LM613IWMX

Manufacturer Part NumberLM613IWMX
DescriptionIC,Operational Amplifier,DUAL,BIPOLAR,SOP,16PIN,PLASTIC
ManufacturerNational Semiconductor
LM613IWMX datasheets
 


Specifications of LM613IWMX

Lead Free Status / RoHS StatusContains lead / RoHS non-compliant  
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Electrical Characteristics
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
is 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
V
, 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: Simultaneous short-circuit of multiple comparators while using high supply voltages may force junction temperature above maximum, and thus should not
be continuous.
Note 5: Junction temperature may be calculated using T
soldered to copper-clad board with dissipation from one comparator or reference output transistor, nominal θ
WM package.
Note 6: Human body model, 100 pF discharged through a 1.5 kΩ resistor.
Note 7: Typical values in standard typeface are for T
most likely parametric norm.
Note 8: All limits are guaranteed at room temperature (standard type face) or at operating temperature extremes (bold type face).
Note 9: Slew rate is measured with the op amp in a voltage follower configuration. For rising slew rate, the input voltage is driven from 5V to 25V, and the output
@
voltage transition is sampled at 10V and
20V. For falling slew rate, the input voltage is driven from 25V to 5V, and the output voltage transition is sampled at 20V
and 10V.
Note 10: V
is the Cathode-to-feedback voltage, nominally 1.244V.
R
Note 11: 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
6
• ∆V
• ∆T
), where ∆V
10
/(V
is the lowest value subtracted from the highest, V
R
R[25˚C]
J
R
is guaranteed by design and sample testing.
Note 12: Hysteresis is the change in V
caused by a change in T
R
hysteresis to the typical value, its junction temperature should be cycled in the following pattern, spiraling in toward 25˚C: 25˚C, 85˚C, −40˚C, 70˚C, 0˚C, 25˚C.
Note 13: Low contact resistance is required for accurate measurement.
(Continued)
θ
= T
+ P
. The given thermal resistance is worst-case for packages in sockets in still air. For packages
J
A
D
JA
= 25˚C; values in bold face type apply for the full operating temperature range. These values represent the
J
is the value at 25˚C, and ∆T
R[25˚C]
, after the reference has been “dehysterized”. To dehysterize the reference; that is minimize the
J
5
is 90˚C/W for the N package, and 135˚C/W for the
JA
is the temperature range. This parameter
J
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