LT1461

Micropower Precision

Low Dropout Series

Voltage Reference Family

Trimmed to High Accuracy: 0.04% Max

Low Drift: 3ppm/

C Max

Low Supply Current: 50

A Max

Temperature Coefficient Guaranteed to 125

High Output Current: 50mA Min

Low Dropout Voltage: 300mV Max

Excellent Thermal Regulation

Power Shutdown

Thermal Limiting

Operating Temperature Range: 40

C to 125

Voltage Options: 2.5V, 3V, 3.3V, 4.096V and 5V

The LT

1461 is a family of low dropout micropower bandgap

references that combine very high accuracy and low drift with
low supply current and high output drive. These series
references use advanced curvature compensation techniques
to obtain low temperature coefficient and trimmed precision
thin-film resistors to achieve high output accuracy. The
LT1461 family draws only 35

A of supply current, making

them ideal for low power and portable applications, however
their high 50mA output drive makes them suitable for higher
power requirements, such as precision regulators.

In low power applications, a dropout voltage of less than
300mV ensures maximum battery life while maintaining full
reference performance. Line regulation is nearly immeasur-
able, while the exceedingly good load and thermal regulation
will not add significantly to system error budgets. The
shutdown feature can be used to switch full load currents and
can be used for system power down. Thermal shutdown
protects the part from overload conditions. The LT1461 is
available in 2.5V, 3V, 3.3V 4.096V and 5V options.

A/D and D/A Converters

Precision Regulators

Handheld Instruments

Power Supplies

, LTC and LT are registered trademarks of Linear Technology Corporation.

OUT

+ 0.3V)

20V

1461 TA01

LT1461

LT1461-2.5 Load Regulation, P

DISS

= 200mW

Basic Connection

0mA

OUT

20mA

OUT

LOAD REG

1mV/DIV

10ms/DIV

1461 TA02

FEATURES

DESCRIPTIO

APPLICATIO S

TYPICAL APPLICATIO

LT1461

ORDER PART

NUMBER

JMAX

= 150

= 190

C/ W

(Note 3)

TOP VIEW

*DNC: DO NOT CONNECT

DNC*

OUT

DNC*

SHDN

GND

S8 PACKAGE

8-LEAD PLASTIC SO

Consult factory for Military grade parts.

Input Voltage ........................................................... 20V
Output Short-Circuit Duration ......................... Indefinite
Operating Temperature Range

(Note 2) ........................................... 40

C to 125

Storage Temperature Range (Note 3) ... 65

C to 150

ABSOLUTE AXI U RATI GS

Specified Temperature Range

Commercial ............................................ 0

C to 70

Industrial ........................................... 40

C to 85

High ................................................. 40

C to 125

Lead Temperature (Soldering, 10 sec).................. 300

(Note 1)

LT1461ACS8-2.5
LT1461BCS8-2.5
LT1461CCS8-2.5
LT1461AIS8-2.5
LT1461BIS8-2.5
LT1461CIS8-2.5
LT1461DHS8-2.5
LT1461ACS8-3
LT1461BCS8-3
LT1461CCS8-3
LT1461AIS8-3
LT1461BIS8-3
LT1461CIS8-3
LT1461DHS8-3

461A25
461B25
461C25
61AI25
61BI25
61CI25
61DH25
1461A3
1461B3
1461C3
461AI3
461BI3
461CI3
461DH3

LT1461ACS8-3.3
LT1461BCS8-3.3
LT1461CCS8-3.3
LT1461AIS8-3.3
LT1461BIS8-3.3
LT1461CIS8-3.3
LT1461DHS8-3.3
LT1461ACS8-4
LT1461BCS8-4
LT1461CCS8-4
LT1461AIS8-4
LT1461BIS8-4
LT1461CIS8-4
LT1461DHS8-4

LT1461ACS8-5
LT1461BCS8-5
LT1461CCS8-5
LT1461AIS8-5
LT1461BIS8-5
LT1461CIS8-5
LT1461DHS8-5

S8 PART MARKING

AVAILABLE OPTIO S

INITIAL

TEMPERATURE

OUTPUT VOLTAGE

ACCURACY

COEFFICIENT

RANGE

2.5V

3.0V

3.3V

4.096V

5.0V

0.04% Max

3ppm/

C Max

C to 70

LT1461ACS8-2.5

LT1461ACS8-3

LT1461ACS8-3.3

LT1461ACS8-4

LT1461ACS8-5

0.04% Max

3ppm/

C Max

C to 85

LT1461AIS8-2.5

LT1461AIS8-3

LT1461AIS8-3.3

LT1461AIS8-4

LT1461AIS8-5

0.06% Max

7ppm/

C Max

C to 70

LT1461BCS8-2.5

LT1461BCS8-3

LT1461BCS8-3.3

LT1461BCS8-4

LT1461BCS8-5

0.06% Max

7ppm/

C Max

C to 85

LT1461BIS8-2.5

LT1461BIS8-3

LT1461BIS8-3.3

LT1461BIS8-4

LT1461BIS8-5

0.08% Max

12ppm/

C Max

C to 70

LT1461CCS8-2.5

LT1461CCS8-3

LT1461CCS8-3.3

LT1461CCS8-4

LT1461CCS8-5

0.08% Max

12ppm/

C Max

C to 85

LT1461CIS8-2.5

LT1461CIS8-3

LT1461CIS8-3.3

LT1461CIS8-4

LT1461CIS8-5

0.15% Max

20ppm/

C Max

C to 125

LT1461DHS8-2.5

LT1461DHS8-3

LT1461DHS8-3.3

LT1461DHS8-4

LT1461DHS8-5

461A33
461B33
461C33
61AI33
61BI33
61CI33
61DH33
1461A4
1461B4
1461C4
461AI4
461BI4
461CI4
461DH4

1461A5
1461B5
1461C5
461AI5
461BI5
461CI5
461DH5

PACKAGE/ORDER I FOR ATIO

LT1461

PARAMETER

CONDITIONS

MIN

TYP

MAX

UNITS

Output Voltage (Note 4)

LT1461ACS8/LT1461AIS8

0.04

LT1461BCS8/LT1461BIS8

0.06

LT1461CCS8/LT1461CIS8

0.08

LT1461DHS8

0.15

Output Voltage Temperature Coefficient (Note 5)

LT1461ACS8/LT1461AIS8

ppm/

LT1461BCS8/LT1461BIS8

ppm/

LT1461CCS8/LT1461CIS8

ppm/

LT1461DHS8

ppm/

Line Regulation

OUT

+ 0.5V)

20V

ppm/V

LT1461DHS8

ppm/V

Load Regulation Sourcing (Note 6)

= V

OUT

+ 2.5V

OUT

50mA

ppm/mA

LT1461DHS8, 0

OUT

10mA

ppm/mA

Dropout Voltage

OUT

, V

OUT

Error = 0.1%

OUT

= 0mA

0.06

OUT

= 1mA

0.13

0.3

OUT

= 10mA

0.20

0.4

OUT

= 50mA, I and C Grades Only

1.50

2.0

Output Current

Short V

OUT

to GND

100

Shutdown Pin

Logic High Input Voltage

2.4

Logic High Input Current, Pin 3 = 2.4V

Logic Low Input Voltage

0.8

Logic Low Input Current, Pin 3 = 0.8V

0.5

Supply Current

No Load

Shutdown Current

= 1k

Output Voltage Noise (Note 7)

0.1Hz

10Hz

ppm

P-P

10Hz

1kHz

9.6

ppm

RMS

Long-Term Drift of Output Voltage, SO-8 Package (Note 8)

See Applications Information

ppm/

kHr

Thermal Hysteresis (Note 9)

T = 0

C to 70

ppm

T = 40

C to 85

ppm

T = 40

C to 125

120

ppm

The

denotes specifications which apply over the specified temperature

range, otherwise specifications are at T

= 25

C. V

 V

OUT

= 0.5V, Pin 3 = 2.4V, C

= 2

F, unless otherwise specified.

ELECTRICAL CHARACTERISTICS

Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.

Note 2: The LT1461 is guaranteed functional over the operating
temperature range of 40

C to 125

Note 3: If the part is stored outside of the specified temperature range, or
the junction temperature exceeds the specified temperature range, the
output may shift due to hysteresis.

Note 4: ESD (Electrostatic Discharge) sensitive device. Extensive use of
ESD protection devices are used internal to the LT1461, however, high
electrostatic discharge can damage or degrade the device. Use proper ESD
handling precautions.

Note 5: Temperature coefficient is calculated from the minimum and
maximum output voltage measured at T

MIN

, Room and T

MAX

as follows:

TC = (V

OMAX

OMIN

)/(T

MAX

MIN

)

Incremental slope is also measured at 25

Note 6: Load regulation is measured on a pulse basis from no load to the
specified load current. Output changes due to die temperature change
must be taken into account separately.

Note 7: Peak-to-peak noise is measured with a single pole highpass filter
at 0.1Hz and a 2-pole lowpass filter at 10Hz. The unit is enclosed in a still-
air environment to eliminate thermocouple effects on the leads. The test
time is 10 seconds. RMS noise is measured with a single pole highpass
filter at 10Hz and a 2-pole lowpass filter at 1kHz. The resulting output is
full-wave rectified and then integrated for a fixed period, making the final
reading an average as opposed to RMS. A correction factor of 1.1 is used
to convert from average to RMS and a second correction of 0.88 is used to
correct for the nonideal bandpass of the filters.

LT1461

ELECTRICAL CHARACTERISTICS

Note 8: Long-term drift typically has a logarithmic characteristic and
therefore, changes after 1000 hours tend to be much smaller than before
that time. Total drift in the second thousand hours is normally less than
one third that of the first thousand hours with a continuing trend toward
reduced drift with time. Long-term drift will also be affected by differential
stresses between the IC and the board material created during board
assembly. See the Applications Information section.

Note 9: Hysteresis in output voltage is created by package stress that
depends on whether the IC was previously at a higher or lower
temperature. Output voltage is always measured at 25

C, but the IC is

cycled hot or cold before successive measurements. Hysteresis is roughly
proportional to the square of the temperature change. Hysteresis is not
normally a problem for operational temperature excursions where the
instrument might be stored at high or low temperature. See Applications
Information section.

TEMPERATURE (

60 40 20

2.4980

REFERENCE VOLTAGE (V)

2.4985

2.4995

2.5000

2.5005

80 100

1461 G01

2.4990

120

2.5010

2.5015

2.5020

TEMPCO 60

C TO 120

3 TYPICAL PARTS

2.5V Reference Voltage
vs Temperature

TEMPERATURE (

40 20

LINE REGULATION (ppm/V)

120

1461 G03

100

SUPPLY

= 15V

5V 20V

2.5V Line Regulation
vs Temperature

2.5V Load Regulation

OUTPUT CURRENT (mA)

0.1

800

OUTPUT VOLTAGE CHANGE (ppm)

1200

1600

100

1461 G02

400

125

= 7.5V

TYPICAL PERFOR A CE CHARACTERISTICS

Characteristic curves are similar for most LT1461s.

Curves from the LT1461-2.5 and the LT1461-5 represent the extremes of the voltage options. Characteristic curves for other output
voltages fall between these curves and can be estimated based on their output.

2.5V Ripple Rejection Ratio
vs Frequency

2.5V Minimum Input/Output
Voltage Differential vs Load Current

OUTPUT CURRENT (mA)

0.1

INPUT/OUTPUT VOLTAGE (V)

100

1461 G04

125

2.5V Supply Current
vs Input Voltage

INPUT VOLTAGE (V)

SUPPLY CURRENT (

1000

1461 G05

100

125

FREQUENCY (kHz)

0.01

RIPPLE REJECTION RATIO (dB)

0.1

100

1000

1641 G06

100

LT1461

2.5V Turn-On Time

2.5V Output Impedance
vs Frequency

2.5V Turn-On Time

FREQUENCY (kHz)

0.01

OUTPUT IMPEDANCE (

)

100

1000

0.1

1461 G07

OUT

= 2

OUT

= 1

TIME (100

s/DIV)

VOLTAGE (V)

1461 G08

= 1

= 2

OUT

TIME (100

s/DIV)

VOLTAGE (V)

1461 G09

= 1

= 2

= 50

OUT

TYPICAL PERFOR A CE CHARACTERISTICS

Characteristic curves are similar for most LT1461s.

2.5V Transient Response to 10mA
Load Step

OUT

0mA

10mA/DIV

OUT

50mV/DIV

1461 G10

2.5V Line Transient Response

OUT

50mV/DIV

1461 G11

= 0.1

2.5V Output Noise
0.1Hz

10Hz

= 2

TIME (2SEC/DIV)

OUTPUT NOISE (10

V/DIV)

1461 G12

LT1461

TYPICAL PERFOR A CE CHARACTERISTICS

Characteristic curves are similar for most LT1461s.

5V Reference Voltage
vs Temperature

5V Line Regulation
vs Temperature

5V Load Regulation

5V Ripple Rejection Ratio
vs Frequency

5V Minimum Input/Output Voltage
Differential vs Load Current

5V Supply Current
vs Input Voltage

TEMPERATURE (

REFERENCE VOLTAGE (V)

5.0040

5.0030

5.0020

5.0010

5.0000

4.9990

4.9980

4.9970

4.9960

4.9950

4.9940

4.9930

1461 G13

80 100 120

TEMPCO 60

C TO 120

3 TYPICAL PARTS

OUTPUT CURRENT (mA)

0.1

800

LOAD REGULATION (ppm)

1200

1600

100

1461 G14

400

2000

= 10V

125

TEMPERATURE (

LINE REGULATION (ppm

/
V

)

120

1461 G15

100

SUPPLY

= 14V

6V TO 20V

OUTPUT CURRENT (mA)

0.1

0.01

INPUT/OUTPUT VOLTAGE (V)

0.1

100

1461 G16

125

INPUT VOLTAGE (V)

SUPPLY CURRENT (

100

1000

10000

1461 G17

125

FREQUENCY (kHz)

0.01

RIPPLE REJECTION RATIO (dB)

0.1

100

1000

1461 G18

100

5V Output Impedance vs Frequency

5V Turn-On Time

FREQUENCY (kHz)

0.01

OUTPUT IMPEDANCE (

)

100

1000

0.1

1461 G19

OUT

= 2

OUT

= 1

200

s/DIV

2V/DIV

1461 G20

OUT

= 1

OUT

= 2

OUT

= 0

200

s/DIV

2V/DIV

1461 G21

OUT

= 1

OUT

= 2

OUT

= 50mA

5V Turn-On Time

LT1461

TYPICAL PERFOR A CE CHARACTERISTICS

Characteristic curves are similar for most LT1461s.

5V Transient Response to 10mA
Load Step

OUT

50mV/DIV

1461 G22

5V Line Transient Response

5V Output Noise
0.1Hz

10Hz

= 2

0mA

10mA

Supply Current
vs Temperature

Current Limit vs Temperature

SHDN Pin Current
vs SHDN Input Voltage

OUT

50mV/DIV

1461 G23

= 0.1

TIME (2SEC/DIV)

OUTPUT NOISE (10

V/DIV)

1461 G24

TEMPERATURE (

SUPPLY CURRENT (

120

1461 G25

100

S(SHDN)

TEMPERATURE (

CURRENT LIMIT (mA)

140

1461 G26

120

100

125

SHDN PIN INPUT VOLTAGE (V)

SHDN PIN CURRENT (

100

200

140

1461 G27

160

125

180

120

LT1461

HYSTERESIS (ppm)

200

NUMBER OF UNITS

WORST-CASE HYSTERESIS
ON 35 UNITS

160

120

160

200

C TO 25

125

C TO 25

1461 G31

HYSTERESIS (ppm)

100

NUMBER OF UNITS

WORST-CASE HYSTERESIS
ON 35 UNITS

100

C TO 25

1461 G30

HYSTERESIS (ppm)

100

NUMBER OF UNITS

WORST-CASE HYSTERESIS
ON 35 UNITS

1461 G29

C TO 25

100

 40

C to 85

C Hysteresis

 40

C to 125

C Hysteresis

C to 70

C Hysteresis

TYPICAL PERFOR A CE CHARACTERISTICS

Characteristic curves are similar for most LT1461s.

LT1461

APPLICATIO S I FOR ATIO

Examples shown in this Applications section use the
LT1461-2.5. The response of other voltage options can
be estimated by proper scaling.

Bypass and Load Capacitors

The LT1461 family requires a capacitor on the input and
on the output for stability. The capacitor on the input is a
supply bypass capacitor and if the bypass capacitors
from other components are close (within 2 inches) they

*SEE APPLICATIONS INFORMATION FOR DETAILED EXPLANATION OF LONG-TERM DRIFT

Long-Term Drift (Number of Data Points Reduced at 650 Hours)*

TYPICAL PERFOR A CE CHARACTERISTICS

Characteristic curves are similar for most LT1461s.

HOURS

ppm

150

250

100

200

400

800

1200

1600

1461 G15

2000

200

600

1000

1400

1800

LT1461S8
3 TYPICAL PARTS SOLDERED ONTO PCB
T

= 30

OUT

200mV/DIV

1461 F02

Figure 2. 50mA Load Step with C

= 2

OUT

50mA/DIV

0mA

1mA

OUT

1mA/DIV

OUT

20mV/DIV

1461 F01

Figure 1. 1mA Load Step with C

= 1

should be sufficient. The output capacitor acts as fre-
quency compensation for the reference and cannot be
omitted. For light loads

1mA, a 1

F nonpolar output

capacitor is usually adequate, but for higher loads (up to
75mA), the output capacitor should be 2

F or greater.

Figures 1 and 2 show the transient response to a 1mA
load step with a 1

F output capacitor and a 50mA load

step with a 2

F output capacitor.

LT1461

Precision Regulator

The LT1461 will deliver 50mA with V

= V

OUT

+ 2.5V and

higher load current with higher V

. Load regulation is

typically 12ppm/mA, which means for a 50mA load step,
the output will change by only 1.5mV. Thermal regulation,
caused by die temperature gradients and created from
load current or input voltage changes, is not measurable.
This often overlooked parameter must be added to normal
line and load regulation errors. The load regulation photo,
on the first page of this data sheet, shows the output
response to 200mW of instantaneous power dissipation
and the reference shows no sign of thermal errors. The
reference has thermal shutdown and will turn off if the
junction temperature exceeds 150

Shutdown

The shutdown (Pin 3 low) serves to shut off load current
when the LT1461 is used as a regulator. The LT1461
operates normally with Pin 3 open or greater than or equal
to 2.4V. In shutdown, the reference draws a maximum
supply current of 35

A. Figure 3 shows the transient

response of shutdown while the part is delivering 25mA.
After shutdown, the reference powers up in about 200

1461 F03

Figure 3. Shutdown While Delivering 25mA, R

= 100

PIN 3

OUT

PC Board Layout

In 13- to 16-bit systems where initial accuracy and tem-
perature coefficient calibrations have been done, the me-
chanical and thermal stress on a PC board (in a card cage
for instance) can shift the output voltage and mask the true
temperature coefficient of a reference. In addition, the
mechanical stress of being soldered into a PC board can
cause the output voltage to shift from its ideal value.
Surface mount voltage references are the most suscep-
tible to PC board stress because of the small amount of
plastic used to hold the lead frame.

A simple way to improve the stress-related shifts is to
mount the reference near the short edge of the PC board,
or in a corner. The board edge acts as a stress boundary,
or a region where the flexure of the board is minimum. The
package should always be mounted so that the leads
absorb the stress and not the package. The package is
generally aligned with the leads parallel to the long side of
the PC board as shown in Figure 5a.

A qualitative technique to evaluate the effect of stress on
voltage references is to solder the part into a PC board and
deform the board a fixed amount as shown in Figure 4. The
flexure #1 represents no displacement, flexure #2 is
concave movement, flexure #3 is relaxation to no dis-
placement and finally, flexure #4 is a convex movement.
This motion is repeated for a number of cycles and the

APPLICATIO S I FOR ATIO

1461 F04

Figure 4. Flexure Numbers

LT1461

The most effective technique to improve PC board stress
is to cut slots in the board around the reference to serve as
a strain relief. These slots can be cut on three sides of the
reference and the leads can exit on the fourth side. This
"tongue" of PC board material can be oriented in the long
direction of the board to further reduce stress transferred
to the reference.

The results of slotting the PC boards of Figures 5a and
5b are shown in Figures 6a and 6b. In this example the
slots can improve the output shift from about 100ppm to
nearly zero.

relative output deviation is noted. The result shown in
Figure 5a is for two LT1461S8-2.5s mounted vertically and
Figure 5b is for two LT1461S8-2.5s mounted horizontally.
The parts oriented in Figure 5a impart less stress into the
package because stress is absorbed in the leads. Figures
5a and 5b show the deviation to be between 125

V and

250

V and implies a 50ppm and 100ppm change respec-

tively. This corresponds to a 13- to 14-bit system and is
not a problem for most 10- to 12-bit systems unless the
system has a calibration. In this case, as with temperature
hysteresis, this low level can be important and even more
careful techniques are required.

SLOT

FLEXURE NUMBER

1461 F06a

OUTPUT DEVIATION (mV)

Figure 6a. Same Two LT1461S8-2.5s in Figure 5a, but with Slots

SLOT

FLEXURE NUMBER

1461 F06b

OUTPUT DEVIATION (mV)

Figure 6b. Same Two LT1461S8-2.5s in Figure 5b, but with Slots

LONG DIMENSION

FLEXURE NUMBER

1461 F05a

OUTPUT DEVIATION (mV)

Figure 5a. Two Typical LT1461S8-2.5s,
Vertical Orientation Without Slots

FLEXURE NUMBER

1461 F05b

LONG DIMENSION

OUTPUT DEVIATION (mV)

Figure 5b. Two Typical LT1461S8-2.5s,
Horizontal Orientation Without Slots

APPLICATIO S I FOR ATIO

LT1461

Long-Term Drift

Long-term drift cannot be extrapolated from acceler-
ated high temperature testing. This erroneous technique
gives drift numbers that are wildly optimistic. The only
way long-term drift can be determined is to measure it
over the time interval of interest. The erroneous tech-
nique uses the Arrhenius Equation to derive an accelera-
tion factor from elevated temperature readings. The
equation is:

K T

where: E

= Activation Energy (Assume 0.7)

K = Boltzmann's Constant
T2 = Test Condition in

Kelvin

T1 = Use Condition Temperature in

Kelvin

To show how absurd this technique is, compare the
LT1461 data. Typical 1000 hour long-term drift at 30

C =

60ppm. The typical 1000 hour long-term drift at 130

C =

120ppm. From the Arrhenius Equation the acceleration
factor is:

0 7

0 0000863

303

403

767

The erroneous projected long-term drift is:

120ppm/767 = 0.156ppm/1000 hr

For a 2.5V reference, this corresponds to a 0.39

V shift

after 1000 hours. This is pretty hard to determine (read
impossible) if the peak-to-peak output noise is larger than
this number. As a practical matter, one of the best labora-
tory references available is the Fluke 732A and its long-
term drift is 1.5

V/mo. This performance is only available

from the best subsurface zener references utilizing spe-
cialized heater techniques.

The LT1461 long-term drift data was taken with parts that
were soldered onto PC boards similar to a "real world"
application. The boards were then placed into a constant
temperature oven with T

= 30

C, their outputs were

scanned regularly and measured with an 8.5 digit DVM. As
an additional accuracy check on the DVM, a Fluke 732A
laboratory reference was also scanned. Figure 7 shows the
long-term drift measurement system. The data taken is
shown at the end of the Typical Performance Characteris-
tics section of this data sheet. The long-term drift is the
trend line that asymptotes to a value at 2000 hours. Note
the slope in output shift between 0 hours and 1000 hours
compared to the slope between 1000 hours and 2000
hours. Long-term drift is affected by differential stresses
between the IC and the board material created during
board assembly.

PCB3

SCANNER

1461 F07

FLUKE

732A

LABORATORY

REFERENCE

PCB2

PCB1

COMPUTER

8.5 DIGIT

DVM

Figure 7. Long-Term Drift Measurement Setup

Hysteresis

The hysteresis curves found in the Typical Performance
Characteristics represent the worst-case data taken on 35
typical parts after multiple temperature cycles. As ex-
pected, the parts that are cycled over the wider 40

C to

125

C temperature range have more hysteresis than those

cycled over lower ranges. Note that the hysteresis coming
from 125

C to 25

C has an influence on the 40

C to 25

hysteresis. The 40

C to 25

C hysteresis is different

depending on the part's previous temperature. This is
because not all of the high temperature stress is relieved
during the 25

C measurement.

The typical performance hysteresis curves are for parts
mounted in a socket and represent the performance of the

APPLICATIO S I FOR ATIO

LT1461

parts alone. What is more interesting are parts IR soldered
onto a PC board. If the PC board is then temperature cycled
several times from 40

C to 85

C, the resulting hysteresis

curve is shown in Figure 8. This graph shows the influence
of the PC board stress on the reference.

When the LT1461 is soldered onto a PC board, the output
shifts due to thermal hysteresis. Figure 9 shows the effect
of soldering 40 pieces onto a PC board using standard IR
reflow techniques. The average output voltage shift is
110ppm. Remeasurement of these parts after 12 days
shows the outputs typically shift back 45ppm toward their
initial value. This second shift is due to the relaxation of
stress incurred during soldering.

Figure 9. Typical Distribution of Output Voltage Shift After Soldering Onto PC Board

OUTPUT VOLTAGE SHIFT (ppm)

300

NUMBER OF UNITS

200

100

1461 F09

200

300

HYSTERESIS (ppm)

200

NUMBER OF UNITS

160

120

160

200

C TO 25

1461 F08

WORST-CASE HYSTERESIS
ON 35 UNITS

Figure 8. 40

C to 85

C Hysteresis of 35 Parts Soldered Onto a PC Board

APPLICATIO S I FOR ATIO

The LT1461 is capable of dissipating high power, i.e., for
the LT1461-2.5, 17.5V · 50mA = 875mW. The SO-8
package has a thermal resistance of 190

C/W and this

dissipation causes a 166

C internal rise producing a

junction temperature of T

= 25

C + 166

C = 191

C. What

will actually occur is the thermal shutdown will limit the
junction temperature to around 150

C. This high tempera-

ture excursion will cause the output to shift due to thermal
hysteresis. Under these conditions, a typical output shift
is 135ppm, although this number can be higher. This
high dissipation can cause the 25

C output accuracy to

exceed its specified limit. For best accuracy and preci-
sion, the LT1461 junction temperature should not ex-
ceed 125

LT1461

Dimensions in inches (millimeters) unless otherwise noted.

S8 Package

8-Lead Plastic Small Outline (Narrow 0.150)

(LTC DWG # 05-08-1610)

0.016 0.050

(0.406 1.270)

0.010 0.020

(0.254 0.508)

TYP

0.008 0.010

(0.203 0.254)

SO8 1298

0.053 0.069

(1.346 1.752)

0.014 0.019

(0.355 0.483)

TYP

0.004 0.010

(0.101 0.254)

0.050

(1.270)

BSC

0.150 0.157**

(3.810 3.988)

0.189 0.197*

(4.801 5.004)

0.228 0.244

(5.791 6.197)

DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE

DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE

PACKAGE DESCRIPTIO

Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no represen-
tation that the interconnection of its circuits as described herein will not infringe on existing patent rights.

LT1461

1461f LT/LCG 0800 4K · PRINTED IN USA

LINEAR TECHNOLOGY CORPORATION 1999

Linear Technology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7417

(408) 432-1900

FAX: (408) 434-0507

www.linear-tech.com

PART NUMBER

DESCRIPTION

COMMENTS

LT1019

Precision Reference

Bandgap, 0.05%, 5ppm/

LT1027

Precision 5V Reference

Lowest TC, High Accuracy, Low Noise, Zener Based

LT1236

Precision Reference

5V and 10V Zener-Based 5ppm/

C, SO-8 Package

LTC

1798

Micropower Low Dropout Reference

0.15% Max, 6.5

A Supply Current

LT1460

Micropower Precision Series Reference

Bandgap, 130

A Supply Current 10ppm/

C, Available in SOT-23

LT1634

Micropower Precision Shunt Voltage Reference

Bandgap 0.05%, 10ppm/

C, 10

A Supply Current

LT1790

Precision SOT-23 Series Reference

Bandgap 0.05% Max, 10ppm/

C Max

RELATED PARTS

SCK
SD0

NOISE PERFORMANCE*

= 0V, V

NOISE

= 1.1ppm

RMS

= 2.25

RMS

= 16

P-P

= V

REF

/2, V

NOISE

= 1.6ppm

RMS

= 4

RMS

= 24

P-P

= V

REF

, V

NOISE

= 2.5ppm

RMS

= 6.25

RMS

= 36

P-P

*FOR 24-BIT PERFORMANCE USE LT1236 REFERENCE

REF

200

1461 TA03

0.1

LTC2400

GND

LT1461-2.5

OUT

INPUT

GND

SPI
INTERFACE

Low Power 16-Bit A/D

TYPICAL APPLICATIO

Ð­Ð»ÐµÐºÑ‚Ñ€Ð¾Ð½Ð½Ñ‹Ð¹ ÐºÐ¾Ð¼Ð¿Ð¾Ð½ÐµÐ½Ñ‚: LT1461BIS8-4

ÐÐ»ÐµÐºÑ‚Ñ€Ð¾Ð½Ð½Ñ‹Ð¹ ÐºÐ¾Ð¼Ð¿Ð¾Ð½ÐµÐ½Ñ‚: LT1461BIS8-4