NSC LM26LVCISDX-090

LM26LV
1.6 V, LLP-6 Factory Preset Temperature Switch and
Temperature Sensor
General Description
The LM26LV is a low-voltage, precision, dual-output, lowpower temperature switch and temperature sensor. The temperature trip point (TTRIP) can be preset at the factory to any
temperature in the range of 0°C to 150°C in 1°C increments.
Built-in temperature hysteresis (THYST) keeps the output stable in an environment of temperature instability.
In normal operation the LM26LV temperature switch outputs
assert when the die temperature exceeds TTRIP. The temperature switch outputs will reset when the temperature falls
below a temperature equal to (TTRIP − THYST). The
OVERTEMP digital output, is active-high with a push-pull
structure, while the OVERTEMP digital output, is active-low
with an open-drain structure.
An analog output, VTEMP, delivers an analog output voltage
which is inversely proportional to the measured temperature.
Driving the TRIP TEST input high: (1) causes the digital outputs to be asserted for in-situ verification and, (2) causes the
threshold voltage to appear at the VTEMP output pin, which
could be used to verify the temperature trip point.
The LM26LV's low minimum supply voltage makes it ideal for
1.8 Volt system designs. Its wide operating range, low supply
current , and excellent accuracy provide a temperature switch
solution for a wide range of commercial and industrial applications.
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Automotive
Disk Drives
Games
Appliances
Features
■
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■
■
■
■
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Low 1.6V operation
Low quiescent current
Push-pull and open-drain temperature switch outputs
Wide trip point range of 0°C to 150°C
Very linear analog VTEMP temperature sensor output
VTEMP output short-circuit protected
Accurate over −50°C to 150°C temperature range
2.2 mm by 2.5 mm (typ) LLP-6 package
Excellent power supply noise rejection
Key Specifications
■ Supply Voltage
■ Supply Current
■ Accuracy, Trip Point
Cell phones
Wireless Transceivers
Digital Cameras
Personal Digital Assistants (PDA's)
Battery Management
■ Accuracy, VTEMP
■ VTEMP Output Drive
■ Operating Temperature
■ Hysteresis Temperature
Connection Diagram
8 μA (typ)
0°C to 150°C
±2.2°C
0°C to 150°C
0°C to 120°C
−50°C to 0°C
±2.3°C
±2.2°C
±1.7°C
Temperature
Applications
■
■
■
■
■
1.6V to 5.5V
±100 μA
−50°C to 150°C
4.5°C to 5.5°C
Typical Transfer Characteristic
LLP-6
VTEMP Analog Voltage vs Die Temperature
20204701
Top View
See NS Package Number SDB06A
20204724
© 2008 National Semiconductor Corporation
202047
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LM26LV 1.6 V, LLP-6 Factory Preset Temperature Switch and Temperature Sensor
May 16, 2008
LM26LV
Block Diagram
20204703
Pin Descriptions
Pin
No.
1
5
3
6
Name
TRIP
TEST
OVERTEMP
OVERTEMP
VTEMP
Type
Equivalent Circuit
Description
Digital
Input
TRIP TEST pin. Active High input.
If TRIP TEST = 0 (Default) then:
VTEMP = VTS, Temperature Sensor Output Voltage
If TRIP TEST = 1 then:
OVERTEMP and OVERTEMP outputs are asserted and
VTEMP = VTRIP, Temperature Trip Voltage.
This pin may be left open if not used.
Digital
Output
Over Temperature Switch output
Active High, Push-Pull
Asserted when the measured temperature exceeds the Trip
Point Temperature or if TRIP TEST = 1
This pin may be left open if not used.
Digital
Output
Over Temperature Switch output
Active Low, Open-drain (See Section 2.1 regarding required pullup resistor.)
Asserted when the measured temperature exceeds the Trip
Point Temperature or if TRIP TEST = 1
This pin may be left open if not used.
Analog
Output
VTEMP Analog Voltage Output
If TRIP TEST = 0 then
VTEMP = VTS, Temperature Sensor Output Voltage
If TRIP TEST = 1 then
VTEMP = VTRIP, Temperature Trip Voltage
This pin may be left open if not used.
4
VDD
Power
Positive Supply Voltage
2
GND
Ground
Power Supply Ground
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2
LM26LV
Typical Application
20204702
3
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LM26LV
Ordering Information
Order Number
Temperature Trip
Point, °C
NS Package
Number
Top Mark
Transport Media
LM26LVCISD-150
150°C
SDB06A
150
1000 Units on Tape and Reel
LM26LVCISDX-150
150°C
SDB06A
150
4500 Units on Tape and Reel
LM26LVCISD-145
145°C
SDB06A
145
1000 Units on Tape and Reel
LM26LVCISDX-145
145°C
SDB06A
145
4500 Units on Tape and Reel
LM26LVCISD-140
140°C
SDB06A
140
1000 Units on Tape and Reel
LM26LVCISDX-140
140°C
SDB06A
140
4500 Units on Tape and Reel
LM26LVCISD-135
135°C
SDB06A
135
1000 Units on Tape and Reel
LM26LVCISDX-135
135°C
SDB06A
135
4500 Units on Tape and Reel
LM26LVCISD-130
130°C
SDB06A
130
1000 Units on Tape and Reel
LM26LVCISDX-130
130°C
SDB06A
130
4500 Units on Tape and Reel
LM26LVCISD-125
125°C
SDB06A
125
1000 Units on Tape and Reel
LM26LVCISDX-125
125°C
SDB06A
125
4500 Units on Tape and Reel
LM26LVCISD-120
120°C
SDB06A
120
1000 Units on Tape and Reel
LM26LVCISDX-120
120°C
SDB06A
120
4500 Units on Tape and Reel
LM26LVCISD-115
115°C
SDB06A
115
1000 Units on Tape and Reel
LM26LVCISDX-115
115°C
SDB06A
115
4500 Units on Tape and Reel
LM26LVCISD-110
110°C
SDB06A
110
1000 Units on Tape and Reel
LM26LVCISDX-110
110°C
SDB06A
110
4500 Units on Tape and Reel
LM26LVCISD-105
105°C
SDB06A
105
1000 Units on Tape and Reel
LM26LVCISDX-105
105°C
SDB06A
105
4500 Units on Tape and Reel
LM26LVCISD-100
100°C
SDB06A
100
1000 Units on Tape and Reel
LM26LVCISDX-100
100°C
SDB06A
100
4500 Units on Tape and Reel
LM26LVCISD-095
95°C
SDB06A
095
1000 Units on Tape and Reel
LM26LVCISDX-095
95°C
SDB06A
095
4500 Units on Tape and Reel
LM26LVCISD-090
90°C
SDB06A
090
1000 Units on Tape and Reel
LM26LVCISDX-090
90°C
SDB06A
090
4500 Units on Tape and Reel
LM26LVCISD-085
85°C
SDB06A
085
1000 Units on Tape and Reel
LM26LVCISDX-085
85°C
SDB06A
085
4500 Units on Tape and Reel
LM26LVCISD-080
80°C
SDB06A
080
1000 Units on Tape and Reel
LM26LVCISDX-080
80°C
SDB06A
080
4500 Units on Tape and Reel
LM26LVCISD-075
75°C
SDB06A
075
1000 Units on Tape and Reel
LM26LVCISDX-075
75°C
SDB06A
075
4500 Units on Tape and Reel
LM26LVCISD-070
70°C
SDB06A
070
1000 Units on Tape and Reel
LM26LVCISDX-070
70°C
SDB06A
070
4500 Units on Tape and Reel
LM26LVCISD-065
65°C
SDB06A
065
1000 Units on Tape and Reel
LM26LVCISDX-065
65°C
SDB06A
065
4500 Units on Tape and Reel
LM26LVCISD-060
60°C
SDB06A
060
1000 Units on Tape and Reel
LM26LVCISDX-060
60°C
SDB06A
060
4500 Units on Tape and Reel
LM26LVCISD-050
50°C
SDB06A
050
1000 Units on Tape and Reel
LM26LVCISDX-050
50°C
SDB06A
050
4500 Units on Tape and Reel
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4
Supply Voltage
Voltage at OVERTEMP pin
Voltage at OVERTEMP and
VTEMP pins
TRIP TEST Input Voltage
Output Current, any output pin
Input Current at any pin (Note 2)
Storage Temperature
Maximum Junction Temperature
TJ(MAX)
ESD Susceptibility (Note 3) :
Human Body Model
−0.2V to +6.0V
−0.2V to +6.0V
−0.2V to (VDD + 0.5V)
−0.2V to (VDD + 0.5V)
±7 mA
5 mA
−65°C to +150°C
Operating Ratings
(Note 1)
Specified Temperature Range:
TMIN ≤ TA ≤ TMAX
−50°C ≤ TA ≤ +150°C
LM26LV
Supply Voltage Range (VDD)
+1.6 V to +5.5 V
Thermal Resistance (θJA) (Note 5)
LLP-6 (Package SDB06A)
+155°C
152 °C/W
4500V
Accuracy Characteristics
Trip Point Accuracy
Parameter
Trip Point Accuracy (Note 8)
Conditions
VDD = 5.0 V
0 − 150°C
Limits
(Note 7)
Units
(Limit)
±2.2
°C (max)
VTEMP Analog Temperature Sensor Output Accuracy
There are four gains corresponding to each of the four Temperature Trip Point Ranges. Gain 1 is the sensor gain used for Temperature Trip Point 0 - 69°C. Likewise Gain 2 is for Trip Points 70 - 109 °C; Gain 3 for 110 - 129 °C; and Gain 4 for 130 - 150 °C.
These limits do not include DC load regulation. These stated accuracy limits are with reference to the values in the LM26LV
Conversion Table.
Parameter
Limits
(Note 7)
Conditions
Gain 1: for Trip Point
Range 0 - 69°C
Gain 2: for Trip Point
Range 70 - 109°C
VTEMP Temperature
Accuracy
(Note 8)
Gain 3: for Trip Point
Range 110 - 129°C
Gain 4: for Trip Point
Range 130 - 150°C
TA = 20°C to 40°C
VDD = 1.6 to 5.5 V
±1.8
TA = 0°C to 70°C
VDD = 1.6 to 5.5 V
±2.0
TA = 0°C to 90°C
VDD = 1.6 to 5.5 V
±2.1
TA = 0°C to 120°C
VDD = 1.6 to 5.5 V
±2.2
TA = 0°C to 150°C
VDD = 1.6 to 5.5 V
±2.3
TA = −50°C to 0°C
VDD = 1.7 to 5.5 V
±1.7
TA = 20°C to 40°C
VDD = 1.8 to 5.5 V
±1.8
TA = 0°C to 70°C
VDD = 1.9 to 5.5 V
±2.0
TA = 0°C to 90°C
VDD = 1.9 to 5.5 V
±2.1
TA = 0°C to 120°C
VDD = 1.9 to 5.5 V
±2.2
TA = 0°C to 150°C
VDD = 1.9 to 5.5 V
±2.3
TA = −50°C to 0°C
VDD = 2.3 to 5.5 V
±1.7
TA = 20°C to 40°C
VDD = 2.3 to 5.5 V
±1.8
TA = 0°C to 70°C
VDD = 2.5 to 5.5 V
±2.0
TA = 0°C to 90°C
VDD = 2.5 to 5.5 V
±2.1
TA = 0°C to 120°C
VDD = 2.5 to 5.5 V
±2.2
TA = 0°C to 150°C
VDD = 2.5 to 5.5 V
±2.3
TA = −50°C to 0°C
VDD = 3.0 to 5.5 V
±1.7
TA = 20°C to 40°C
VDD = 2.7 to 5.5 V
±1.8
TA = 0°C to 70°C
VDD = 3.0 to 5.5 V
±2.0
TA = 0°C to 90°C
VDD = 3.0 to 5.5 V
±2.1
TA = 0°C to 120°C
VDD = 3.0 to 5.5 V
±2.2
TA = 0°C to 150°C
VDD = 3.0 to 5.5 V
±2.3
TA = −50°C to 0°C
VDD = 3.6 to 5.5 V
±1.7
5
Units
(Limit)
°C (max)
°C (max)
°C (max)
°C (max)
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LM26LV
Machine Model
300V
Charged Device Model
1000V
Soldering process must comply with National's
Reflow Temperature Profile specifications. Refer to
www.national.com/packaging. (Note 4)
Absolute Maximum Ratings (Note 1)
LM26LV
Electrical Characteristics
Unless otherwise noted, these specifications apply for +VDD = +1.6V to +5.5V. Boldface limits apply for TA = TJ = TMIN to
TMAX ; all other limits TA = TJ = 25°C.
Symbol
Parameter
Conditions
Typical
(Note 6)
Limits
(Note 7)
Units
(Limit)
Quiescent Power Supply
Current
8
16
μA (max)
Hysteresis
5
5.5
°C (max)
4.5
°C (Min)
VDD − 0.2V
V (min)
VDD − 0.45V
V (min)
GENERAL SPECIFICATIONS
IS
OVERTEMP DIGITAL OUTPUT
VOH
Logic "1" Output Voltage
ACTIVE HIGH, PUSH-PULL
VDD ≥ 1.6V
Source ≤ 340 μA
VDD ≥ 2.0V
Source ≤ 498 μA
VDD ≥ 3.3V
Source ≤ 780 μA
VDD ≥ 1.6V
Source ≤ 600 μA
VDD ≥ 2.0V
Source ≤ 980 μA
VDD ≥ 3.3V
Source ≤ 1.6 mA
BOTH OVERTEMP and OVERTEMP DIGITAL OUTPUTS
VOL
Logic "0" Output Voltage
OVERTEMP DIGITAL OUTPUT
IOH
Logic "1" Output Leakage
Current (Note 12)
VDD ≥ 1.6V
Sink ≤ 385 μA
VDD ≥ 2.0V
Sink ≤ 500 μA
VDD ≥ 3.3V
Sink ≤ 730 μA
VDD ≥ 1.6V
Sink ≤ 690 μA
VDD ≥ 2.0V
Sink ≤ 1.05 mA
VDD ≥ 3.3V
Sink ≤ 1.62 mA
0.2
V (max)
0.45
ACTIVE LOW, OPEN DRAIN
TA = 30 °C
0.001
TA = 150 °C
0.025
1
μA (max)
VTEMP ANALOG TEMPERATURE SENSOR OUTPUT
VTEMP Sensor Gain
Gain 1: If Trip Point = 0 - 69°C
−5.1
mV/°C
Gain 2: If Trip Point = 70 - 109°C
−7.7
mV/°C
Gain 3: If Trip Point = 110 - 129°C
−10.3
mV/°C
Gain 4: If Trip Point = 130 - 150°C
−12.8
mV/°C
Source ≤ 90 μA
1.6V ≤ VDD < 1.8V
(VDD − VTEMP) ≥ 200 mV
Sink ≤ 100 μA
VTEMP ≥ 260 mV
VTEMP Load Regulation
(Note 10)
Source ≤ 120 μA
VDD ≥ 1.8V
(VDD − VTEMP) ≥ 200 mV
Sink ≤ 200 μA
VTEMP ≥ 260 mV
Source or Sink = 100 μA
VDD Supply- to-VTEMP
DC Line Regulation
(Note 13)
CL
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VTEMP Output Load
Capacitance
VDD = +1.6V to +5.5V
Without series resistor. See Section 4.2
6
−0.1
−1
mV (max)
0.1
1
mV (max)
−0.1
−1
mV (max)
0.1
1
mV (max)
1
Ohm
0.29
mV
74
μV/V
−82
dB
1100
pF (max)
Unless otherwise noted, these specifications apply for +VDD = +1.6V to +5.5V. Boldface limits apply for TA = TJ = TMIN to
TMAX ; all other limits TA = TJ = 25°C.
Symbol
Parameter
Conditions
Typical
(Note 6)
Limits
(Note 7)
Units
(Limit)
VDD− 0.5
V (min)
TRIP TEST DIGITAL INPUT
VIH
Logic "1" Threshold Voltage
VIL
Logic "0" Threshold Voltage
0.5
V (max)
IIH
Logic "1" Input Current
1.5
2.5
μA (max)
IIL
Logic "0" Input Current
(Note 12)
0.001
1
μA (max)
Time from Power On to Digital
Output Enabled. See
definition below.
(Note 11).
1.1
2.3
ms (max)
Time from Power On to
Analog Temperature Valid.
See definition below.
(Note 11)
0.9
10
ms (max)
TIMING
tEN
tVTEMP
Definitions of tEN and tVTEMP
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20204750
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LM26LV
Electrical Characteristics
LM26LV
Notes
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 > VDD), the current at that pin should be limited to 5 mA.
Note 3: The Human Body Model (HBM) is a 100 pF capacitor charged to the specified voltage then discharged through a 1.5 kΩ resistor into each pin. The
Machine Model (MM) is a 200 pF capacitor charged to the specified voltage then discharged directly into each pin. The Charged Device Model (CDM) is a specified
circuit characterizing an ESD event that occurs when a device acquires charge through some triboelectric (frictional) or electrostatic induction processes and then
abruptly touches a grounded object or surface.
Note 4: Reflow temperature profiles are different for lead-free and non-lead-free packages.
Note 5: The junction to ambient temperature resistance (θJA) is specified without a heat sink in still air.
Note 6: Typicals are at TJ = TA = 25°C and represent most likely parametric norm.
Note 7: Limits are guaranteed to National's AOQL (Average Outgoing Quality Level).
Note 8: Accuracy is defined as the error between the measured and reference output voltages, tabulated in the Conversion Table at the specified conditions of
supply gain setting, voltage, and temperature (expressed in °C). Accuracy limits include line regulation within the specified conditions. Accuracy limits do not
include load regulation; they assume no DC load.
Note 9: Changes in output due to self heating can be computed by multiplying the internal dissipation by the temperature resistance.
Note 10: Source currents are flowing out of the LM26LV. Sink currents are flowing into the LM26LV.
Note 11: Guaranteed by design.
Note 12: The 1 µA limit is based on a testing limitation and does not reflect the actual performance of the part. Expect to see a doubling of the current for every
15°C increase in temperature. For example, the 1 nA typical current at 25°C would increase to 16 nA at 85°C.
Note 13: Line regulation (DC) is calculated by subtracting the output voltage at the highest supply voltage from the output voltage at the lowest supply voltage.
The typical DC line regulation specification does not include the output voltage shift discussed in Section 4.3.
Note 14: The curves shown represent typical performance under worst-case conditions. Performance improves with larger overhead (VDD − VTEMP), larger VDD,
and lower temperatures.
Note 15: The curves shown represent typical performance under worst-case conditions. Performance improves with larger VTEMP, larger VDD and lower
temperatures.
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8
VTEMP Output Temperature Error vs. Temperature
Minimum Operating Temperature vs. Supply Voltage
20204706
20204707
Supply Current vs. Temperature
Supply Current vs. Supply Voltage
20204704
20204705
Load Regulation, 100 mV Overhead
T = 80°C Sourcing Current (Note 14)
Load Regulation, 200 mV Overhead
T = 80°C Sourcing Current (Note 14)
20204740
20204746
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LM26LV
Typical Performance Characteristics
LM26LV
Load Regulation, 400 mV Overhead
T = 80°C Sourcing Current (Note 14)
Load Regulation, 1.72V Overhead
T = 150°C, VDD = 2.4V
Sourcing Current (Note 14)
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20204748
Load Regulation, VDD = 1.6V
Sinking Current (Note 15)
Load Regulation, VDD = 1.8V
Sinking Current (Note 15)
20204741
20204744
Load Regulation, VDD = 2.4V
Sinking Current (Note 15)
Change in VTEMP vs. Overhead Voltage
20204742
20204745
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10
LM26LV
VTEMP Supply-Noise Gain vs. Frequency
VTEMP vs. Supply Voltage
Gain 1: For Trip Points
0 - 69°C
20204743
20204734
VTEMP vs. Supply Voltage
Gain 2: For Trip Points
70 - 109°C
VTEMP vs. Supply Voltage
Gain 3: For Trip Points
110 - 129°C
20204735
20204736
VTEMP vs. Supply Voltage
Gain 4: For Trip Points
130 - 150°C
20204737
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LM26LV
1.0 LM26LV VTEMP vs Die
Temperature Conversion Table
−22
1172
1757
2343
2929
−21
1167
1750
2333
2916
−20
1162
1742
2323
2903
−19
1157
1735
2313
2891
−18
1152
1727
2303
2878
−17
1147
1720
2293
2866
−16
1142
1712
2283
2853
−15
1137
1705
2272
2841
−14
1132
1697
2262
2828
−13
1127
1690
2252
2815
−12
1122
1682
2242
2803
−11
1116
1674
2232
2790
−10
1111
1667
2222
2777
−9
1106
1659
2212
2765
−8
1101
1652
2202
2752
−7
1096
1644
2192
2740
−6
1091
1637
2182
2727
−5
1086
1629
2171
2714
−4
1081
1621
2161
2702
−3
1076
1614
2151
2689
−2
1071
1606
2141
2676
−1
1066
1599
2131
2664
0
1061
1591
2121
2651
3278
1
1056
1583
2111
2638
3266
2
1051
1576
2101
2626
3253
3
1046
1568
2090
2613
1041
1561
2080
2600
The LM26LV has one out of four possible factory-set gains,
Gain 1 through Gain 4, depending on the range of the Temperature Trip Point. The VTEMP temperature sensor voltage,
in millivolts, at each discrete die temperature over the complete operating temperature range, and for each of the four
Temperature Trip Point ranges, is shown in the Conversion
Table below. This table is the reference from which the
LM26LV accuracy specifications (listed in the Electrical Characteristics section) are determined. This table can be used,
for example, in a host processor look-up table. See Section
1.1.1 for the parabolic equation used in the Conversion Table.
VTEMP Temperature Sensor Output Voltage vs Die
Temperature Conversion Table
The VTEMP temperature sensor output voltage, in mV, vs Die
Temperature, in °C, for each of the four gains corresponding
to each of the four Temperature Trip Point Ranges. Gain 1 is
the sensor gain used for Temperature Trip Point 0 - 69°C.
Likewise Gain 2 is for Trip Points 70 - 109 °C; Gain 3 for 110
- 129 °C; and Gain 4 for 130 - 150 °C. VDD = 5.0V. The values
in bold font are for the Trip Point range.
VTEMP, Analog Output Voltage, mV
Die
Temp.,
°C
−50
−49
−48
Gain 1:
for
TTRIP =
0-69°C
1312
1307
1302
Gain 2:
Gain 3:
Gain 4:
for
for
for
TTRIP =
TTRIP =
TTRIP =
70-109°C 110-129°C 130-150°C
1967
1960
1952
2623
2613
2603
−47
1297
1945
2593
3241
4
−46
1292
1937
2583
3229
5
1035
1553
2070
2587
3216
6
1030
1545
2060
2575
1025
1538
2050
2562
−45
1287
1930
2573
−44
1282
1922
2563
3204
7
−43
1277
1915
2553
3191
8
1020
1530
2040
2549
3179
9
1015
1522
2029
2537
1010
1515
2019
2524
−42
1272
1908
2543
−41
1267
1900
2533
3166
10
−40
1262
1893
2523
3154
11
1005
1507
2009
2511
3141
12
1000
1499
1999
2498
995
1492
1989
2486
−39
1257
1885
2513
−38
1252
1878
2503
3129
13
−37
1247
1870
2493
3116
14
990
1484
1978
2473
3104
15
985
1477
1968
2460
3091
16
980
1469
1958
2447
974
1461
1948
2435
−36
−35
1242
1237
1863
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2483
2473
−34
1232
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17
−33
1227
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969
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1938
2422
3054
19
964
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1927
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959
1438
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−32
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−31
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−30
1212
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22
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944
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1810
2413
−28
1202
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2403
3004
23
−27
1197
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2991
24
939
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25
934
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2332
2966
26
928
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1856
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923
1384
1845
2307
918
1377
1835
2294
−26
−25
1192
1187
1788
1780
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−24
1182
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2954
27
−23
1177
1765
2353
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28
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12
913
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2010
101
538
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51
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1997
102
533
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52
794
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1984
103
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53
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1971
104
522
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54
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1958
105
517
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1032
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55
779
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1946
106
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56
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1933
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1920
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LM26LV
29
LM26LV
131
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811
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320
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627
784
144
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616
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303
455
606
757
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298
447
595
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150
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690
linear formula below can be used. Using this formula, with the
constant and slope in the following set of equations, the bestfit VTEMP vs Die Temperature performance can be calculated
with an approximation error less than 18 mV. VTEMP is in mV.
1.1.3 First-Order Approximation (Linear) over Small
Temperature Range
For a linear approximation, a line can easily be calculated
over the desired temperature range from the Conversion Table using the two-point equation:
Where V is in mV, T is in °C, T1 and V1 are the coordinates of
the lowest temperature, T2 and V2 are the coordinates of the
highest temperature.
For example, if we want to determine the equation of a line
with Gain 4, over a temperature range of 20°C to 50°C, we
would proceed as follows:
1.1 VTEMP vs DIE TEMPERATURE APPROXIMATIONS
The LM26LV's VTEMP analog temperature output is very linear. The Conversion Table above and the equation in Section
1.1.1 represent the most accurate typical performance of the
VTEMP voltage output vs Temperature.
1.1.1 The Second-Order Equation (Parabolic)
The data from the Conversion Table, or the equation below,
when plotted, has an umbrella-shaped parabolic curve.
VTEMP is in mV.
Using this method of linear approximation, the transfer function can be approximated for one or more temperature ranges
of interest.
1.1.2 The First-Order Approximation (Linear)
For a quicker approximation, although less accurate than the
second-order, over the full operating temperature range the
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14
The OVERTEMP Active High, Push-Pull Output and the
OVERTEMP Active Low, Open-Drain Output both assert at
the same time whenever the Die Temperature reaches the
factory preset Temperature Trip Point. They also assert simultaneously whenever the TRIP TEST pin is set high. Both
outputs de-assert when the die temperature goes below the
Temperature Trip Point - Hysteresis. These two types of digital outputs enable the user the flexibility to choose the type
of output that is most suitable for his design.
Either the OVERTEMP or the OVERTEMP Digital Output pins
can be left open if not used.
2.2 NOISE IMMUNITY
The LM26LV is virtually immune from false triggers on the
OVERTEMP and OVERTEMP digital outputs due to noise on
the power supply. Test have been conducted showing that,
with the die temperature within 0.5°C of the temperature trip
point, and the severe test of a 3 Vpp square wave "noise"
signal injected on the VDD line, over the VDD range of 2V to
5V, there were no false triggers.
2.1 OVERTEMP OPEN-DRAIN DIGITAL OUTPUT
The OVERTEMP Active Low, Open-Drain Digital Output, if
used, requires a pull-up resistor between this pin and VDD.
The following section shows how to determine the pull-up resistor value.
Determining the Pull-up Resistor Value
3.0 TRIP TEST Digital Input
The TRIP TEST pin simply provides a means to test the
OVERTEMP and OVERTEMP digital outputs electronically
by causing them to assert, at any operating temperature, as
a result of forcing the TRIP TEST pin high.
When the TRIP TEST pin is pulled high the VTEMP pin will be
at the VTRIP voltage.
If not used, the TRIP TEST pin may either be left open or
grounded.
4.0 VTEMP Analog Temperature
Sensor Output
The VTEMP push-pull output provides the ability to sink and
source significant current. This is beneficial when, for example, driving dynamic loads like an input stage on an analogto-digital converter (ADC). In these applications the source
current is required to quickly charge the input capacitor of the
ADC. See the Applications Circuits section for more discussion of this topic. The LM26LV is ideal for this and other
applications which require strong source or sink current.
20204752
The Pull-up resistor value is calculated at the condition of
maximum total current, iT, through the resistor. The total current is:
where,
iT
iL
VOUT
VDD(Max)
4.1 NOISE CONSIDERATIONS
The LM26LV's supply-noise gain (the ratio of the AC signal
on VTEMP to the AC signal on VDD) was measured during
bench tests. It's typical attenuation is shown in the Typical
Performance Characteristics section. A load capacitor on the
output can help to filter noise.
For operation in very noisy environments, some bypass capacitance should be present on the supply within approximately 2 inches of the LM26LV.
iT is the maximum total current through the Pull-up
Resistor at VOL.
iL is the load current, which is very low for typical
digital inputs.
VOUT is the Voltage at the OVERTEMP pin. Use
VOL for calculating the Pull-up resistor.
VDD(Max) is the maximum power supply voltage to be
used in the customer's system.
The pull-up resistor maximum value can be found by using
the following formula:
4.2 CAPACITIVE LOADS
The VTEMP Output handles capacitive loading well. In an extremely noisy environment, or when driving a switched sampling input on an ADC, it may be necessary to add some
filtering to minimize noise coupling. Without any precautions,
the VTEMP can drive a capacitive load less than or equal to
1100 pF as shown in Figure 1. For capacitive loads greater
than 1100 pF, a series resistor is required on the output, as
shown in Figure 2, to maintain stable conditions.
EXAMPLE CALCULATION
Suppose we have, for our example, a V DD of 3.3 V ± 0.3V, a
CMOS digital input as a load, a VOL of 0.2 V.
15
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LM26LV
(1) We see that for VOL of 0.2 V the electrical specification for
OVERTEMP shows a maximim isink of 385 µA.
(2) Let iL= 1 µA, then iT is about 386 µA max. If we select
35 µA as the current limit then iT for the calculation becomes
35 µA
(3) We notice that VDD(Max) is 3.3V + 0.3V = 3.6V and then
calculate the pull-up resistor as
RPull-up = (3.6 − 0.2)/35 µA = 97k
(4) Based on this calculated value, we select the closest resistor value in the tolerance family we are using.
In our example, if we are using 5% resistor values, then the
next closest value is 100 kΩ.
2.0 OVERTEMP and OVERTEMP
Digital Outputs
LM26LV
To ensure good temperature conductivity, the backside of the
LM26LV die is directly attached to the GND pin (Pin 2). The
temperatures of the lands and traces to the other leads of the
LM26LV will also affect the temperature reading.
Alternatively, the LM26LV can be mounted inside a sealedend metal tube, and can then be dipped into a bath or screwed
into a threaded hole in a tank. As with any IC, the LM26LV
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. If moisture creates a short circuit from
the VTEMP output to ground or VDD, the VTEMP output from the
LM26LV will not be correct. Printed-circuit coatings are often
used to ensure that moisture cannot corrode the leads or circuit traces.
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. The equation used to
calculate the rise in the LM26LV's die temperature is
20204715
FIGURE 1. LM26LV No Decoupling Required for
Capacitive Loads Less than 1100 pF.
20204733
CLOAD
RS
1.1 nF to 99 nF
3 kΩ
100 nF to 999 nF
1.5 kΩ
1 μF
800 Ω
where TA is the ambient temperature, IQ is the quiescent current, IL is the load current on the output, and VO is the output
voltage. For example, in an application where TA = 30 °C,
VDD = 5 V, IDD = 9 μA, Gain 4, VTEMP = 2231 mV, and
IL = 2 μA, the junction temperature would be 30.021 °C, showing a self-heating error of only 0.021°C. Since the LM26LV's
junction temperature is the actual temperature being measured, care should be taken to minimize the load current that
the VTEMP output is required to drive. If The OVERTEMP output is used with a 100 k pull-up resistor, and this output is
asserted (low), then for this example the additional contribution is [(152° C/W)x(5V)2/100k] = 0.038°C for a total selfheating error of 0.059°C. Figure 3 shows the thermal
resistance of the LM26LV.
FIGURE 2. LM26LV with series resistor for capacitive
loading greater than 1100 pF.
4.3 VOLTAGE SHIFT
The LM26LV is very linear over temperature and supply voltage range. Due to the intrinsic behavior of an NMOS/PMOS
rail-to-rail buffer, a slight shift in the output can occur when
the supply voltage is ramped over the operating range of the
device. The location of the shift is determined by the relative
levels of VDD and VTEMP. The shift typically occurs when
VDD − VTEMP = 1.0V.
This slight shift (a few millivolts) takes place over a wide
change (approximately 200 mV) in VDD or VTEMP. Since the
shift takes place over a wide temperature change of 5°C to
20°C, VTEMP is always monotonic. The accuracy specifications in the Electrical Characteristics table already includes
this possible shift.
NS Package
Number
Thermal
Resistance (θJA)
LM26LVCISD
SDB06A
152° C/W
FIGURE 3. LM26LV Thermal Resistance
5.0 Mounting and Temperature
Conductivity
The LM26LV can be applied easily in the same way as other
integrated-circuit temperature sensors. It can be glued or cemented to a surface.
www.national.com
Device Number
16
LM26LV
6.0 Applications Circuits
20204761
FIGURE 4. Temperature Switch Using Push-Pull Output
20204762
FIGURE 5. Temperature Switch Using Open-Drain Output
20204728
Most CMOS ADCs found in microcontrollers and ASICs have a sampled data comparator input structure. When the ADC charges
the sampling cap, it requires instantaneous charge from the output of the analog source such as the LM26LV temperature sensor
and many op amps. This requirement is easily accommodated by the addition of a capacitor (CFILTER). The size of CFILTER depends
on the size of the sampling capacitor and the sampling frequency. Since not all ADCs have identical input stages, the charge
requirements will vary. This general ADC application is shown as an example only.
FIGURE 6. Suggested Connection to a Sampling Analog-to-Digital Converter Input Stage
17
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LM26LV
20204718
FIGURE 7. Celsius Temperature Switch
20204760
FIGURE 8. TRIP TEST Digital Output Test Circuit
20204765
The TRIP TEST pin, normally used to check the operation of the OVERTEMP and OVERTEMP pins, may be used to latch the
outputs whenever the temperature exceeds the programmed limit and causes the digital outputs to assert. As shown in the figure,
when OVERTEMP goes high the TRIP TEST input is also pulled high and causes OVERTEMP output to latch high and the
OVERTEMP output to latch low. Momentarily switching the TRIP TEST input low will reset the LM26LV to normal operation. The
resistor limits the current out of the OVERTEMP output pin.
FIGURE 9. Latch Circuit using OVERTEMP Output
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18
LM26LV
Physical Dimensions inches (millimeters) unless otherwise noted
6-Lead LLP-6 Package
Order Number LM26LVCISD, LM26LVCISDX
NS Package Number SDB06A
19
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LM26LV 1.6 V, LLP-6 Factory Preset Temperature Switch and Temperature Sensor
Notes
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