST1, HSYT2
-500
ICL7665B, V+ = 9V,
TA = TMIN to TMAX
OUT1, OUT2
2000
VSET1 = 2V,
IOUT1 = 2mA
VHYST1 Saturation
Voltage
VSET1 = 2V,
IHYST1 = -0.5mA
VOUT2 Saturation
Voltage
VSET2 = 0V,
IOUT2 = 2mA
VSET2 = 2V,
IHYST2 = -0.2mA
VHYST2 Saturation
Voltage
VSET2 = 2V,
IHYST2 = -0.5mA
VSET Input Leakage
Current
ISET
MIN
nA
HYST1, HSYT2
-500
ICL7665, ICL7665B: V+ = 2V
0.20
ICL7665A: V+ = 2V
0.20
All grades: V+ = 5V
0.10
0.30
ICL7665, ICL7665A: V+ = 15V
0.06
0.20
ICL7665B: V+ = 9V
0.06
0.25
All grades: V+ = 2V
-0.15
-0.30
All grades: V+ = 5V
-0.05
-0.15
ICL7665, ICL665A: V+ = 15V
-0.02
-0.10
ICL7665B: V+ = 9V
-0.02
-0.15
All grades: V+ = 2V
0.20
0.50
All grades: V+ = 5V
0.15
0.30
ICL7665, ICL665A: V+ = 15V
0.11
0.25
ICL7665B: V+ = 9V
0.11
0.30
All grades: V+ = 2V
-0.25
-0.80
All grades: V+ = 5V
-0.43
-1.00
ICL7665: V+ = 15V
-0.35
-0.80
ICL7665A: V+ = 15V
-0.35
-1.00
ICL7665B: V+ = 9V
-0.35
-1.00
±0.01
±10
GND ≤ VSET ≤ V+
VSET Input Change for
Complete Output
Change
∆VSET
ROUT = 4.7kΩ, RHYST = 20kΩ,
VOUTLO = 1% V+, VOUTHI = 99% V+
0.1
Difference in Trip
Voltage
VSET1–
VSET2
ROUT, RHYST = 1MΩ
±5
ROUT, RHYST = 1MΩ
±0.1
Output/Hysteresis
Difference
UNITS
0.50
V
V
V
V
nA
mV
±50
mV
mV
_______________________________________________________________________________________
3
ICL7665
ELECTRICAL CHARACTERISTICS (continued)
ICL7665
Microprocessor Voltage Monitor with
Dual Over/Undervoltage Detection
AC OPERATING CHARACTERISTICS
(V+ = 5V, TA = +25°C, unless otherwise noted.)
PARAMETER
SYMBOL
CONDITIONS
MIN
tSO1d
tSH1d
Output Delay Time,
Input Going High
tSO2d
VSET switched from 1.0V to 1.6V,
ROUT = 4.7kΩ, CL = 12pF,
RHYST = 20kΩ
90
tSH1d
55
75
VSET switched from 1.6V to 1.0V,
ROUT = 4.7kΩ, CL = 12pF,
RHYST = 20kΩ
80
60
tO1r
0.6
tH1r
VSET switched between 1.0V and 1.6V,
ROUT = 4.7kΩ, CL = 12pF,
RHYST = 20kΩ
0.8
0.7
tO1f
Output Fall Times
tH1f
µs
7.5
tH2r
tO2f
µs
60
tSH2d
tO2r
Output Rise Times
UNITS
µs
55
tSH2d
tSO2d
MAX
85
tSO1d
Output Delay Time,
Input Going Low
TYP
0.6
VSET switched between 1.0V and 1.6V,
ROUT = 4.7kΩ, CL = 12pF,
RHYST = 20kΩ
0.7
µs
4.0
tH2f
1.8
_______________________________________________________Switching Waveforms
1.6V
INPUT
VSET1,VSET2
1.0V
t SO1d
t SO1d
V+ (5V)
OUT1
t O1r
t O1f
HYST1
GND
V+ (5V)
t SH1d
t H1r
GND
t SH1d
t H1f
t SO2d
t SO2d
V+ (5V)
OUT2
t O2r
HYST2
t O2f
t SH2d
4
V+ (5V)
GND
t SH2d
t H2r
GND
t H2f
_______________________________________________________________________________________
Microprocessor Voltage Monitor with
Dual Over/Undervoltage Detection
SUPPLY CURRENT AS A
FUNCTION OF SUPPLY VOLTAGE
0V ≤ VSET1, VSET2 ≤ V+
4.5
V+ = 9V
V+ = 15V
0.5
3.5
TA = -20°C
3.0
TA = +25°C
2.5
TA = +70°C
2.0
1.5
5
15
10
2
4
6
8
10 12
SUPPLY VOLTAGE (V)
14
16
-0.8
V+ = 9V
-1.2
V+ = 2V
-2.0
ICL7665-05
V+ = 15V
V+ = 9V
V+ = 5V
-3
V+ = 2V
-4
-4
HYST1 OUTPUT CURRENT (mA)
0
1.5
V+ = 2V
V+ = 5V
V+ = 9V
V+ = 15V
1.0
0.5
0
-5
-8
60
2.0
-1
-2
0
20
40
AMBIENT TEMPERATURE (°C)
OUT2 SATURATION VOLTAGE AS A
FUNCTION OF OUTPUT CURRENT
0
HYST2 OUTPUT SATURATION VOLTAGE (V)
ICL7665-04
V+ = 15V
-12
-20
HYST2 OUTPUT SATURATION VOLTAGE
vs. HYST2 OUTPUT CURRENT
-0.4
-16
V+ = 2V
0
0
20
0
-20
1.5
0.5
HYST1 OUTPUT SATURATION VOLTAGE
vs. HYST1 OUTPUT CURRENT
V+ = 5V
2.0
0.5
IOUT OUT1 (mA)
-1.6
2.5
1.0
VOLTAGE SATURATION (V)
0
3.0
1.0
0
V+ = 9V
3.5
ICL7665-06
1.0
V+ = 15V
4.0
SUPPLY CURRENT (µA)
SUPPLY CURRENT (µA)
V+ = 5V
0V ≤ VSET1, VSET2 ≤ V+
4.5
4.0
1.5
0
HYST1 OUTPUT SATURATION VOLTAGE (V)
5.0
ICL7665-03
V+ = 2V
VOLTAGE SATURATION (V)
5.0
ICL7665-01
2.0
SUPPLY CURRENT AS A
FUNCTION OF AMBIENT TEMPERATURE
ICL7665-02
OUT1 SATURATION VOLTAGE AS A
FUNCTION OF OUTPUT CURRENT
-5
-4
-3
-2
-1
HYST2 OUTPUT CURRENT (mA)
0
0
5
10
15
20
IOUT OUT2 (mA)
_______________________________________________________________________________________
5
ICL7665
__________________________________________Typical Operating Characteristics
(TA = +25°C, unless otherwise noted.)
ICL7665
Microprocessor Voltage Monitor with
Dual Over/Undervoltage Detection
V+
4.7k
OUT1
HYST1
INPUT
1.6V
V+
8
OUT2
7
SET1
SET2
6
GND
HSYT2
5
1
OUT1
2
HYST1
3
4
ICL7665
1.0V
4.7k
OUT2
HSYT2
20k
20k
12pF
12pF
12pF
12pF
Figure 1. Test Circuit
_______________Detailed Description
As shown in the block diagram of Figure 2, the Maxim
ICL7665 combines a 1.3V reference with two comparators, two open-drain N-channel outputs, and two
open-drain P-channel hysteresis outputs. The reference and comparator are very low-power linear CMOS
circuits, with a total operating current of 10µA maximum, 3µA typical. The N-channel outputs can sink
greater than 10mA, but are unable to source any current. These outputs are suitable for wire-OR connections
and are capable of driving TTL inputs when an external
pull-up resistor is added.
The ICL7665 Truth Table is shown in Table 1. OUT1 is
an inverting output; all other outputs are noninverting.
HYST1 and HYST2 are P-channel current sources
whose sources are connected to V+. OUT1 and OUT2
are N-channel current sinks with their sources connected to ground. Both OUT1 and OUT2 can drive at least
one TTL load with a VOL of 0.4V.
V+
SET1
HYST1
OUT1
1.3V
BANDGAP
REFERENCE
TO V+
HYST2
SET2
OUT2
Table 1. ICL7665 Truth Table
INPUT*
OUTPUT
HYSTERESIS
VSET1 > 1.3V
OUT1 = ON = LOW
HYST1 = ON = HI
VSET1 < 1.3V
OUT1 = OFF = HI
HYST1 = OFF = LOW
VSET2 > 1.3V
OUT2 = OFF = HI
HYST2 = ON = HI
VSET2 < 1.3V
OUT2 = ON = LOW
HYST2 = OFF = LOW
OUT1 is an inverting output; all others are noninverting. OUT1
and OUT2 are open-drain, N-channel current sinks. HYST1
and HYST2 are open-drain, P-channel current sinks.
Figure 2. Block Diagram
In spite of the very low operating current, the ICL7665
has a typical propagation delay of only 75µs. Since the
comparator input bias current and the output leakages
are very low, high-impedance external resistors can be
used. This design feature minimizes both the total supply current used and loading on the voltage source that
is being monitored.
* See Electrical Characteristics
6
_______________________________________________________________________________________
Microprocessor Voltage Monitor with
Dual Over/Undervoltage Detection
V+
V+
OUT1
OUT2
OUT1
VIN1
VIN2
R22
R21
OUT2
R22
ICL7665
R31
SET2
SET1
SET2
R12
R32
HYST2
HYST1
R11
VIN2
R21
ICL7665
SET1
ICL7665
VIN1
R12
R11
V+
OUT1
OUT1
VL1
VIN1
0V
VU1
VIN1
VTRIP1
OUT2
V+
OUT2
VIN2
VTRIP2
0V
VIN2
Figure 3. Simple Threshold Detector
Basic Over/Undervoltage
Detection Circuits
Figures 3, 4, and 5 show the three basic voltage detection circuits.
The simplest circuit, depicted in Figure 3, does not
have any hysteresis. The comparator trip-point formulas
can easily be derived by observing that the comparator
changes state when the VSET input is 1.3V. The external resistors form a voltage divider that attenuates the
input signal. This ensures that the VSET terminal is at
1.3V when the input voltage is at the desired comparator trip point. Since the bias current of the comparator
is only a fraction of a nanoamp, the current in the voltage divider can be less than one microamp without losing accuracy due to bias currents. The ICL7665A has a
2% threshold accuracy at +25°C, and a typical temperature coefficient of 100ppm/°C including comparator
offset drift, eliminating the need for external potentiometers in most applications.
Figure 4 adds another resistor to each voltage detector.
This third resistor supplies current from the HYST output whenever the VSET input is above the 1.3V threshold. As the formulas show, this hysteresis resistor
affects only the lower trip point. Hysteresis (defined as
VL2 VU2
Figure 4. Threshold Detector with Hysteresis
the difference between the upper and lower trip points)
keeps noise or small variations in the input signal from
repeatedly switching the output when the input signal
remains near the trip point for a long period of time.
The third basic circuit, Figure 5, is suitable only when the
voltage to be detected is also the power-supply voltage for
the ICL7665. This circuit has the advantage that all of the
current flowing through the input divider resistors flows
through the hysteresis resistor. This allows the use of
higher-value resistors, without hysteresis output leakage
having an appreciable effect on the trip point.
Resistor-Value Calculations
Figure 3
1) Choose a value for R11. This value determines the
amount of current flowing though the input divider,
equal to VSET / R11. R11 can typically be in the
range of 10kΩ to 10MΩ.
2) Calculate R21 based on R11 and the desired trip
point:
(
) (
)
VTRIP – VSET
VTRIP – 1.3V
R21 = R11 ——————— = R11 ——————
VSET
1.3V
_______________________________________________________________________________________
7
ICL7665
Microprocessor Voltage Monitor with
Dual Over/Undervoltage Detection
Figure 5
1) Select a value for R11, usually between 10kΩ and
10MΩ.
2) Calculate R21:
VIN
R31
R32
HYST1
V+
(
R22
ICL7665
SET1
SET2
OUT1
OUT2
UNDERVOLTAGE
OVERVOLTAGE
GND
R11
R12
OUT1
VL1 VU1
OUT2
VIN
)
)
VU – VL
R31 = R11 —————
VSET
4) As in the other circuits, all three resistor values may
be scaled up or down in value without changing VU
and VL. VU and VL depend only on the ratio of the
three resistors, if the absolute values are such that
the hysteresis output resistance and the leakage
currents of the VSET input and hysteresis output can
be ignored.
Fault Monitor for a Single Supply
Figure 5. Threshold Detector, VIN = V+
Figure 4
1) Choose a resistor value for R11. Typical values are
in the 10kΩ to 10MΩ range.
2) Calculate R21 for the desired upper trip point, VU,
using the formula:
)
(
)
VU - VSET
VU – 1.3V
R21 = R11 —————— = R11 —————
VSET
1.3V
3) Calculate R31 for the desired amount of hysteresis:
(R21) (V+ – 1.3V)
(R21) (V+ – VSET)
R31 = ————————— = —————————
VU – VL
VU – VL
or, if V+ = VIN:
(R21) (VL – VSET)
(R21) (VL – 1.3V)
R31 = ————————— = —————————
VU – VL
VU – VL
4) The trip voltages are not affected by the absolute
value of the resistors, as long as the impedances
are high enough that the resistance of R31 is
much greater than the HYST output’s resistance,
and the current through R31 is much higher than
the HYST output’s leakage current. Normally, R31
will be in the 100kΩ to 22MΩ range. Multiplying or
dividing all three resistors by the same factor will
not affect the trip voltages.
8
(
(
VL – 1.3V
= R11 —————
1.3
__________Applications Information
VL2 VU2
(
)
VL – VSET
R21 = R11 ——————
VSET
3) Calculate R31:
HYST2
R21
Figure 6 shows a typical over/undervoltage fault monitor
for a single supply. In this case, the upper trip points (controlling OUT1) are centered on 5.5V, with 100mV of hysteresis (VU = 5.55V, VL = 5.45V); and the lower trip points
(controlling OUT2) are centered on 4.5V, also with 100mV
of hysteresis. OUT1 and OUT2 are connected together in
a wire-OR configuration to generate a power-OK signal.
Multiple-Supply Fault Monitor
The ICL7665 can simultaneously monitor several power
supplies, as shown in Figure 7. The easiest way to calculate
the resistor values is to note that when the VSET input is at
the trip point (1.3V), the current through R11 is 1.3V / R11.
The sum of the currents through R21A, R21B and R31 must
equal this current when the two input voltages are at the
desired low-voltage detection point. Ordinarily, R21A and
R21B are chosen so that the current through the two resistors is equal. Note that, since the voltage at the ICL7665
VSET input depends on the voltage of both supplies being
monitored, there will be some interaction between the lowvoltage trip points for the two supplies. In this example,
OUT1 will go low when either supply is 10% below nominal
(assuming the other supply is at the nominal voltage), or
when both supplies are 5% or more below their nominal
voltage. R31 sets the hysteresis, in this case, to about 43mV
at the 5V supply or 170mV at the 15V supply. The second
section of ICL7665 can be used to detect overvoltage or, as
shown in Figure 7, can be used to detect the absence of
negative supplies. Note that the trip points for OUT2 depend
on both the voltages of the negative power supplies and
the actual voltage of the +5V supply.
_______________________________________________________________________________________
Microprocessor Voltage Monitor with
Dual Over/Undervoltage Detection
Nickel cadmium (NiCd) batteries are excellent rechargeable power sources for portable equipment, but care
must be taken to ensure that NiCd batteries are not
damaged by overdischarge. Specifically, a NiCd battery
should not be discharged to the point where the polarity
of the lowest-capacity cell is reversed, and that cell is
reverse charged by the higher-capacity cells. This reverse
charging will dramatically reduce the life of a NiCd battery.
The Figure 8 circuit both prevents reverse charging and
gives a low-battery warning. A typical low-battery warning
voltage is 1V per cell. Since a NiCd “9V” battery is ordinarily made up of six cells with a nominal voltage of 7.2V,
a low-battery warning of 6V is appropriate, with a small
hysteresis of 100mV. To prevent overdischarge of a battery, the load should be disconnected when the battery
voltage is 1V x (N – 1), where N = number of cells. In this
case, the low-battery load disconnect should occur at
5V. Since the battery voltage will rise when the load is
disconnected, 800mV of hysteresis is used to prevent
repeated on/off cycling.
Power-Fail Warning and
Power-Up/Power-Down Reset
Figure 9 illustrates a power-fail warning circuit that
monitors raw DC input voltage to the 7805 three-terminal 5V regulator. The power-fail warning signal goes
high when the unregulated DC input falls below 8.0V.
When the raw DC power source is disconnected or the
AC power fails, the voltage on the input of the 7805
decays at a rate of IOUT / C (in this case, 200mV/ms).
Since the 7805 will continue to provide a 5V output at
1A until VIN is less than 7.3V, this circuit will give at
least 3.5ms of warning before the 5V output begins to
drop. If additional warning time is needed, either the
trip voltage or filter capacitance should be increased,
or the output current should be decreased.
The ICL7665 OUT2 is set to trip when the 5V output has
decayed to 3.9V. This output can be used to prevent
the microprocessor from writing spurious data to a
CMOS battery-backup memory, or can be used to activate a battery-backup system.
AC Power-Fail and Brownout Detector
By monitoring the secondary of the transformer, the circuit in Figure 10 performs the same power-failure warning function as Figure 9. With a normal 110V AC input
to the transformer, OUT1 will discharge C1 every
16.7ms when the peak transformer secondary voltage
exceeds 10.2V. When the 110V AC power-line voltage
is either interrupted or reduced so that the peak voltage
is less than 10.2V, C1 will be charged through R1.
OUT2, the power-fail warning output, goes high when
the voltage on C1 reaches 1.3V. The time constant R1 x
C1 determines the delay time before the power-fail warning
signal is activated, in this case 42ms or 21⁄2 line cycles.
Optional components R2, R3 and Q1 add hysteresis by
increasing the peak secondary voltage required to discharge C1 once the power-fail warning is active.
Battery Switchover Circuit
The circuit in Figure 11 performs two functions: switching the power supply of a CMOS memory to a backup
battery when the line-powered supply is turned off, and
lighting a low-battery-warning LED when the backup
battery is nearly discharged. The PNP transistor, Q1,
connects the line-powered +5V to the CMOS memory
whenever the line-powered +5V supply voltage is
greater than 3.5V. The voltage drop across Q1 will only
be a couple of hundred millivolts, since it will be saturated. Whenever the input voltage falls below 3.5V,
OUT1 goes high, turns off Q1, and connects the 3V
lithium cell to the CMOS memory.
The second voltage detector of the ICL7665 monitors the
voltage of the lithium cell. If the battery voltage falls below
2.6V, OUT2 goes low and the low-battery-warning LED
turns on (assuming that the +5V is present, of course).
Another possible use for the second section of the
ICL7665 is the detection of the input voltage falling
below 4.5V. This signal could then be used to prevent
the microprocessor from writing spurious data to the
CMOS memory while its power-supply voltage is outside its guaranteed operating range.
Simple High/Low Temperature Alarm
The circuit in Figure 12 is a simple high/low temperature alarm, which uses a low-cost NPN transistor as the
sensor and an ICL7665 as the high/low detector. The
NPN transistor and potentiometer R1 form a Vbe multiplier whose output voltage is determined by the Vbe of
the transistor and the position of R1’s wiper arm. The
voltage at the top of R1 will have a temperature coefficient of approximately -5mV/°C. R1 is set so that the
voltage at VSET2 equals the VSET2 trip voltage when the
temperature of the NPN transistor reaches the level
selected for the high-temperature alarm. R2 can be
adjusted so that the voltage at VSET1 is 1.3V when the
NPN transistor’s temperature reaches the low-temperature limit.
_______________________________________________________________________________________
9
ICL7665
Combination Low-Battery Warning and
Low-Battery Disconnect
ICL7665
Microprocessor Voltage Monitor with
Dual Over/Undervoltage Detection
+5V SUPPLY
HYST1
324k
13M
5%
V+
R21A
274k
100k
SET2
OUT1
+15V
UNDERVOLTAGE
100k
DETECTOR
VU ≈ 4.55V
VL ≈ 4.45V
OUT2
ICL7665
SET2
R21B
1.02M
100k
22M
249k
7.5M
5%
ICL7665
V+
HYST1
R31
22M
+5V
HYST2
SET1
OVERVOLTAGE
DETECTOR
VU ≈ 5.55V
VL ≈ 5.45V
+5V
HYST2
SET1
OUT2
R11
49.9k
301k
OUT1
787k
+5V
-5V
-15V
POWER OK
POWER OK
Figure 6. Fault Monitor for a Single Supply
Figure 7. Multiple-Supply Fault Monitor
R31
R32
1M
V+
V+
HYST1
R21
OUT2
OUT1
HYST2
SENSE
R22
ICL7665
SET1
+5V, 1A
OUTPUT
100Ω
ICL7663
SET
SHDN
SET2
R11
R12
OUT1
GND
OUT2
GND
LOW-BATTERY WARNING
LOW-BATTERY SHUTDOWN
Figure 8. Low-Battery Warning and Low-Battery Disconnect
UNREGULATED
DC INPUT
4700µF
5V, 1A
5V, 1A
OUTPUT
7805
5V REGULATOR
470µF
BACK-UP
BATTERY
20V CENTER
TAPPED TRANS
10VAC
60Hz
7805
5V REGULATOR
4700µF
+5V
V+
V+
HYST1
HYST1
HYST2
ICL7665
715k
SET1
ICL7665
2.2M
SET1
SET2
130k
1M
OUT1
R1
681k
22M
5.6M
OUT2
HYST2
RESET
OR
WRITE
ENABLE
R2
1M
100k
Q1
SET2
OUT2
OUT1
R3
1M
C1
POWER-FAIL WARNING
Figure 9. Power-Fail Warning and Power-Up/Power-Down Reset
10
Figure 10. AC Power-Fail and Brownout Detector
______________________________________________________________________________________
POWER-FAIL
WARNING
Microprocessor Voltage Monitor with
Dual Over/Undervoltage Detection
ICL7665
VCC TO
CMOS
MEMORY
Q1
LINE-POWERED
+5V INPUT
100k
1µF
1k
2N7000
2N4393
1M
OUT1
V+
HYST1
HYST2
5.6M
22M
ICL7665
2.4M
SET1
3V
LITHIUM
CELL
1.15M
1%
SET2
1M
GND
1M
1%
OUT2
220Ω
Figure 11. Battery Switchover Circuit
9V
V+
TEMPERATURE
SENSOR
(GENERAL
PURPOSE NPN
TRANSISTOR)
HYST2
R3
470k
R4
22M
R6
22M
ICL7665
SET2
R1, 1M
HIGHTEMPERATURE
LIMIT
ADJUSTMENT
HYST1
SET1
R5
27k
OUT2
LOW-TEMPERATURE
LIMIT ADJUST
OUT1
R7
1.5M
R2
1M
ALARM
SIGNAL FOR
DRIVING LEDS,
BELLS, ETC.
Figure 12. Simple High/Low Temperature Alarm
______________________________________________________________________________________
11
ICL7665
Microprocessor Voltage Monitor with
Dual Over/Undervoltage Detection
_______________________SCR Latchup
Like all junction-isolated CMOS circuits, the ICL7665 has
an inherent four-layer or SCR structure that can be
triggered into destructive latchup under certain conditions. Avoid destructive latchup by following these
precautions:
1) If either VSET terminal can be driven to a voltage
greater than V+ or less than ground, limit the input
current to 500µA maximum. Usually, an input voltage divider resistance can be chosen to ensure
the input current remains below 500µA, even
when the input voltage is applied before the
ICL7665 V+ supply is connected.
2) Limit the rate-of-rise of V+ by using a bypass
capacitor near the ICL7665. Rate-of-rise SCRs
rarely occur unless: a) the battery has a low
impedance—as is the case with NiCd and lead
acid batteries; b) the battery is connected directly
to the ICL7665 or is switched on via a mechanical
switch with low resistance; or c) there is little or no
input filter capacitance near the ICL7665. In linepowered systems, the rate-of-rise is usually limited
by other factors and will not cause a rate-of-rise
SCR action under normal circumstances.
3) Limit the maximum supply voltage (including transient spikes) to 18V. Likewise, limit the maximum voltage on OUT1 and OUT2 to +18V and the maximum voltage on HYST1 and HYST2 to 18V below V+.
___________________Chip Topography
V+
OUT2
0.066"
(1.42mm)
OUT1
SET2
HYST2
HYST1
SET1
V-
0.084"
(1.63mm)
TRANSISTOR COUNT: 38
SUBSTRATE CONNECTED TO V+.
_Ordering Information (continued)
PART
TEMP. RANGE
PIN-PACKAGE
ICL7665CTV
0°C to +70°C
8 TO-99
ICL7665ACTV
0°C to +70°C
8 TO-99
ICL7665BCTV
0°C to +70°C
8 TO-99
ICL7665AC/D
0°C to +70°C
Dice*
ICL7665IPA
-20°C to +85°C
8 Plastic DIP
ICL7665IJA
-20°C to +85°C
8 CERDIP
ICL7665EPA
-40°C to +85°C
8 Plastic DIP
ICL7665AEPA
-40°C to +85°C
8 Plastic DIP
ICL7665ESA
-40°C to +85°C
8 SO
ICL7665AESA
-40°C to +85°C
8 SO
*Contact factory for dice specifications.
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.
12 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 1997 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.