NSC LM19CIZ

LM19
2.4V, 10μA, TO-92 Temperature Sensor
General Description
The LM19 is a precision analog output CMOS integrated-circuit temperature sensor that operates over a −55°C to +130°
C temperature range. The power supply operating range is
+2.4 V to +5.5 V. The transfer function of LM19 is predominately linear, yet has a slight predictable parabolic curvature.
The accuracy of the LM19 when specified to a parabolic
transfer function is ±2.5°C at an ambient temperature of +30°
C. The temperature error increases linearly and reaches a
maximum of ±3.8°C at the temperature range extremes. The
temperature range is affected by the power supply voltage. At
a power supply voltage of 2.7 V to 5.5 V the temperature
range extremes are +130°C and −55°C. Decreasing the power supply voltage to 2.4 V changes the negative extreme to
−30°C, while the positive remains at +130°C.
The LM19's quiescent current is less than 10 μA. Therefore,
self-heating is less than 0.02°C in still air. Shutdown capability
for the LM19 is intrinsic because its inherent low power consumption allows it to be powered directly from the output of
many logic gates or does not necessitate shutdown at all.
Applications
■
■
■
■
Cellular Phones
Computers
Power Supply Modules
Battery Management
■
■
■
■
■
FAX Machines
Printers
HVAC
Disk Drives
Appliances
Features
■
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■
■
■
Rated for full −55°C to +130°C range
Available in a TO-92 package
Predictable curvature error
Suitable for remote applications
UL Recognized Component
Key Specifications
■ Accuracy at +30°C
■ Accuracy at +130°C & −55°C
■ Power Supply Voltage Range
■ Current Drain
■ Nonlinearity
■ Output Impedance
■ Load Regulation
0 μA < IL< +16 μA
±2.5 °C (max)
±3.5 to ±3.8 °C (max)
+2.4V to +5.5V
10 μA (max)
±0.4 % (typ)
160 Ω (max)
−2.5 mV (max)
Typical Application
Output Voltage vs Temperature
20004002
VO = (−3.88×10−6×T2) + (−1.15×10−2×T) + 1.8639
or
20004024
where:
T is temperature, and VO is the measured output voltage of the LM19.
FIGURE 1. Full-Range Celsius (Centigrade) Temperature Sensor (−55°C to +130°C)
Operating from a Single Li-Ion Battery Cell
© 2007 National Semiconductor Corporation
200040
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LM19 2.4V, 10μA, TO-92 Temperature Sensor
October 2007
LM19
Temperature (T)
Typical VO
+130°C
+303 mV
+100°C
+675 mV
+80°C
+919 mV
+30°C
+1515 mV
+25°C
+1574 mV
0°C
+1863.9 mV
−30°C
+2205 mV
−40°C
+2318 mV
−55°C
+2485 mV
Connection Diagram
TO-92
20004001
See NS Package Number Z03A
Ordering Information
Order
Number
LM19CIZ
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Temperature
Accuracy
Temperature
Range
NS Package
Number
Device
Marking
±3.8°C
−55°C to +130°C
Z03A
LM19CIZ
2
Transport Media
Bulk
Supply Voltage
Output Voltage
+6.5V to −0.2V
(V+ + 0.6 V) to
−0.6 V
Output Current
10 mA
Input Current at any pin (Note 2)
5 mA
Storage Temperature
−65°C to +150°C
Maximum Junction Temperature (TJMAX)
+150°C
ESD Susceptibility (Note 3) :
Human Body Model
2500 V
Operating Ratings
250 V
+240°C
(Note 1)
TMIN ≤ TA ≤ TMAX
Specified Temperature Range:
2.4 V ≤ V+≤ 2.7 V
−30°C ≤ TA ≤ +130°C
2.7 V ≤ V+≤ 5.5 V
Supply Voltage Range (V+)
−55°C ≤ TA ≤ +130°C
+2.4 V to +5.5 V
Thermal Resistance, θJA(Note 4)
TO-92
150°C/W
Electrical Characteristics
Unless otherwise noted, these specifications apply for V+ = +2.7 VDC. Boldface limits apply for TA = TJ = TMIN to TMAX ; all other
limits TA = TJ = 25°C; Unless otherwise noted.
Parameter
Temperature to Voltage Error
VO = (−3.88×10−6×T2)
+ (−1.15×10−2×T) + 1.8639V (Note 7)
Conditions
Typical
(Note 5)
Limits
(Note 6)
Units
(Limit)
TA = +25°C to +30°C
±2.5
°C (max)
TA = +130°C
±3.5
°C (max)
TA = +125°C
±3.5
°C (max)
TA = +100°C
±3.2
°C (max)
TA = +85°C
±3.1
°C (max)
TA = +80°C
±3.0
°C (max)
TA = 0°C
±2.9
°C (max)
TA = −30°C
±3.3
°C (min)
TA = −40°C
±3.5
°C (max)
±3.8
°C (max)
TA = −55°C
Output Voltage at 0°C
Variance from Curve
Non-Linearity (Note 8)
LM19C
−20°C ≤ TA ≤ +80°C
Sensor Gain (Temperature Sensitivity −30°C ≤ TA ≤ +100°C
or Average Slope) to equation:
VO=−11.77 mV/°C×T+1.860V
+1.8639
V
±1.0
°C
±0.4
%
−11.77
−11.0
−12.6
mV/°C (min)
mV/°C (max)
160
Ω (max)
−2.5
mV (max)
Output Impedance
0 μA ≤ IL ≤ +16 μA
Load Regulation(Note 9)
0 μA ≤ IL ≤ +16 μA
Line Regulation
+2. 4 V ≤ V+ ≤ +5.0V
+3.7
mV/V (max)
+5.0 V ≤ V+ ≤ +5.5 V
+11
mV (max)
(Notes 10, 11)
(Notes 10, 11)
Quiescent Current
Change of Quiescent Current
+2. 4 V ≤ V+ ≤ +5.0V
4.5
7
μA (max)
+5.0V ≤ V+ ≤ +5.5V
4.5
9
μA (max)
+2. 4 V ≤ V+ ≤ +5.0V
4.5
10
μA (max)
+2. 4 V ≤
+0.7
μA
−11
nA/°C
0.02
μA
V+
≤ +5.5V
Temperature Coefficient of
Quiescent Current
Shutdown Current
V+ ≤ +0.8 V
3
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LM19
Machine Model
Lead Temperature
TO-92 Package
Soldering (3 seconds dwell)
Absolute Maximum Ratings (Note 1)
LM19
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
functional, but do not guarantee specific performance limits. For guaranteed specifications and test conditions, see the Electrical Characteristics. The guaranteed
specifications apply only for the test conditions listed. Some performance characteristics may degrade when the device is not operated under the listed test
conditions.
Note 2: When the input voltage (VI) at any pin exceeds power supplies (VI < GND or VI > V+), the current at that pin should be limited to 5 mA.
Note 3: The human body model is a 100 pF capacitor discharged through a 1.5 kΩ resistor into each pin. The machine model is a 200 pF capacitor discharged
directly into each pin.
Note 4: The junction to ambient thermal resistance (θJA) is specified without a heat sink in still air.
Note 5: Typicals are at TJ = TA = 25°C and represent most likely parametric norm.
Note 6: Limits are guaranteed to National's AOQL (Average Outgoing Quality Level).
Note 7: Accuracy is defined as the error between the measured and calculated output voltage at the specified conditions of voltage, current, and temperature
(expressed in°C).
Note 8: Non-Linearity is defined as the deviation of the calculated output-voltage-versus-temperature curve from the best-fit straight line, over the temperature
range specified.
Note 9: Regulation is measured at constant junction temperature, using pulse testing with a low duty cycle. Changes in output due to heating effects can be
computed by multiplying the internal dissipation by the thermal resistance.
Note 10: Negative currents are flowing into the LM19. Positive currents are flowing out of the LM19. Using this convention the LM19 can at most sink −1 μA and
source +16 μA.
Note 11: Load regulation or output impedance specifications apply over the supply voltage range of +2.4V to +5.5V.
Note 12: Line regulation is calculated by subtracting the output voltage at the highest supply input voltage from the output voltage at the lowest supply input
voltage.
Typical Performance Characteristics
Temperature Error vs. Temperature
Thermal Response in Still Air
20004035
20004034
where T is the middle of the temperature range of interest and
m is in V/°C. For example for the temperature range of Tmin=
−30 to Tmax=+100°C:
1.0 LM19 Transfer Function
The LM19's transfer function can be described in different
ways with varying levels of precision. A simple linear transfer
function, with good accuracy near 25°C, is
T=35°C
and
VO= −11.69 mV/°C × T + 1.8663 V
m = −11.77 mV/°C
Over the full operating temperature range of −55°C to +130°
C, best accuracy can be obtained by using the parabolic
transfer function
The offset of the linear transfer function can be calculated using the following equation:
b = (VOP(Tmax) + VOP(T) + m × (Tmax+T))/2
VO = (−3.88×10−6×T2) + (−1.15×10−2×T) + 1.8639
,
where:
• VOP(Tmax) is the calculated output voltage at Tmax using
the parabolic transfer function for VO
• VOP(T) is the calculated output voltage at T using the
parabolic transfer function for VO.
Using this procedure the best fit linear transfer function for
many popular temperature ranges was calculated in Figure
2. As shown in Figure 2 the error that is introduced by the
linear transfer function increases with wider temperature
ranges.
solving for T:
A linear transfer function can be used over a limited temperature range by calculating a slope and offset that give best
results over that range. A linear transfer function can be calculated from the parabolic transfer function of the LM19. The
slope of the linear transfer function can be calculated using
the following equation:
m = −7.76 × 10−6× T − 0.0115,
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4
Temperature Range
Tmax (°C)
Linear Equation
VO=
Maximum Deviation of Linear Equation from
Parabolic Equation (°C)
−55
+130
−11.79 mV/°C × T + 1.8528 V
±1.41
−40
+110
−11.77 mV/°C × T + 1.8577 V
±0.93
−30
+100
−11.77 mV/°C × T + 1.8605 V
±0.70
±0.65
-40
+85
−11.67 mV/°C × T + 1.8583 V
−10
+65
−11.71 mV/°C × T + 1.8641 V
±0.23
+35
+45
−11.81 mV/°C × T + 1.8701 V
±0.004
+20
+30
−11.69 mV/°C × T + 1.8663 V
±0.004
FIGURE 2. First Order Equations Optimized For Different Temperature Ranges.
2.0 Mounting
TO-92
no heat sink
The LM19 can be applied easily in the same way as other
integrated-circuit temperature sensors. It can be glued or cemented to a surface. The temperature that the LM19 is sensing will be within about +0.02°C of the surface temperature to
which the LM19's leads are attached.
This presumes that the ambient air temperature is almost the
same as the surface temperature; if the air temperature were
much higher or lower than the surface temperature, the actual
temperature measured would be at an intermediate temperature between the surface temperature and the air temperature.
To ensure good thermal conductivity the backside of the
LM19 die is directly attached to the GND pin. The tempertures
of the lands and traces to the other leads of the LM19 will also
affect the temperature that is being sensed.
Alternatively, the LM19 can be mounted inside a sealed-end
metal tube, and can then be dipped into a bath or screwed
into a threaded hole in a tank. As with any IC, the LM19 and
accompanying wiring and circuits must be kept insulated and
dry, to avoid leakage and corrosion. This is especially true if
the circuit may operate at cold temperatures where condensation can occur. Printed-circuit coatings and varnishes such
as Humiseal and epoxy paints or dips are often used to ensure
that moisture cannot corrode the LM19 or its connections.
The thermal resistance junction to ambient (θJA) is the parameter used to calculate the rise of a device junction temperature due to its power dissipation. For the LM19 the
equation used to calculate the rise in the die temperature is
as follows:
TJ = TA + θJA [(V+ IQ) + (V+ − VO) IL]
where IQ is the quiescent current and ILis the load current on
the output. Since the LM19's junction temperature is the actual temperature being measured care should be taken to
minimize the load current that the LM19 is required to drive.
The tables shown in Figure 3 summarize the rise in die temperature of the LM19 without any loading, and the thermal
resistance for different conditions.
TO-92
small heat fin
θJA
TJ − TA
θJA
TJ − TA
(°C/W)
(°C)
(°C/W)
(°C)
Still air
150
TBD
TBD
TBD
Moving air
TBD
TBD
TBD
TBD
FIGURE 3. Temperature Rise of LM19 Due to
Self-Heating and Thermal Resistance (θJA)
3.0 Capacitive Loads
The LM19 handles capacitive loading well. Without any precautions, the LM19 can drive any capacitive load less than
300 pF as shown in Figure 4. Over the specified temperature
range the LM19 has a maximum output impedance of 160
Ω. In an extremely noisy environment it may be necessary to
add some filtering to minimize noise pickup. It is recommended that 0.1 μF be added from V+ to GND to bypass the power
supply voltage, as shown in Figure 5. In a noisy environment
it may even be necessary to add a capacitor from the output
to ground with a series resistor as shown in Figure 5. A 1 μF
output capacitor with the 160 Ω maximum output impedance
and a 200 Ω series resistor will form a 442 Hz lowpass filter.
Since the thermal time constant of the LM19 is much slower,
the overall response time of the LM19 will not be significantly
affected.
20004015
FIGURE 4. LM19 No Decoupling Required for Capacitive
Loads Less than 300 pF.
5
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LM19
Tmin (°C)
LM19
R (Ω)
C (µF)
200
1
470
0.1
680
0.01
1k
0.001
FIGURE 5. LM19 with Filter for Noisy Environment and
Capacitive Loading greater than 300 pF. Either placement
of resistor as shown above is just as effective.
20004016
20004033
4.0 Applications Circuits
20004018
FIGURE 6. Centigrade Thermostat
20004019
FIGURE 7. Conserving Power Dissipation with Shutdown
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6
LM19
20004028
Most CMOS ADCs found in ASICs have a sampled data comparator input structure that is notorious for causing grief to analog
output devices such as the LM19 and many op amps. The cause of this grief is the requirement of instantaneous charge of the
input sampling capacitor in the ADC. This requirement is easily accommodated by the addition of a capacitor. Since not all ADCs
have identical input stages, the charge requirements will vary necessitating a different value of compensating capacitor. This ADC
is shown as an example only. If a digital output temperature is required please refer to devices such as the LM74.
FIGURE 8. Suggested Connection to a Sampling Analog to Digital Converter Input Stage
7
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LM19
Physical Dimensions inches (millimeters) unless otherwise noted
3-Lead TO-92 Plastic Package (Z)
Order Number LM19CIZ
NS Package Number Z03A
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8
LM19
Notes
9
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LM19 2.4V, 10μA, TO-92 Temperature Sensor
Notes
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