LINEAR TECHNOLOGY LT3092 Technical data

Convert Temperature to Current at High Linearity with LT3092
Current Source –

Design Note 484

Todd Owen

Electronics 101

One of the fi rst lessons in a basic electronics course
covers the symbols for resistors, capacitors, induc­tors, voltage sources and current sources. Although
each symbol represents a functional component of a
real-world circuit, only some of the symbols have direct
physical counterparts. For instance, the three discrete
passive devices—resistors, capacitors, inductors—can
be picked off a shelf and placed on a real board much
as their symbolic analogs appear in a basic schematic.
Likewise, while voltage sources have no direct 2-terminal
analog, a voltage source can be easily built with an off­the-shelf linear regulator.

The black sheep of basic electronics symbols has long
been the 2-terminal current source. The symbol shows
up in every basic electronics course, but Electronics 101
instructors must take time to explain away the lack of
a real-world equivalent. The symbol presents a simple
electronics concept, but building a current source has,
until now, been a complex undertaking.

A Real 2-Terminal Current Source

With the introduction of the LT®3092, it is now as easy
to produce a 2-terminal current source as it is to create a
voltage source. Figure 1 shows how the LT3092 uses an
internal current source and error amplifi er, together with
the ratio of two external resistors, to program a constant
output current at any level between 0.5mA and 200mA.

VIN – V

= 1.2V TO 40V

OUT

LT3092

I

SOURCE

Figure 1. 2-Terminal Current Source Requires Only Two
Resistors to Program

IN

10μA

+
–

SET OUT

R

SET

= 10μA •

DN484 F01

R

SET

R

OUT

R

OUT

The fl at temperature coeffi cient of the internal reference
c u r r e n t ( h i g h l i g h t e d i n F i g u r e 2 ) i s a s g o o d a s m a n y v o l t a g e
references. Low TC resistors do not need to be used; the
temperature coeffi cients of the external resistors need
only match one another for optimum results.

No frequency compensation or supply bypass capacitors
are needed. Frequency compensation is internal and the
internal reference circuitry is buffered to protect it from
line changes.

No input-to-output capacitors are required. While exten­sive testing has been done to ensure stable operation
under the widest possible set of conditions, complex load
impedance conditions could provoke instability. As such,
testing in situ with fi nal component values is highly rec­ommended. If stability issues occur, they can be resolved
with small capacitors or series RC combinations placed
on the input, output, or from input to output.

The LT3092 offers all the protection features expected
from a high performance product: thermal shutdown,
overcurrent protection, reverse-voltage and reverse­current protection. Because a simple resistor ratio sets
the current, a wide variety of techniques can be utilized
to adjust the current on the fl y. The LT3092 can also be
confi gured as a linear regulator without ou tput capacitors
for use in intrinsic safety environments.

L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks of
Linear Technology Corporation. All other trademarks are the property of their respective
owners.

10.100

10.075

10.050

10.025

10.000

9.975

SET PIN CURRENT (μA)

9.950

9.925

9.900
–25025 50 10075 125

–50

TEMPERATURE (°C)

Figure 2. SET Pin Current vs Temperature

150

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11/10/484

The LT3092 as a T-to-I Converter

Omega’s 44200 series linear thermistor kits* include
thermistors and resistors that together create a linear
response to temperature when appropriately confi gured.
These kits generate either a voltage or resistance pro­portional to temperature with high accuracy; the #44201
kit is listed for the 0°C to 100°C temperature range with

0.15°C accuracy.

Obviously, these kits easily satisfy the needs of a wide
variety of applications, but problems arise when the
thermi stor mus t be pl ace d at th e end of a long wir e—ap ­plication information from Omega suggests no more
than 100 feet of #22 wire for thermistor kit #44201. Wire
impedance interferes with the thermistor resistance and
defeats the accuracy inherent in the kit.

By adding the LT3092 to the thermistor kit along with
three 0.1% accuracy resistors and one fi nal trim, a very
accurate 2-terminal temperature-to-current conver ter can
be built. This circuit measures 700μA operating current
at 0°C, dropping by 2μA every degree until 100°C, at
which point the current measures 500μA. The obvious
advantage to this T-to-I converter over a T-to-V converter
is that current remains constant regardless of the wire
length—as long as there is suffi cient voltage to meet the
compliance of the LT3092 circuit while not exceeding
its absolute maximum. Electronics 101: Kirchoff’s laws
dictate conservation of current in the wire runs as long
as there are no nodes for current to leak along the run.

A

B

+
–

SET

R1
29400Ω

TRIM•RT

R2 • R3

R2

1870Ω

IN

I

3

I

2

OUT

C

R3
1470Ω

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(t)

LT3092

I

1

10μA

R

TRIM

2k

R1TH
3200Ω

R1 + R

R

(t)

TRIM

T

+

+

R3

R3

TRIM

2V TO 40V

+

V

IN

–

RT(t) = RESISTANCE OF THERMISTOR
= 2768.23Ω – 17.115 • TΩ/°C
FOR OMEGA #44201 KIT
= –17.115Ω/°C FOR OMEGA #44201 KIT

I

OUT

dI

OUT

dt

I = 700μA-2μA/°C

dR

T

dt

R2TH

OMEGA KIT #44201

6250Ω

RED

BRN

TC1
TH1

GRN

R1 + R

= 10μA +

= 10μA

TRIM



R2

dR

1

T

+

 



dt

R3

TC2
TH2

R1 + R

R1 + R

R2 • R3

Figure 3. 2-Terminal Temperature-to-Current Thermometer
Suitable for Use at the End of Long Wire Runs

Data Sheet Download

www.linear.com

Figure 3 shows the schematic for linear thermistor kit
#44201 from Omega with the LT3092 and the additional
resistor values. The formulas under the fi gure allow for
substitution of other thermistor kit values and determi­nation of appropriate complementary resistors to fi t the
application.

Once the initial circuit is built, any initial tolerance, varia­tions, and offsets are easily trimmed out by connecting
a voltmeter from node A to node B and trimming the
potentiometer to measure 302mV (for this design). This
voltage remains constant regardless of temperature.

Now, one wire runs out and back for temperature sens­ing at signifi cant distances. By providing input voltage
above the compliance level of the LT3092 (less than 2V
for this circuit and resistor combination) and sensing the
resultant current (use a 1k resistor and DVM) one can
measure temperature. Figure 4 shows the current output
from the circuit across temperature and the difference
between measured and calculated response.

Conclusion

The LT 3092 requires only two external resistors to produce
a 2-terminal current source that references to input or
ground, or sits in series with signal lines.

A 2-terminal current source enables a number of ap­plications, especially those involving long wire runs, as
Kirchoff’s laws dictate the conservation of current over
long wire distances—distances where a voltage signal
would be corrupted. T he example presented here uses the
LT3092 and a linear thermistor kit to conver t temperature
to current, creating a 2-terminal current output thermom­eter. Placing this in series with long distances of wire
maintains accuracy despite the distance of wire used.

*Available from www.omega.com

750

700

650

600

550

OUTPUT CURRENT (μA)

500

450

20 40 60 80

TEMPERATURE (°C)

Figure 4. Calculated vs Measured Performance of the
Thermometer in Figure 3.

For applications help,

call (408) 432-1900, Ext. 3805

3

AND CALCULATED TEMPERATURE (°C)

DIFFERENCE BETWEEN MEASURED

2

1

0

–1

–2

–3

10010030507090

DN484 F04

Linear Technology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7417

(408) 432-1900

●

FAX: (408) 434-0507 ● www.linear.com

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