NSC LM612IM

LM612
Dual-Channel Comparator and Reference
General Description
Features
The dual-channel comparator consists of two individual
comparators, having an input voltage range that extends
down to the negative supply voltage V b. The common
open-collector output can be driven low by either half of the
LM612. This configuration makes the LM612 ideal for use
as a window comparator. The input stages of the comparator have lateral PNP input transistors which maintain low
input currents for large differential input voltages and swings
above V a .
The 1.2V voltage reference, referred to the Vb terminal, is a
two-terminal shunt-type band-gap similar to the LM185-1.2
series, with voltage accuracy of g 0.6% available. The reference features operation over a shunt current range of 17 mA
to 20 mA, low dynamic impedance, and broad capacitive
load range.
As a member of National’s Super-Block TM family, the
LM612 is a space-saving monolithic alternative to a multichip solution, offering a high level of integration without sacrificing performance.
COMPARATORS
Y Low operating current
Y Wide supply voltage range
Y Open-collector outputs
Y Input common-mode range
Y Wide differential input voltage
REFERENCE
Y Fixed output voltage
Y Tight initial tolerance available
Y Wide operating current range
Y Tolerant of load capacitance
300 mA
4V to 36V
Vb to (V a b 1.8V)
g 36V
1.24V
g 0.6% (25§ C)
17 mA to 20 mA
Applications
Y
Y
Y
Voltage window comparator
Power supply voltage monitor
Dual-channel fault monitor
Connection Diagram
TL/H/11058 – 1
Top View
Ordering Information
For information about surface-mount packaging of this device, please contact the Analog Product Marketing group at
National Semiconductor Corporation headquarters.
Reference
Tolerances
g 0.6% at 25§ C,
80 ppm/§ C Max
Temperature Range
Package
NSC
Package
Number
8-Pin
Molded DIP
N08E
8-Pin
Ceramic DIP
J08A
LM612IN
8-Pin
Molded DIP
N08E
LM612IM
8-Pin Narrow
Surface Mount
M08A
Military
b 55§ C s TJ s a 125§ C
Industrial
b 40§ C s TJ a 85§ C
LM612AMN
LM612AIN
LM612AMJ/883
(Note 13)
g 2.0% at 25§ C,
150 ppm/§ C Max
LM612MN
Super-BlockTM is a trademark of National Semiconductor Corporation.
C1995 National Semiconductor Corporation
TL/H/11058
RRD-B30M115/Printed in U. S. A.
LM612 Dual-Channel Comparator and Reference
February 1995
Absolute Maximum Ratings (Note 1)
Thermal Resistance, Junction-to-Ambient (Note 5)
N Package
100§ C/W
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales
Office/Distributors for availability and specifications.
Voltage on Any Pin Except VR (referred to Vb pin)
(Note 2)
36V (Max)
b 0.3V (Min)
(Note 3)
g 20 mA
Current through Any Input Pin and VR Pin
g 36V
Differential Input Voltage
Output Short-Circuit Duration
(Note 4)
b 65§ C s TJ s a 150§ C
Storage Temperature Range
Maximum Junction Temperature
150§ C
Soldering Information
N Package
Soldering (10 seconds)
260§ C
ESD Tolerance (Note 6)
g 1 kV
Operating Temperature Range
LM612AI, LM612I
LM612AM, LM612M
b 40§ C s TJ s a 85§ C
b 55§ C s TJ s a 125§ C
Electrical Characteristics These specifications apply for Vb e GND e 0V, V a e 5V, VCM e VOUT e V a /2,
IR e 100 mA, unless otherwise specified. Limits in standard typeface are for TJ e 25§ C; limits in boldface type apply over the
Operating Temperature Range.
Symbol
Parameter
Conditions
Typical
(Note 7)
LM612AM
LM612AI
Limits
(Note 8)
LM612M
LM612I
Limits
(Note 8)
Units
COMPARATORS
IS
Total Supply Current
V a Current, RLOAD e % ,
3V s V a s 36V
150
170
250
300
250
300
mA Max
mA Max
VOS
Offset Voltage over
V a Range
4V s V a s 36V, RL e 15 kX
1.0
2.0
3.0
6.0
5.0
7.0
mV Max
mV Max
VOS
Offset Voltage over
VCM Range
0V s VCM s (V a b1.8V)
V a e 30V, RL e 15 kX
1.0
1.5
3.0
6.0
5.0
7.0
mV Max
mV Max
DVOS
DT
Average Offset Voltage
Drift
IB
Input Bias Current
IOS
Input Offset Current
AV
Voltage Gain
tR
ISINK
IL
15
mV/§ C
5
8
25
30
35
40
nA Max
nA Max
0.2
0.3
4
5
4
5
nA Max
nA Max
RL e 10 kX to 36V,
2V s VOUT s 27V
500
100
50
50
V/mV Min
V/mV
Large Signal Response
Time
V a IN e 1.4V, VbIN e TTL
Swing, RL e 5.1 kX
1.5
2.0
Output Sink Current
V a IN e 0V, VbIN e 1V,
VOUT e 1.5V
20
13
10
8
10
8
mA Min
mA Min
VOUT e 0.4V
2.8
2.4
1.0
0.5
0.8
0.5
mA Min
mA Min
0.1
0.2
10
10
mA Max
mA
Output Leakage Current
V a IN e 1V, VbIN e 0V,
VOUT e 36V
2
ms
ms
Electrical Characteristics These specifications apply for Vb e GND e 0V, V a e 5V, VCM e VOUT e V a /2,
IR e 100 mA, unless otherwise specified. Limits in standard typeface are for TJ e 25§ C; limits in boldface type apply over the
Operating Temperature Range. (Continued)
Symbol
Parameter
LM612AM
LM612AI
Limits
(Note 8)
LM612M
LM612I
Limits
(Note 8)
1.244
1.2365
1.2515
( g 0.6%)
1.2191
1.2689
( g 2%)
18
80
150
Typical
(Note 7)
Conditions
Units
VOLTAGE REFERENCE (Note 9)
VR
Reference Voltage
DVR
DT
Average Drift with
Temperature
DVR
kH
Average Drift with
Time
DVR
DTJ
Hysteresis
(Note 11)
DVR
DIR
VR Change with
Current
VR[100 mA] b VR[17 mA]
0.05
0.1
1
1.1
1
1.1
mV Max
mV Max
VR[10 mA] b VR[100 mA]
(Note 12)
1.5
2.0
5
5.5
5
5.5
mV Max
mV Max
(Note 10)
TJ e 40§ C
TJ e 150§ C
V Min
V Max
ppm/§ C
Max
400
1000
ppm/kH
ppm/kH
3.2
mV/§ C
R
Resistance
DVR[10 mA to 0.1 mA] /9.9 mA
DVR[100 mA to 17 mA] /83 mA
0.2
0.6
0.56
13
0.56
13
X Max
X Max
DVR
DV a
VR Change with
V a Change
VR[V a
e 5V] b
VR[V a
e 36V]
0.1
0.1
1.2
1.3
1.2
1.3
mV Max
mV Max
VR[V a
e 5V] b
VR[V a
e 3V]
0.01
0.01
1
1.5
1
1.5
mV Max
mV Max
en
Voltage Noise
BW e 10 Hz to 10 kHz
30
mVRMS
Note 1: Absolute maximum ratings indicate limits beyond which damage to the component may occur. Electrical specifications do not apply when operating the
device beyond its rated operating conditions.
Note 2: Input voltage above V a is not allowed. As long as one input pin voltage remains inside the common-mode range, the comparator will deliver the correct
output.
Note 3: More accurately, it is excessive current flow, with resulting excess heating, that limits the voltages on all pins. When any pin is pulled a diode drop below
Vb, a parasitic NPN transistor turns ON. No latch-up will occur as long as the current through that pin remains below the Maximum Rating. Operation is undefined
and unpredictable when any parasitic diode or transistor is conducting.
Note 4: Shorting the Output to Vb will not cause power dissipation, so it may be continuous. However, shorting the Output to any more positive voltage (including
V a ), will cause 80 mA (typ.) to be drawn through the output transistor. This current multiplied by the applied voltage is the power dissipation in the output transistor.
If this total power causes the junction temperature to exceed 150§ C, degraded reliability or destruction of the device may occur. To determine junction temperature,
see Note 5.
Note 5: Junction temperature may be calculated using TJ e TA a PD iJA. The given thermal resistance is worst-case for packages in sockets in still air. For
packages soldered to copper-clad board with dissipation from one comparator or reference output transistor, nominal iJA is 90§ C/W for the N package.
Note 6: Human body model, 100 pF discharged through a 1.5 kX resistor.
Note 7: Typical values in standard typeface are for TJ e 25§ C; values in boldface type apply for the full operating temperature range. These values represent the
most likely parametric norm.
Note 8: All limits are guaranteed for TJ e 25§ C (standard type face) or over the full operating temperature range (bold type face).
Note 9: VR is the reference output voltage, nominally 1.24V.
Note 10: Average reference drift is calculated from the measurement of the reference voltage at 25§ C and at the temperature extremes. The drift, in ppm/§ C, is
106 # DVR/VR[25§ C] # DTJ, where DVR is the lowest value subtracted from the highest, VR[25§ C] is the value at 25§ C, and DTJ is the temperature range. This
parameter is guaranteed by design and sample testing.
Note 11: Hysteresis is the change in VR caused by a change in TJ, after the reference has been ‘‘dehysterized’’. To dehysterize the reference; that is minimize the
hysteresis to the typical value, its junction temperature should be cycled in the following pattern, spiralling in toward 25§ C: 25§ C, 85§ C, b 40§ C, 70§ C, 0§ C, 25§ C.
Note 12: Low contact resistance is required for accurate measurement.
Note 13: A military RETS 612AMX electrical test specification is available on request. The military screened parts can also be procured as a Standard Military
Drawing.
3
Simplified Schematic Diagrams
Comparator
TL/H/11058 – 2
Reference
Bias
TL/H/11058 – 3
4
Typical Performance Characteristics (Reference)
b
TJ e 25§ C, V e 0V, unless otherwise noted
Reference Voltage vs Temp.
Reference Voltage
Drift vs Time
Accelerated Reference
Voltage Drift vs Time
Reference Voltage vs
Current and Temperature
Reference Voltage vs
Reference Current
Reference Voltage Change
with Supply Voltage Step
Reference AC
Stability Range
Reference Noise Voltage
vs Frequency
Reference Small-Signal
Impedance vs Frequency
Reference Power-Up Time
Reference Voltage with
100 E 12 mA Current Step
Reference Step Response
for 100 mA E 10 mA
Current Step
TL/H/11058 – 4
5
Typical Performance Characteristics (Comparators)
TJ e 25§ C, V a e 5V, Vb e 0V
Supply Current
vs Supply Voltage
Input Bias Current vs
Common-Mode Voltage
Input Current vs
Differential Input Voltage
Output Saturation
Voltage vs Sink Current
Small-Signal Response
TimesÐInverting Input,
Negative Transition
Small-Signal Response
TimesÐInverting Input,
Positive Transition
Small-Signal Response
TimesÐNon-Inverting Input,
Positive Transition
Small-Signal Response
TimesÐNon-Inverting Input,
Negative Transition
Large-Signal Response
TimesÐInverting Input,
Positive Transition
Large-Signal Response
TimesÐInverting Input,
Negative Transition
Large-Signal Response
TimesÐNon-Inverting Input,
Positive Transition
Large-Signal Response
TimesÐNon-Inverting Input,
Negative Transition
TL/H/11058 – 6
6
Application Information
Capacitors in parallel with the reference are allowed. See
the Reference AC Stability Range typical curve for capacitance valuesÐfrom 20 mA to 3 mA the reference is stable
for any value of capacitance. With the reference’s wide stability range with resistive and capacitive loads, a wide range
of RC filter values will perform noise filtering when necessary.
VOLTAGE REFERENCE
Reference Biasing
The voltage reference is of a shunt regulator topology that
models as a simple zener diode. With current IR flowing in
the ‘‘forward’’ direction there is the familiar diode transfer
function. IR flowing in the reverse direction forces the reference voltage to be developed from cathode to anode.
Reference Hysteresis
The reference voltage depends, slightly, on the thermal history of the die. Competitive micro-power products varyÐalways check the datasheet for any given device. Do not assume that no specification means no hysteresis.
COMPARATORS
Either comparator or the reference may be biased in any
way with no effect on the other sections of the LM612, except when a substrate diode conducts (see Electrical Characteristics Note 3). For example, one or both inputs of one
comparator may be outside the input voltage range limits,
the reference may be unpowered, and the other comparator
will still operate correctly. The inverting input of an unused
comparator should be tied to Vb and the non-inverting tied
to V a .
TL/H/11058 – 8
FIGURE 1. 1.24V Reference is Developed between
Cathode and Anode; Current Source IR is External
The reference equivalent circuit reveals how VR is held at
the constant 1.2V by feedback for a wide range of reverse
current.
Hysteresis
Any comparator may oscillate or produce a noisy output if
the applied differential input voltage is near the comparator’s offset voltage. This usually happens when the input
signal is moving very slowly across the comparator’s switching threshold. This problem can be prevented by the addition of hysteresis, or positive feedback, as shown in Figure
4.
TL/H/11058 – 9
FIGURE 2. Reference Equivalent Circuit
To generate the required reverse current, typically a resistor
is connected from a supply voltage higher than the reference voltage to the Reference Output pin. Varying that voltage, and so varying IR, has small effect with the equivalent
series resistance of less than an ohm at the higher currents.
Alternatively, an active current source, such as the LM134
series, may generate IR.
TL/H/11058 – 11
FIGURE 4. RS and RF Add Hysteresis to Comparator
The amount of hysteresis added in Figure 4 is
RS
VH e V a c
(RF a RS)
RS
for RF ll RS
RF
A good rule of thumb is to add hysteresis of at least the
maximum specified offset voltage. More than about 50 mV
&Va c
TL/H/11058 – 10
FIGURE 3. 1.2V Reference
7
Application Information (Continued)
of hysteresis can substantially reduce the accuracy of the
comparator, since the offset voltage is effectively being increased by the hysteresis when the comparator output is
high.
It is often a good idea to decrease the amount of hysteresis
until oscillations are observed, then use three times that
minimum hysteresis in the final circuit. Note that the amount
of hysteresis needed is greatly affected by layout. The
amount of hysteresis should be rechecked each time the
layout is changed, such as changing from a breadboard to a
P.C. board.
The guaranteed common-mode input voltage range for an
LM612 is Vb s VCM s (V a b 1.8V), over temperature.
This is the voltage range in which the comparisons must be
made. If both inputs are within this range, the output will be
at the correct state. If one input is within this range, and the
other input is less than (Vb a 32V), even if this is greater
than V a , the output will be at the correct state. If, however,
either or both inputs are driven below Vb, and either input
current exceeds 10 mA, the output state is not guaranteed
to be correct. If both inputs are above (V a b 1.8V), the
output state is also not guaranteed to be correct.
Input Stage
The input stage uses lateral PNP input transistors which,
unlike those of many op amps, have breakdown voltage
BVEBO equal to the absolute maximum supply voltage. Also,
they have no diode clamps to the positive supply nor across
the inputs. These features make the inputs look like high
impedances to input sources producing large differential
and common-mode voltages.
Output Stage
The comparators have a common open-collector output
stage which requires a pull-up resistor to a positive supply
voltage for the output to switch properly. When the internal
output transistor is off, the output (HIGH) voltage will be
pulled up to this external positive voltage.
To ensure that the LOW output voltage is under the TTL-low
threshold, the output transistor’s load current must be less
than 0.8 mA (over temperature) when it turns on. This impacts the minimum value of the pull-up resistor.
Typical Applications
TL/H/11058 – 12
Power Supply Monitor with Indicator
8
Physical Dimensions inches (millimeters)
8-Pin Ceramic Dual-In-Line Package (J)
Order Number LM612AMJ/883
NS Package Number J08A
8-Pin Surface Mount Package (M)
Order Number LM612IM
NS Package Number M08A
9
LM612 Dual-Channel Comparator and Reference
Physical Dimensions inches (millimeters) (Continued)
8-Pin Molded Dual-In-Line Package (N)
Order Number LM612AMJ/883, LM612AMN, LM612AIN, LM612MN or LM612IN
NS Package Number N08E
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