VSH144
Bulk Metal® Foil Technology Low Profile Conformally Coated
High Precision Voltage Divider Resistor with TCR Tracking
to 0.5 ppm/°C and Tolerance Match to 0.01 % (100 ppm)
FEATURES
APPLICATIONS
R2
Instrumentation amplifiers
Bridge networks
R1
Differential amplifiers
Vin
-
Vout
+
Military
VSH144
Space
Medical
Automatic test equipment
Down-hole (high temperature)
TABLE 1A - MODEL VSH144
SPECIFICATIONS
RESISTANCE
VALUES
ABSOLUTE
TOLERANCE
500 to 20 k
± 0.01 %
100 to < 500
± 0.02 %
ABSOLUTE TCR
(- 55 °C to + 125 °C,
+ 25 °C ref.)
TYPICAL AND MAX.
SPREAD
± 2 ppm/°C ± 3 ppm/°C
TABLE 1B - MODEL VSH144
SPECIFICATIONS
RESISTANCE
RATIO
1:1
> 1:1 to 4:1
> 4:1 to 10:1
>10:1
TOLERANCE
MATCH
Temperature coefficient of resistance (TCR)
absolute: ± 2 ppm/°C typical
(- 55 °C to + 125 °C, + 25 °C ref.)
tracking: 0.5 ppm/°C
Tolerance: absolute and matching to 0.01 %
(100 ppm)
Power rating: 0.2 W at 70 °C, for the entire resistive
element R1 and R2, divided proportionally between the two
values
Load life ratio stability: < 0.01 % (100 ppm) 0.2 W at 70 °C
for 2000 h
Maximum working voltage: 200 V
Resistance range: 100R to 20K per resistive element
Vishay Foil resistors are not restricted to standard
values/ratios; specific “as requested” values/ratios can be
supplied at no extra cost or delivery (e.g. 1K2345 vs. 1K)
Electrostatic discharge (ESD) up to 25 000 V
Non-inductive, non-capacitive design
Rise time: 1 ns effectively no ringing
Thermal stabilization time < 1 s (nominal value achieved
within 10 ppm of steady state value)
Current noise: 0.010 µVRMS/V of applied voltage (< - 40 dB)
Thermal EMF: 0.05 µV/°C typical
Voltage coefficient: < 0.1 ppm/V
Non inductive: < 0.08 µH
Non hot spot design
Terminal finish: lead (Pb)-free or tin/lead alloy
Compliant to RoHS directive 2002/95/EC
Prototype quantities available in just 5 working days
or sooner. For more information, please contact
foil@vpgsensors.com
For better performances see VSH144Z (Z-Foil) datasheet
TCR TRACKING MAX.
0.01 %
0.02 %
FIGURE 1 - TRIMMING TO VALUES
0.5 ppm/°C
1.0 ppm/°C
1.5 ppm/°C
Interloop
Capacitance
Reduction
in Series
2.0 ppm/°C
Note
• See table 2 for additional established ratios
Mutual
Inductance
Reduction due
to Opposing
Current in
Adjacent Lines
Current Path
Before Trimming
Current Path
After Trimming
Trimming Process
Removes this Material
from Shorting Strip Area
Changing Current Path
and Increasing Resistance
Note: Foil shown in black, etched spaces in white
* Pb containing terminations are not RoHS compliant, exemptions may apply
Document Number: 63172
Revision: 5-Mar-15
For any questions, contact
foil@vpgsensors.com
www.vishayfoilresistors.com
1
VSH144
INTRODUCTION
What is precision?
For resistors, precision is the term used to describe a
combination of attributes starting with accuracy but including
stability with time, temperature and load as well.
There are many causes for a resistor to depart from the
fundamental precept of Ohm's Law and it is in the realm of
precision that this is most demanding and most challenging.
There are ideal solutions to these issues in the form of
Foil-based resistors.
Generally, “precision” resistors are those devices that are
understood to fall within a range of accuracy better than 1 %
and hold their initial value throughout the assembly and life
of the equipment to better than 0.5 %. Resistors that maintain
these characteristics with “orders-of-magnitude better
performance”, such as the foil resistor technology, can be
reasonably termed “ultra-precision”. Of course there are
other considerations such as frequency response that may
govern the selection but starting with these parameters we
can pretty much rule out every technology except Foil, wire,
and deposited metal film in that order of precision.
What is matching?
This term defines to what extent one or more resistors are
referenced to one another as opposed to each resistor
having its own independent specifications, unrelated to other
resistors in the circuit. Usually, one resistor is defined as the
reference resistor and all others are defined relative to the
reference resistor. For example, the reference resistor may
have an absolute (or independent) tolerance of ± 0.1 %, and
other resistors can be specified as “matched” to within
0.01 % of the reference resistor. For a tighter grouping of
three or more resistors, all resistors may be specified as
having a defined match among all the resistors, thereby
keeping the entire grouping of resistors within a tighter
grouping than if they were all refered to just one reference
resistor. The initial “match” refers to the initial supplied
tolerance of each resistor and its relationship to other defined
resistors in the group. However, the initial match is degraded
in application as each resistor in the set responds differently
to board-assembly stresses, temperature excursions,
self-heating from power dissipation, thermal shock, load-life,
etc. So the term “match” may be extended to indicate the limit
of change in the set of resistors as they experience any
number of defined exposures. That is, for example, the set
may be defined as being matched to within 0.01 % initially,
and within 0.05 % after exposure to thermal shock, load-life,
etc. These exposure cause permanent changes in
resistance. Temporary changes are classified in other terms
such as TCR (Temperature Coefficient of Resistance) and
TCR tracking, PCR (Power Coefficient of Resistance), etc
but can be as important or more important than matching in
that they change the relationships among the resistors
immediately while in actual operation.
The differential self heating effect on “matching” is often
overlooked. Even though the initial match is tight and good
TCR “tracking” is exhibited, the same current flow through
the resistors of different values will produce power
dissipation differences (I2R self heating) and induce ratio
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2
changes proportional to the absolute TCR.
Therefore the lower the absolute TCR, the less the match will
be affected over temperature changes, including differential
power-induced temperatures.
Additionally, when resistors within a set have different
absolute TCR’s (individual TCR’s - not relative or tracking
TCR), the ratios change even more due to the differential
self-heating as well as to differential ambient temperatures:
ratio = (TCR track x temp 1) + (absolute TCR x temp 2)
where temp 1 is the change of ambient temperature and
temp 2 is the temperature difference between two resistors
due to differential self-heating.
Differential self-heating can occur, for example, when the
same current flows through resistors of different resistance
values. The construction of the VSH144 keeps both resistors
at the same temperature regardless of resistance value or
differential power.
Since for precision applications the TCR tracking is often
selected to be less than the absolute TCR (e.g.: 15 ppm/°C
absolute selected for 5 ppm/°C track) the absolute TCR is
much more important any time the resistors are at different
temperatures, regardless of the cause. The error in the
match becomes critical when long term ratio stability is
required under small variations of ambient temperature and
self heating, even if selected for excellent initial matching
and tracking.
Bulk Metal Foil resistor dividers have the lowest absolute
TCR and TCR tracking of any technology and therefore have
the best operational and end of life matching for applications
where stability is important.
Why ratio stability is important?
Resistors in divider or network form, are called upon to track
at more than ambient temperature. Throughout the service
life of the equipment, the resistors around the operational
amplifier, for example, are required to hold a defined ratio
even though the dissipation in the feedback resistor is
different from that in the input resistor, causing one to be at
the higher temperature than the other. This is called tracking
under power. If environment stresses cause one resistor to
drift (permanent R’s) more than its counterpart, the ratio
changes over a period of time and can be significant. This is
called tracking with time. Foil resistors used in dividers form
share the same substrate for thermal equality and possess a
TCR track of less than 0.1 ppm/°C, they offer the best
combination of temperature-load-time tracking.
The factors that contribute to this are:
1. Fundamentally low absolute TCR
2. Extremely low TCR tracking
2. Very small drift with load over time
3. Common behavior - all parts move the same direction with
temperature, load and time
Our application engineering department is available to
advise and make recommendations. For non-standard
technical requirements and special applications. Please
contact foil@vpgsensors.com.
For any questions, contact
foil@vpgsensors.com
Document Number: 63172
Revision: 5-Mar-15
VSH144
FIGURE 2 - STANDARD PRINTING AND DIMENSIONS in inches (millimeters)
Model VSH144 and Schematic (2)
0.263 ±0.02
(6.7 ±0.5)
VSH(T)
(D.C.)(-)
0.098 +0.008/–0.01
(2.5 +0.2/–0.3)
(3)
(4)
(R1)
(R2)
R1
0.283 ±0.04
(7.2 ±1.0)
R2
1.0 (25.4)
Min.
1
0.100
(2.54)
0.200
(5.08)
(2)
(3)
(4)
Lead wires: #22 AWG solder coated copper, 0.75" minimum length
Each divider pair consists of two resistors on one single chip
For lead (Pb)-free: print “T” after VSH and “-” after (D.C.)
If the resistance value contains more than 5 characters,
the VCODE will be printed instead (see Table 2).
FIGURE 3 - POWER DERATING CURVE
Percent of Rated Power at + 70 °C
- 55 °C
3
Dimensional Tolerance: ±0.010" (0.25)
(1)
100 %
2
FIGURE 4 - TYPICAL RESISTANCE/
TEMPERATURE CURVE
+ 70 °C
Rated Power
+ 150
+ 100
75 %
Recommended
operation for
< 150 ppm ΔR
after 2000 h
load life
50 %
25 %
ΔR
+ 50
R
(ppm)
0
- 50
- 100
- 200
- 55 - 50
0
- 75
2 ppm/°C
- 150
- 50
- 25
0
+ 25 + 50 + 75 + 100 + 125 + 150 + 175
- 25
0
+ 25
+ 50
+ 75
+ 100
+ 125
Ambient Temperature (°C)
Ambient Temperature (°C)
Note
• Power is divided proportionally between the 2 values
Document Number: 63172
Revision: 5-Mar-15
For any questions, contact
foil@vpgsensors.com
www.vishayfoilresistors.com
3
VSH144
TABLE 2 - EXAMPLES OF VCODES FOR POPULAR VALUES (other values available on request)
VSH144 RATIOS
VCODES
R1
R2
VCODES
R1
R2
V0009
20K
20K
V0058
2K
20K
V0010
20K
10K
V0030
2K
18K
V0100
20K
2K
V0029
2K
4K
V0055
19K4
9K7
V0059
2K
2K
V0223
17K5
20K
V0103
2K
3K
V0097
15K
15K
V0154
1K5
3K
V0001
10K
10K
V0032
1K
16K
V0042
10K
8K323
V0121
1K
2K
V0006
10K
2K
V0004
1K
1K
V0166
10K
15K
V0379
1K
7K
V0226
9K
10K
V0374
800R
800R
V0003
9K
1K
V0022
511R
16K2
V0013
8K
16K
V0091
500R
500R
V0107
6K
20K
V0162
500R
15K
V0014
6K
7K
V0378
500R
4K5
V0160
6K
6K
V0061
300R
300R
V0159
5K5
7K7
V0088
100R
100R
V0005
5K
10K
V0380
100R
15K
V0002
5K
5K
V0375
100R
12K3
V0373
4K
12K
V0381
100R
50R
V0026
3K
19K2
V0377
50R
28K
V0156
3K
6K
V0376
35R
20K
V0158
2K7
10K
-
-
-
Note
• A combination of these values is also available in reverse order.
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For any questions, contact
foil@vpgsensors.com
Document Number: 63172
Revision: 5-Mar-15
VSH144
TABLE 3 - GLOBAL PART NUMBER INFORMATION (1)
NEW GLOBAL PART NUMBER: Y1767V0058QT9L (preferred part number format)
DENOTES PRECISION
VCODE
TOLERANCE MATCH
PACKAGING
Y
RESISTANCE
VALUE CODE
V = 0.005 %
T = 0.01 %
Q = 0.02 %
A = 0.05 %
B = 0.1 %
D = 0.5 %
F = 1.0 %
L = bulk pack
Y
1
7
6
7
V
0
0
5
8
Q
T
9
L
PRODUCT CODE
RESISTANCE TOLERANCE
CHARACTERISTICS
1767 = VSH144
V = ± 0.005 %
T = ± 0.01 %
Q = ± 0.02 %
A = ± 0.05 %
B = ± 0.1 %
D = ± 0.5 %
F = ± 1.0 %
0 = standard
9 = lead (Pb)-free
1 to 999 = custom
FOR EXAMPLE: ABOVE GLOBAL ORDER Y1767 V0058 Q T 9 L:
TYPE: VSH144
VALUES: 2K/20K
ABSOLUTE TOLERANCE: ± 0.02 %
TOLERANCE MATCH: 0.01 %
TERMINATION: lead (Pb)-free
PACKAGING: bulk pack
HISTORICAL PART NUMBER: VSH144T 2K/20K TCR2 Q T B (will continue to be used)
VSH144
T
2K/20K
TCR2
Q
T
B
MODEL
TERMINATION
OHMIC VALUE
TCR
CHARACTERISTIC
ABSOLUTE
TOLERANCE
TOLERANCE
MATCH
PACKAGING
VSH144
T = lead (Pb)-free
None = tin/lead alloy
R1 = 2 k
R2 = 20 k
V
T
Q
A
B
D
F
= ± 0.005 %
= ± 0.01 %
= ± 0.02 %
= ± 0.05 %
= ± 0.1 %
= ± 0.5 %
= ± 1.0 %
V = 0.005 %
T = 0.01 %
Q = 0.02 %
A = 0.05 %
B = 0.1 %
D = 0.5 %
F = 1.0 %
B = bulk pack
Note
(1) For non-standard requests, please contact application engineering
Document Number: 63172
Revision: 5-Mar-15
For any questions, contact
foil@vpgsensors.com
www.vishayfoilresistors.com
5
Legal Disclaimer Notice
Vishay Precision Group, Inc.
Disclaimer
ALL PRODUCTS, PRODUCT SPECIFICATIONS AND DATA ARE SUBJECT TO CHANGE WITHOUT NOTICE.
Vishay Precision Group, Inc., its affiliates, agents, and employees, and all persons acting on its or their behalf
(collectively, “VPG”), disclaim any and all liability for any errors, inaccuracies or incompleteness contained herein or in
any other disclosure relating to any product.
The product specifications do not expand or otherwise modify VPG’s terms and conditions of purchase, including but
not limited to, the warranty expressed therein.
VPG makes no warranty, representation or guarantee other than as set forth in the terms and conditions of purchase.
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Information provided in datasheets and/or specifications may vary from actual results in different applications and
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Copyright Vishay Precision Group, Inc., 2014. All rights reserved.
Document No.: 63999
Revision: 15-Jul-2014
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