QPL product with established reliability (ER): meets
requirements of MIL-PRF-55182/9
•
Load life stability: ± 0.005 % for 2000 h, 0.3 W at + 125 °C
•
Temperature coefficient of resistance (TCR): ± 2 ppm/°C max.
(- 55 °C to + 175 °C)
•
Resistance tolerance: to ± 0.005 %
•
Thermal EMF: < 0.1 µV/°C
•
Qualified resistance range: 4.99
Ω
to 121 kΩ (RNC90Y)
30.1
Ω
to 121 kΩ (RNC90Z)
•
Specially conditioned non-QPL resistors available
See data sheet “Improved Performance Tested”
•
Fast thermal stabilization
•
Rise time: 1 ns without ringing
•
Special coatings that provide a cushioning layer which isolates
the resistive element from external stresses and moisture
•
Electrostatic discharge (ESD) above 25 000 V
•
Non inductive, non capacitive design
•
Current noise < - 42 dB
•
Prototype sample available from 72 h
INTRODUCTION
Vishay Military Established Reliability resistors are available
in resistance values from 4.99
Ω
through 121 kΩ and for
tolerances from ± 0.005 % to ± 1.0 %. The same resistors are
also available as a non-qualified product for customers
desiring higher or lower resistance values and the same or
better performance capabilities. (See table 2) Both the
qualified and the non-qualified version are manufactured on
the same production line facilities and are subjected to the
same process, lot control, conditioning, and GRP A (100 %)
screening. Qualified versions receive additional MIL Group B
and C testing.
TABLE 1 - SPECIFICATIONS COMPARISON
SPECIFICATION
RNC90Y (QUALIFIED)
RNC90Z (QUALIFIED)
S555 (NON-QUALIFIED)
Z555 (NON-QUALIFIED)
MIL-PRF-55182/9
MIL-PRF-55182/9
VISHAY PERFORMANCE
VISHAY PERFORMANCE
CHARACTERISTIC Y LIMITS CHARACTERISTIC Z LIMITS
LIMITS
LIMITS
± 5 ppm/°C
± 2 ppm/°C
± 5 ppm/°C
± 3 ppm/°C ± 2.5 ppm/°C ± 2 ppm/°C
(- 55 °C to + 125 °C)
(- 55 °C to + 175 °C)
(- 55 °C to + 125 °C)
± 10 ppm/°C
(- 55 °C to + 125 °C)
(+ 125 °C to + 175 °C)
4.99
Ω
to
> 25
Ω
to
4.99
Ω
to 121 k
Ω
30.1
Ω
to 121 k
Ω
1
Ω
to 150 k
Ω
> 80
Ω
25
Ω
80
Ω
Level R
Level R
Not specified
Not specified
Temperature
Coefficient of
Resistance
Resistance Range
Failure Rate
Load-Life Stability
0.3 W at + 125 °C
at 2000 h
at 10 000 h
Current Noise
High-Frequency
Operation
Rise Time
Inductance
3)
(L)
Capacitance (C)
Voltage Coefficient
Working Voltage
4)
Thermal EMF
5)
± 0.05 % maximum
ΔR
± 0.5 % maximum
ΔR
Not specified
± 0.05 % maximum
ΔR
± 0.5 % maximum
ΔR
Not specified
± 0.015 % maximum
ΔR
2)
± 0.05 % maximum
ΔR
2)
- 40 dB minimum
1.0 ns at 1 k
Ω
0.1 µH maximum
0.08 µH typical
1.0 pF maximum
0.5 pF typical
0.0001 %/V
300 V maximum
0.1 µV/°C maximum
1 µV/W maximum
± 0.015 % maximum
ΔR
2)
± 0.05 % maximum
ΔR
2)
- 40 dB minimum
1.0 ns at 1 k
Ω
0.1 µH maximum
0.08 µH typical
1.0 pF maximum
0.5 pF typical
0.0001 %/V
300 V maximum
0.1 µV/°C maximum
1 µV/W maximum
Not specified
Not specified
Not specified
0.0005 %/V
300 V maximum
Not specified
Not specified
Not specified
Not specified
0.0005 %/V
300 V maximum
Not specified
Notes
1. Qualification and failure rate verification test data is maintained by Vishay Foil and is available upon request. Lot traceability and identification
data is maintained by Vishay Foil for 7 years.
2. Load life
ΔR
Maximum can be reduced by 80 % through Enhanced Reliability Testing (ERT). Consult Vishay Applications Engineering for
details.
3. Inductance (L) due mainly to the leads.
4. Not to exceed power rating of resistor.
5. µV/°C relates to EMF due to lead temperature differences and µV/W due to power applied to the resistor.
6. 0.200" (5.08 mm) lead spacing available - specify RNC90T for RNC90Y, and RNC90S for RNC90Z.
Document Number: 63007
Revision: 23-Mar-10
For any questions, contact:
foil@vishaypg.com
www.foilresistors.com
1
Military and Space Established Reliability
Vishay Foil Resistors
FIGURE 1 - COMPARISON OF RNC90Y TO RNC90Z TEMPERATURE COEFFICIENT OF RESISTANCE
+ 1000
RNC90Y
+ 1000
+ 1000
RNC90Z
+ 1000
+ 500
+ 400
ΔR/R
(ppm)
ΔR/R
(ppm)
+ 160
0
- 160
+ 300
+ 200
0
- 200
- 300
- 400
- 500
- 1000
- 55
25
Temperature (°C)
125
- 1000
175
- 1000
- 55
25
Temperature (°C)
125
- 1000
175
Specification ± 5 ppm/°C ± 10 ppm/°C
Specification ± 2 ppm/°C
FIGURE 2 - TRIMMING TO VALUES
(Conceptual Illustration)
FIGURE 3 - POWER DERATING CURVE
+ 70 °C
Interloop Capacitance
Reduction in Series
Current Path
Before Trimming
Current Path
After Trimming
Trimming Process
Removes this Material
from Shorting Strip Area
Changing Current Path
and Increasing
Resistance
Percent of Rated Power
200
150
100
50
0
- 50
Rated Power
Mutual Inductance
Reduction due
to Change in
Current Direction
- 25
0
+ 25 + 50 + 75 + 100 + 125 + 150 + 175
Ambient Temperature °C
Note:
Foil shown in
black,
etched spaces in
white
FIGURE 4 - IMPRINTING AND DIMENSIONS
RNC90Y and RNC90Z Military Approved Resistors
Front View
L
VISHAY
18612
XXXXX J
Side View
Manufacturers
Identification
Number
W
Resistance
Tolerance
Code
Lead Material
#22 AWG
(0.025 Dia.)
Solder Coated
Copper
Rear View
Model Number
XXXXX
100R01
B
R
H
Mfr. Code
07
11
B
Factory Year Week
Resistance
Value Code
Failure Rate Code
(Not Present If
Non-Qualified)
LL
ST
Jan Designator
(Non Present If
Non-Qualified)
SW
LS
1)
Note
1. 0.200" (5.08 mm) lead spacing available - specify RNC90T for RNC90Y, and RNC90S for RNC90Z
www.foilresistors.com
2
For any questions, contact:
foil@vishaypg.com
Document Number: 63007
Revision: 23-Mar-10
Military and Space Established Reliability
Vishay Foil Resistors
TABLE 2 - MODEL SELECTION
STANDARD RESISTANCE
TOLERANCE
TIGHTEST
LOOSEST
%
%
30.1 to 121K
± 0.005
± 1.0
16.2 to 30.0
± 0.05
± 1.0
RNC90Y
4.99 to 16.0
± 0.1
± 1.0
RNC90Z
30.1 to 121K
± 0.005
± 1.0
30.1 to 121K
± 0.005
± 1.0
20 to < 30.1
± 0.01
± 1.0
5 to < 20
± 0.05
± 1.0
S555
(NON QPL)
2 to < 5
± 0.1
± 1.0
1 to < 2
± 0.5
± 1.0
> 121K to 150K
± 0.005
± 1.0
30.1 to 121K
± 0.005
± 1.0
Z555
20 to < 30.1
± 0.01
± 1.0
(NON QPL)
4.99 to < 20R
± 0.05
± 1.0
Note
MODEL
NUMBER
RESISTANCE
RANGE
(Ω)
FAILURE
RATE
M, P, R
(See
Table 3)
AVERAGE
WEIGHT
(g)
at + 70 °C at + 125 ° C
0.6 W
0.6 W
0.3 W
0.3 W
0.6
0.6
W: 0.105 ± 0.010
L: 0.300 ± 0.010
H: 0.326 ± 0.010
ST: 0.015 ± 0.005
SW: 0.040 ± 0.005
LL: 1.000 ± 0.125
LS: 0.150 ± 0.005
2.67 ± 0.25
7.62 ± 0.25
8.28 ± 0.25
0.38 ± 0.13
1.02 ± 0.13
25.4 ± 3.18
3.81 ± 0.13
AMBIENT
POWER RATING
DIMENSIONS
INCHES
mm
-
0.6 W
0.3 W
0.6
-
-
0.4 W
0.6 W
0.2 W
0.3 W
0.6
0.6
• S555 and Z555 units are manufactured on the same production line facilities and are subjected to all the same process and lot control
requirements imposed on RNC90Y (Z) version, as well as all of the special screening, environmental conditioning and documentation
stipulations outlined in MIL-PRF 55182/9
TABLE 3 - GLOBAL PART NUMBER INFORMATION
NEW GLOBAL PART NUMBER: Y1189100R500AR0L (preferred part number format)
DENOTES PRECISION
Y
VALUE
R
=
Ω
K
= kΩ
LIFE FAILURE RATE (LFR)
R
= ± 0.01 %
P
= ± 0.1 %
M
= ± 1.0 %
AER*
0
= standard
1 - 999
= custom
Y
1
1
8
9
1
0
0
R
5
0
0
A
R
0
L
PRODUCT CODE
1189
= RNC90Z
0089
= RNC90Y
1508
= RNC90T
1506
= RNC90S
0088
= S555
1288
= Z555
RESISTANCE TOLERANCE
V
= ± 0.005 %
T
= ± 0.01 %
A
= ± 0.05 %
B
= ± 0.1 %
D
= ± 0.5 %
F
= ± 1.0 %
PACKAGING
L
= bulk pack
R
= tape and reel
FOR EXAMPLE: ABOVE GLOBAL ORDER Y1189 100R500 A R 0 L:
TYPE: RNC90Z
VALUE: 100.5
Ω
ABSOLUTE TOLERANCE: ± 0.05 %
LIFE FAILURE RATE (LFR): ± 0.01 %
AER: standard
PACKAGING: bulk pack
HISTORICAL PART NUMBER: RNC90Z 100R50 A R B (will continue to be used)
RNC90Z
MODEL
RNC90Z
RNC90S
RNC90Y
RNC90T
S555
Z555
Note
* For non-standard requests, please contact application engineering.
Document Number: 63007
Revision: 23-Mar-10
For any questions, contact:
foil@vishaypg.com
www.foilresistors.com
3
100R50
OHMIC VALUE
100.5
Ω
A
RESISTANCE
TOLERANCE
V
= ± 0.005 %
T
= ± 0.01 %
A
= ± 0.05 %
B
= ± 0.1 %
D
= ± 0.5 %
F
= ± 1.0 %
R
LIFE FAILURE
RATE (LFR)
R
= ± 0.01 %
P
= ± 0.1 %
M
= ± 1.0 %
B
PACKAGING
B
= bulk pack
Military and Space Established Reliability
Vishay Foil Resistors
CAGE #18612
“Commercial and Government Entity”
Formerly “FSCM”
The response of military and non military grade resistors to environmental stresses can be made better by “Improved
Performance Testing” (IPT). The IPT part will see burn-in and cycling that removes the “knee” from the normal drift of non IPT
parts. (See Table 4 for the improvement to expect in military parts when calling for Vishay recommended screening). Users
should be aware that IPT testing renders the part non QPL and so a 3XXXXX part number will be assigned by Vishay. Consult
Applications Engineering for details and ordering advice.
TABLE 4 - IMPROVED PERFORMANCE TESTING (NON-QPL APPROVED) VS. QPL
TEST
GROUP
I
TEST
Power Conditioning
Thermal Shock and
Overload Combined
Resistance Temperature
Characteristic
Low Temperature Storage
Low Temperature Operation
Terminal Strength
DWV
Insulation Resistance
Resistance to Soldering Heat
Moisture Resistance
Shock
Vibration
Load Life at + 125 °C; 2000 h
Load Life at + 125 °C; 10 000 h
+ 85 °C Power Rating
+ 70 °C Power Rating
+ 25 °C Power Rating
Storage Life
High Temperature Exposure
Max. Allowance Reactance
Current Noise
Voltage Coefficient
Thermal EMF
not done
4.8.2
4.8.3
4.8.9
RNC90Y
MIL-PRF-55182/9
METHOD PARAGRAPH
LIMITS
-
-
± 0.05 %
± 5 ppm/°C
VISHAY
IMPROVED PERFORMANCE
TESTING
(IPT) LIMITS
± 0.0025 %
± 0.0025 %
± 0.0025 %
< ± 2 ppm/°C
(- 55 °C to + 125 °C)
(Can be sorted for tighter tracking)
± 0.0025 %
± 0.0025 %
± 0.001 %
± 0.001 %
> 10
4
MΩ
± 0.001 %
± 0.015 %
± 0.0025 %
± 0.0025 %
± 0.005 % (50 ppm)
± 0.015 % (150 ppm)
± 0.005 % (50 ppm)
± 0.005 % (50 ppm)
± 0.005 % (50 ppm)
± 0.0025 %
± 0.005 %
<1%
< - 42 dB
< 0.00001 %/V
(< 0.1 ppm/V)
0.1 µV/°C
II
III
IV
V
V (a)
V (b)
VI
VII
VIII
4.8.23
4.8.10
4.8.11
4.8.12
4.8.13
4.8.14
4.8.15
4.8.16
4.8.17
4.8.18
4.8.18
-
4.8.18
-
-
4.8.19
-
-
4.8.20
-
-
± 0.05 %
± 0.05 %
± 0.02 %
± 0.02 %
10
4
MΩ
± 0.02 %
± 0.05 %
± 0.01 %
± 0.02 %
± 0.05 %
± 0.5 %
-
± 0.05 %
-
-
± 0.5 %
-
-
0.0005 %/V
(5 ppm/V)
-
FIGURE 5 - IPT IMPRINTING AND DIMENSIONS
in inches (millimeters)
Front View
0.300 ± 0.010
(7.62 ± 0.25)
VISHAY
XXXX
3XXXXX
Date Code
01
10
Year Week
0.015 ± 0.005
(0.381 ± 0.13)
Model Number
0.150 ± 0.005
(3.81 ± 0.13)
Lead Material
#22 AWG
(0.025 Dia.)
Solder Coated
Copper
0.040 ± 0.005
(1.02 ± 0.13)
Side View
0.105 ± 0.010
(2.67 ± 0.25)
Rear View
Optional
Customer P/N
6 Digits Maximum
Resistance
Value Code
Tolerance
1.00 ± 0.125
(25.4 ± 3.18)
0.326 ± 0.010
(8.28 ± 0.25)
XXXXXX
100R01
0.01 %
www.foilresistors.com
4
For any questions, contact:
foil@vishaypg.com
Document Number: 63007
Revision: 23-Mar-10
Legal Disclaimer Notice
Vishay Precision Group
Disclaimer
All 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, “Vishay Precision Group”), disclaim any and all liability for any errors, inaccuracies or incompleteness
contained herein or in any other disclosure relating to any product.
Vishay Precision Group disclaims any and all liability arising out of the use or application of any product described
herein or of any information provided herein to the maximum extent permitted by law. The product specifications do
not expand or otherwise modify Vishay Precision Group’s terms and conditions of purchase, including but not limited
to the warranty expressed therein, which apply to these products.
No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this
document or by any conduct of Vishay Precision Group.
The products shown herein are not designed for use in medical, life-saving, or life-sustaining applications unless
otherwise expressly indicated. Customers using or selling Vishay Precision Group products not expressly indicated
for use in such applications do so entirely at their own risk and agree to fully indemnify Vishay Precision Group for
any damages arising or resulting from such use or sale. Please contact authorized Vishay Precision Group
personnel to obtain written terms and conditions regarding products designed for such applications.
Product names and markings noted herein may be trademarks of their respective owners.
.mif and .hex files are both data file formats supported by Quartus and are often used as memory initialization files. However, ModelSim does not support .mif files, but only supports .hex files. This...
The output voltage of my tilt sensor is very strange. It should be 2.5V when it is flat, but now it is around 3.9V for a while and then drops to 1.4V. Sometimes it can also shake around 2.5V. I think ...
T1 interrupt, execute the interrupt program, turn off the general interrupt in the interrupt program, and turn on the general interrupt after executing the interrupt program.
I would like to ask, when...
[i=s] This post was last edited by snoweaglemcu on 2016-4-30 23:06[/i] [font=宋体][size=12pt]Before writing this article, I went to check my personal profile. The registration time was 2009[/size][font=...
On August 23rd, Geely's subsidiary, Jiyao Tongxing, announced it has the industry's largest advanced production capacity for tandao
batteries
, with eight production bases across China. Jiy...[Details]
When you are happily watching NBA or football, your wife asks you to turn off the lights in the bedroom. Would you be depressed? Of course, unless you are not afraid of your wife.
Now you are ...[Details]
Ever since the Tesla fire incident, electric cars, already known for their poor reputation, have been subjected to even more scathing criticism. Despite this, many people are still willing to buy t...[Details]
We are entering a new era where people are increasingly affordably equipped with more electronic gadgets. Electronics have become essential to our lives. For example, the average consumer now owns ...[Details]
Electric vehicles are powered by electricity, and charging is a device that supplements the vehicle's energy source. It is common to need to recharge the vehicle when driving. But can you charge th...[Details]
A tubular motor is an electric motor that is typically used to control the movement of machines and equipment. Tubular motors are generally divided into two categories: linear tubular motors and ro...[Details]
A scale, a large, ground-mounted scale, is typically used to measure the tonnage of truck cargo. It's the primary weighing device used in factories, mines, and businesses for bulk cargo measurement...[Details]
The fracture mechanism is stress concentration, which typically occurs at the capacitor lead pins or pad connection points, as shown in the figure. Under vibration, the capacitor lead pins and pad ...[Details]
Batteries are a core component of new energy vehicles, accounting for over 40% of the total cost. This is also the area where automakers are most willing to tamper with costs. Since 2021, domestic ...[Details]
introduction
The OMAP-L138 dual-core processor is a new generation of low-power single-chip systems (SoCs) from TI. It is widely used in communications, industrial, medical diagnostic, and aud...[Details]
In microwave amplification circuits, the power chip is the core of the entire circuit. A large number of semiconductor devices in the chip will generate a lot of heat when working. If the heat diss...[Details]
For the average person, an electricity meter is a monthly bill. For beginners, it's a collection of components and parts. For experienced meter engineers, however, it's a complex and complex proces...[Details]
Recently, I received a request to use OK1028A-C to output PWM square wave. However, I found that there was no relevant instructions on the OK1028 platform, so I started writing this article.
A...[Details]
On August 19, Huawei's Executive Director and Chairman of the Device BG, Richard Yu, shared a Weibo post about a conversation he had with a Zunjie S800 owner. The owner had driven over 5,000 kilome...[Details]
In July 2025, stimulated by the "old for new" policy, China's new energy vehicle penetration rate reached a historic 50% mark. While industry experts like Cui Dongshu celebrated the market's perfor...[Details]
FPGA/CPLD
京公网安备 11010802033920号
EEWORLD
