251R14S2R7BV4T

## MULTI-LAYER HIGH-Q CAPACITORS 

These lines of multilayer capacitors have been developed for High-Q and microwave applications. 

• The S-Series (R07S, R14S, R15S) capacitors give an ultrahigh Q performance, and exhibit NP0 temperature characteristics. 

• The L-Series (R05L) capacitors give mid-high Q performance, and exhibit NP0 temperature characteristics. 

• The E-Series (S42E, S48E, S58E) capacitors give excellent high-Q performance from HF to Microwave frequencies. Typical uses are high voltage, high current applications.  These are offered in various terminations styles. 

• RoHS compliance is standard for all unleaded parts (see termination options box). 

• Automotive versions (AEC-Q200) of R05L, R07S, R14S, R15S, and S42E series are available on request 

## HOW TO ORDER 

**==> picture [518 x 274] intentionally omitted <==**

**----- Start of picture text -----**<br>
252 S48 E 470 K U 4 E -AEC<br>WVDC [2] CASE SIZE CAPACITANCE (pF) TOLERANCE TERMINATION PACKAGING QUALIFICATION<br>250 = 25 V R05 (0201) 1st two digits are < 10pF Nickel Barrier  S = Bulk AEC-Q200<br>500 = 50V201 = 200 V R07 (0402)R14 (0603) significant; third digitdenotes number of    A = ± 0.05 pF  B = ± 0.10 pF V = Ni/Sn  (Green)T = Ni/SnPb W = Waffle Pack0201 - 0603 (optional)qualification  [3]<br>251 = 250 V R15 (0805) zeros, R = decimal.   C = ± 0.25 pF G = Ni/Au  (Green) Y = Paper 5” Reel<br>501 = 500 V102 = 1000 V152 = 1500 V S42 (1111)   S48 (2525)    S58 (3838) 100 = 10 pF101 = 100 pF   D = ± 0.50 pF≥ 10pF Non-MagU = Cu/Sn (Green)C = Cu/SnPb [1] JT = Paper 7” ReelR0805  [1][1]  = Paper 5” Reel -  = Paper 13” Reel- 3838<br>252 = 2500 V362 = 3600 V DIELECTRIC F = ±1 %G = ±2% Leaded (All Non- Z = Embossed  5” ReelE = Embossed  7” Reel<br>722 = 7200 V S = Ultra High Q NPO J = ±5% Mag) [1] U [1]  = Embossed 13” Reel<br>L = High Q NPO K = ± 10%     1 = Microstrip M [1]  = Embossed 5” Reel -<br>E = Ultra High Q NPO,  2 = Axial Ribbon Horizontally Oriented Electrodes<br>Part Number written:  High Voltage, High Power For tolerance availability, see  3 = Axial Wire4 = Radial Ribbon QVertically Oriented Electrodes [1]  = Embossed 5” Reel -<br>252S48E470KU4E G = Fully Oriented,  chart. 5 = Radial Wire G [1]  = Embossed 7” Reel -<br>Ultra High-Q NPO Horizontally Oriented ElectrodesP [1]  = Embossed 7” Reel -<br>Vertically Oriented Electrodes<br>Tape specifications<br>conform to EIA RS481<br>MARKING<br>3 = Cap Code<br>      & Tolerance<br>4 = No Marking<br>6 = EIA Code<br>(Marking option is only available<br>on 0805 and larger case sizes)<br>**----- End of picture text -----**<br>


1 - Not available for all MLCC - Call factory for info. 

2 - WVDC - Working Voltage DC. 

- 3 

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7 

- LOW ESR / HIGH Q CAPACITOR SELECTION CHART 

|EIA Size<br>Cap. Value|EIA Size<br>Cap. Value|EIA Size<br>Cap. Value|||RF Power Applications|RF Power Applications|RF Power Applications|RF Power Applications|RF Power Applications|RF Power Applications|RF Power Applications|RF Power Applications|
|---|---|---|---|---|---|---|---|---|---|---|---|---|
||||0201 (R05)|0402<br>(R07S)|0603<br>(R14S)|0805<br>(R15S)|0805<br>(R15L)|1111<br>(S42E)||2525<br>(S48E)|3838<br>(S58E)||
||||NPO<br>(R05L)||||||||||
|Capacitance<br>pF<br>Code|||||||||||||
|0.1|0R1|A<br>B<br>C<br>D|25/50 V|50/250 V|250 V||||||||
|0.2|0R2||25/50 V|50/250 V|250 V|||500V|1500V||||
|0.3|0R3||25/50 V|50/250 V|250 V|250 V||500V|1500V||||
|0.4|0R4||25/50 V|50/250 V|250 V|250 V||500V|1500V||||
|0.5|0R5||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|||
|0.6|0R6||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|0.7|0R7||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|0.8|0R8||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|0.9|0R9||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|1.0|1R0||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|1.1|1R1||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|1.2|1R2||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|1.3|1R3||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|1.4|1R4||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|1.5|1R5||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|1.6|1R6||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|1.7|1R7||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|1.8|1R8||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|1.9|1R9||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|2.0|2R0||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|2.1|2R1||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|2.2|2R2||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|2.4|2R4||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|2.7|2R7||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|3.0|3R0||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|3.3|3R3||25/50 V|50/250 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|3.6|3R6||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|3.9|3R9||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|4.3|4R3||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|4.7|4R7||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|5.1|5R1|A**<br>B<br>C<br>D|25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|5.6|5R6||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|6.2|6R2||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|6.8|6R8||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|7.5|7R5||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|8.2|8R2||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|9.1|9R1||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|10|100|F<br>G<br>J<br>K|25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|11|110||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|12|120||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|13|130||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|15|150||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|16|160||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|18|180||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|20|200||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|22|220||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|24|240||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|27|270||25/50 V|50/200 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|30|300||25/50 V|50 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|
|33|330||25/50 V|50 V|250 V|250 V||500V|1500V|3600V|3600V|7200V|



Consult factory for Non-Standard values. 

**A tolerance only available for R07S (0402) and R14S(0603) caps 

www.johansontechnology.com 

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- LOW ESR / HIGH Q CAPACITOR SELECTION CHART 

|EIA Size<br>Cap. Value|EIA Size<br>Cap. Value|EIA Size<br>Cap. Value|||RF Power Applications|RF Power Applications|RF Power Applications|RF Power Applications|RF Power Applications|RF Power Applications|RF Power Applications|RF Power Applications|
|---|---|---|---|---|---|---|---|---|---|---|---|---|
||||0201 (R05)|0402<br>(R07S)|0603<br>(R14S)|0805<br>(R15S)|0805<br>(R15L)|1111<br>(S42E)||2525<br>(S48E)|3838<br>(S58E)||
||||NPO<br>(R05L)||||||||||
|Capacitance<br>pF<br>Code||Toler-<br>ance|||||||||||
|36|360|F<br>G<br>J<br>K|25/50 V||250 V|250 V||500V|1500V|3600V|3600V|7200V|
|39|390||25/50 V||250 V|250 V||500V|1500V|3600V|3600V|7200V|
|43|430||25/50 V||250 V|250 V||500V|1500V|3600V|3600V|7200V|
|47|470||25/50 V||250 V|250 V||500V|1500V|3600V|3600V|7200V|
|51|510||25/50 V||250 V|250 V||500V|1500V|3600V|3600V|7200V|
|56|560||25/50 V||250 V|250 V||500V|1500V|3600V|3600V|7200V|
|62|620||25/50 V||250 V|250 V||500V|1500V|3600V|3600V|7200V|
|68|680||25/50 V||250 V|250 V||500V|1500V|3600V|3600V|7200V|
|75|750||25/50 V||250 V|250 V||500V|1500V|3600V|3600V|7200V|
|82|820||25/50 V||250 V|250 V||500V|1500V|3600V|3600V|7200V|
|91|910||25/50 V||250 V|250 V||500V|1500V|3600V|3600V|7200V|
|100|101||25/50 V||250 V|250 V||500V|1500V|3600V|3600V|7200V|
|110|111|||||250 V||300V|1500V|2500V|3600V|7200V|
|120|121|||||250 V||300V|1000V|2500V|3600V|7200V|
|130|131|||||250 V||300V|1000V|2500V|3600V|7200V|
|150|151|||||250 V||300V|1000V|2500V|3600V|7200V|
|160|161|||||250 V||300V|1000V|2500V|3600V|7200V|
|180|181|||||250 V||300V|1000V|2500V|3600V|7200V|
|200|201|||||250 V||300V|1000V|2500V|3600V||
|220|221|||||250 V||200V|1000V|2500V|3600V||
|240|241||||||200/500V|200V|600V|2500V|3600V||
|270|271||||||200/500V|200V|600V|2500V|3600V||
|300|301||||||200/500V|200V|600V|1500V|3600V||
|330|331||||||200/500V|200V|600V|1500V|3600V||
|360|361||||||200/500V|200V|600V|1500V|3600V||
|390|391||||||200/500V|200V|500V|1500V|3600V||
|430|431|F<br>G<br>J<br>K|||||200/500V|200V|500V|1500V|2500V||
|470|471||||||500V|200V|500V|1500V|2500V||
|510|511||||||100V|200V|500V|1000V|2500V||
|560|561||||||100V|200V|500V|1000V|2500V||
|620|621||||||100V|200V|500V|1000V|2500V||
|680|681||||||50V|200V||1000V|2500V||
|750|751||||||50V|200V||1000V|2500V||
|820|821||||||50V|200V||1000V|2500V||
|910|911||||||50V|200V||1000V|1000V||
|1000|102||||||50V|200V||1000V|1000V||
|1200|122||||||50V|||1000V|1000V||
|1500|152||||||50V|||500V|1000V||
|1800|182||||||50V|||500V|1000V||
|2200|222||||||50V|||300V|1000V||
|2700|272|||||||||300V|500V||
|3300|332||||||||||500V||
|3900|392||||||||||500V||
|4700|472||||||||||500V||
|5100|512||||||||||500V||
|10000|103||||||||||||



Consult factory for Non-Standard values. 

www.johansontechnology.com 

9 

DIELECTRIC CHARACTERISTICS NPO TEMPERATURE COEFFICIENT: 0 ± 30ppm /°C, -55 to 125°C QUALITY FACTOR /  DF: Q >1,000 @ 1KHz (C>1,000pF), Typical 10,000 (C<1,000 pF) INSULATION RESISTANCE: >100 GΩ @ 25°C,WVDC[1] ; 125°C IR is 10% of 25°C rating TEST PARAMETERS: 1MHz ±50kHz, 1.0±0.2VRMS for capacitance values ≤ 1,000pF 1kHZ ±50Hz, 1.0±0.2VRMS for capacitance values > 1,000pF DIELECTRIC STRENGTH: 500 V ≤ 2.5 X WVDC[1] Min., 25°C, 50 mA max 1000 V ≤ 1.5 X WVDC[1] Min., 25°C, 50 mA max > 1500 = 1.2 X WVDC[1] Min., 25°C, 50 mA max AVAILABLE CAPACITANCE: Size 0201: 0.2 - 100 pF Size 1111:     0.2 - 1000 pF Size 0402: 0.2 - 33 pF Size 2525:     1.0 - 2700 pF Size 0603: 0.2 - 100 pF Size 3838:     1.0 - 5100 pF Size 0805: 0.3 - 220 pF 

*ON REQUEST, WE CAN EXTEND THE HIGHEST TEMPERATURE TO +150° C FOR ANY OF OUR HIGH-Q SERIES 

## MECHANICAL & ENVIRONMENTAL CHARACTERISTICS 

||SPECIFICATION|TEST PARAMETERS|
|---|---|---|
|SOLDERABILITY:|Solder coverage ≥ 90% of metalized areas|Preheat chip to 120°-150°C for 60 sec., dip terminals in rosin flux|
||No termination degradation|then dip in Sn62 solder @ 240°±5°C for 5±1 sec|
|RESISTANCE TO|No mechanical damage|Preheat device to 80°-100°C for 60 sec.|
|SOLDERING HEAT:|Capacitance change: ±2.5% or 0.25pF|followed by 150°-180°C for 60 sec.|
||Q>500   I.R. >10 G Ohms|Dip in 260°±5°C solder for 10±1 sec.|
||DWV2: 2.5 x WVDC1|Measure after 24±2 hour cooling period|
|TERMINAL|Termination should not pull off.|Linear pull force3exerted on axial leads soldered to each terminal.|
|ADHESION:|Ceramic should remain undamaged.||
|PCB DEFLECTION:|No mechanical damage.|Glass epoxy PCB: 2 mm deflection|
||Capacitance change: 5% or||
||0.5pF whichever is greater.||
|LIFETEST:|MIL-STD-202, Method 108l|Applied voltage: 200% of WVDC1for capacitors rated at 500 volts DC or less.|
||No mechanical damage|100% of WVDC1for capacitors rated at 1250 volts DC or less.|
||Capacitance change: ±3.0% or 0.3 pF|Temperature: 125°±3°C|
||Q>500   I.R. >1 G Ohms|Test time: 1000+48-0 hours|
||DWV2: 2.5 x WVDC1||
|THERMAL CYCLE:|No mechanical damage.|5 cycles of: 30±3 minutes @ -55°+0/-3°C,|
||Capacitance change: ±2.5% or 0.25pF|2-3 min. @ 25°C, 30±3 min. @ +125°+3/-0°C,|
||Q>2000   I.R. >10 G Ohms|2-3 min. @ 25°C|
||DWV2: 2.5 x WVDC1|Measure after 24±2 hour cooling period|
|HUMIDITY,|No mechanical damage.|Relative humidity: 90-95%|
|STEADY STATE:|Capacitance change: ±5.0% or 0.50pF max.|Temperature: 40°±2°C|
||Q>300 I.R. ≥1 G-Ohm|Test time: 500 +12/-0 Hours|
||DWV2: 2.5 x WVDC1|Measure after 24±2 hour cooling period|
|HUMIDITY,|No mechanical damage.|Applied voltage: 1.5 VDC, 50 mA max.|
|LOW VOLTAGE:|Capacitance change: ±5.0% or 0.50pF max.|Relative humidity: 85±2%  Temperature: 40°±2°C|
||Q>300 I.R. = 1 G-Ohm min.|Test time: 240 +12/-0 Hours|
||DWV2: 2.5 x WVDC1|Measure after 24±2 hour cooling period|
|VIBRATION:|No mechanical damage.||
||Capacitance change: ±2.5% or 0.25pF|Cycle performed for 2 hours in each of three perpendicular directions|
||Q>1000   I.R. ≥ 10 G-Ohm|Frequency range 10Hz to 55 Hz to 10 Hz traversed|
||DWV2: 2.5 x WVDC1|in 1 minute. Harmonic motion amplitude: 1.5mm|
||1- WVDC - Working Voltage DC.||
||2- DWV - Dielectric Withstanding Voltage.||
||3- 0402≥2.0lbs, 0603≥4.0lbs (min).||
||AEC-Q200: Qualifcation required for automotive|application - Not available for all series - Call factory for info.|



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10 

MECHANICAL CHARACTERISTICS 

Size Units Length Width Thickness End Band EIA 0201 In .024 ±.001 .012 ±.001 .012 ±.001 .008 Max. Metric (0603) mm (0.60 ±0.03) (0.30 ±0.03) (0.30 ±0.03) (0.20 Max.) EIA 0402 In .040 ±.004 .020 ±.004 .020 ±.004 .010 ±.006 Metric (1005) mm (1.02 ±0.1) (0.51 ±0.1) (0.51 ±0.1) (0.25 ±.15) EIA 0603 In .062 ±.006 .032 ±.006 .030 +.005/-.003 .014 ±.006 Metric (1608) mm (1.57 ±0.15) (0.81 ±0.15) (0.76 +.13-.08) (0.35 ±.15) EIA 0805 In .080 ±.008 .050 ±.008 .040 ±.006 .020 ±.010 ~~_~~ Metric (2012) mm (2.03 ±0.20) (1.27 ±0.20) (1.02 ±.15) (0.50 ±.25) HORIZONTAL AND VERTICLE ORIENTED CAPACITORS Horizontal Electrode Orientation 

## Vertical Electrode Orientation 

## APPLICATIONS & FEATURES 

Size: EIA 0201, 0805, 1111 Performance: SRF’s up to 20 GHz, Ultra High Q, Tight tolerance, Ultralow ESR Termination: Ni/Au, Ni/Sn, Ni/SnPb Applications: High Frequency Wireless Communications, Portable Wireless Products, Battery Powered Products 

RoHS Compliant 

## BENIFITS OF USING ORIENTED CAPACITORS 

- Consistent Orientation - Improved repeatability of production circuits. 

- Consistent Orientation - More consistent filter performance. 

- Vertical Orientation - The elimination of parallel frequencies. 

- Vertical Orinetation - Lower inductance for a given capacitor. 

- Horizontal Orientation - Lower coupling between adjacent capacitors. 

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11 

## E-SERIES TERMINATIONS AND LEADS 

## CHIP DIMENSIONS 

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Termination Size Units L Tol  W Tol T E / B Tol For all E-Series Models:<br>V, T, U, C S42E mmIn 0.1102.79 +0.51  -0.25+.020  -.010 0.1102.79 +/- .015+/- 0.38 0.102 Max.2.59 Max. 0.015 Typ.0.38 Typ. +/- 0.008+/- 0.20 OPERATING TEMP. :INSULATION RESISTANCE: -55 to +150°C>10G Ω @ 25°C<br>T, U, C S48E In 0.230 +.025  -.010 0.250 +/- .015 0.150 Max. 0.025 Typ. TEMPERATURE COEFFICIENT: 0 ± 30ppm /°C, -55 to<br>mm 5.84 +0.63  -0.25 6.35 +/- 0.38 3.81 Max. 0.63 Typ.  125°C<br>T, U, C S58E In 0.380 +.015  -.010 0.380 +/- .010 0.170 Max. 0.025 Typ. DISSIPATION FACTOR (TYP.): < 0.05% @ 1 MHz<br>mm 9.65 +0.38  -0.25 9.65 +/- 0.25 4.32 Max. 0.63 Typ.<br>Drawings not to scale<br>S42E Family Termination Codes “V”, “T”,  “U”, or  “C” Microstrip Ribbon Leads (Non-Magnetic),  Axial Ribbon Leads (Non-Magnetic), Termi-<br>S48E and S58E Families Termination Codes  “U”, “C” Termination Code “1” nation Code “2”<br>e<br>e<br>W<br> L<br> E/B X X<br>T<br>LL  LL  LL  LL<br>Axial Wire Leads (Non-Magnetic),  Radial Ribbon Leads (Non-Magnetic), Ter- Radial Wire Leads (Non-Magnetic),<br>Termination Code “3” e mination Code “4” e Termination Code “5”<br>LL LL<br>T LL LL<br>W W<br>LL LL T<br>X X<br>LL<br>e e<br>Lead Size LL(min) X Tol e e-Tol Lead Size LL(min) X Tol e e-Tol<br>0.25 0.093 +/-0.005 0.004 +/- 0.002 0.352 0.093 +/-0.005 0.004 +/- 0.002<br>S42E S42E<br>6.40 2.36 +/- 0.13 0.102 +/- 0.051 8.90 2.36 +/- 0.13 0.102 +/- 0.051<br>0.394 0.217 +/- 0.02 0.009 - 0.0019/+ 0.0031 0.501 0.217 +/- 0.02 0.009 - 0.0019/+ 0.0031<br>1 S48E 4 S48E<br>10.0 5.5 +/- 0.50 0.220 - 0.050/+ 0.080 12.70 5.50 +/- 0.50 0.220 - 0.050/+ 0.080<br>0.748 0.35 +/- 0.02 0.010 - 0.0019/+ 0.0039 0.886 0.35 +/- 0.02 0.010 - 0.0019/+ 0.0039<br>S58E S58E<br>19.00 8.90 +/- 0.50 0.250 - 0.050/+ 0.100 22.50 8.90 +/- 0.50 0.25 - 0.050/+ 0.100<br>0.25 0.093 +/-0.005 0.004 +/- 0.002 0.25<br>S42E S42E<br>6.40 2.36 +/- 0.13 0.102 +/- 0.051 6.40<br>0.394 0.217 +/- 0.02 0.009 - 0.0019/+ 0.0031 0.394<br>2 S48E 5 S48E 0.020in (0.511) diameter wire<br>10.00 5.50 +/- 0.50 0.220 - 0.050/+ 0.080 10.00<br>0.748 0.35 +/- 0.02 0.010 - 0.0019/+ 0.0039 0.748<br>S58E S58E<br>19.00 8.90 +/- 0.50 0.25 - 0.050/+ 0.100 19.00<br>0.25<br>S42E<br>6.40<br>0.394<br>3 S48E 0.020in (0.511) diameter wire<br>10.00<br>0.748<br>S58E<br>19.00<br>**----- End of picture text -----**<br>


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12 

RF CHARACTERISTICS - 0201 R05L SERIES More data at: https://jtisoft.johansontechnology.com 

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Resonant Frequency : 0201/R05L<br>q y 0201 R05L Equivalent Series Resistance (ESR)<br>100 300<br>Typical values of  SRF with:<br> Series mounting<br> Horizontal orientation 250<br> 14 mil-thick FR4  substrate<br>SRF<br>200<br>3.0 pF<br>150 10 pF<br>10<br>33 pF<br>100<br>56 pF<br>50 100 pF<br>Typical values<br>0<br>1 0 500 1000 1500 2000<br>1 10 100 Freq (MHz)<br>Capacitance value (pF)<br>The Series Resonant Frequency is highly dependent on the substrate,<br>pad dimensions, and measurement method. The above chart is for<br>reference only.<br>0201 R05L Q factor 0201 R05L Max Current<br>10000 3<br>Estimated maximum current based on<br> Ambient temperature = 65 °C<br>2.5  Thermal resistance of  DUT on<br>substrate  = 300°C/W<br>1000  Infinite heatsink<br>2  Duty cycle=100%<br>3 pF<br>3.0 pF<br>1.5 10 pF<br>100 10 pF<br>33 pF<br>33 pF 1<br>56 pF<br>10 56 pF 0.5 100 pF<br>100 pF<br>0<br>1 0 500 1000 1500 2000<br>0 500 1000 1500 2000 Freq (MHz)<br>Freq (MHz)<br>RF CHARACTERISTICS - 0402 R07S SERIES More data at: https://jtisoft.johansontechnology.com<br>0402 R07S Series Resonant frequency 0402 R07S Equivalent Series Resistance (ESR)<br>250<br>Typical values of  SRF with:<br> Series mounting<br> Horizontal orientation 200<br> 16 mil-thick Rogers 4003 substrate<br>10 150 2.2 pF<br>5.6 pF<br>100 10 pF<br>15 pF<br>50<br>SRF 33 pF<br>Typical values<br>0<br>0 500 1000 1500 2000<br>1<br>Freq (MHz)<br>0.1 1 10<br>Capacitance value (pF)<br>ESR (mΩ)<br>Resonant frequency (GHz)<br>Q factor<br>Maximum current (A rms)<br>ESR (mΩ)<br>Resonant frequency (GHz)<br>**----- End of picture text -----**<br>


The Series Resonant Frequency is highly dependent on the substrate, pad dimensions, and measurement method. The above chart is for reference only. 

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## RF CHARACTERISTICS 0402 R07S SERIES More data at: https://jtisoft.johansontechnology.com 

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0402 R07S Q factor 0402 R07S Max Current<br>10000 5<br>Estimated maximum current based on<br>4.5  Ambient temperature = 65 °C<br> Thermal resistance of  DUT on substrate  = 120°C/W<br>4  Infinite heatsink<br>1000 3.5  Duty cycle=100%<br>2.2 pF 3 33 pF<br>2.5 15 pF<br>100 5.6 pF<br>2 10 pF<br>10 pF<br>1.5 5.6 pF<br>10 15 pF 1<br>2.2 pF<br>33 pF 0.5<br>Typical values 0<br>1 0 500 1000 1500 2000<br>0 500 1000 1500 2000 Freq (MHz)<br>Freq (MHz)<br>Q factor<br>Maximum current (A rms)<br>**----- End of picture text -----**<br>


## RF CHARACTERISTICS 0603 R14S SERIES More data at: https://jtisoft.johansontechnology.com 

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0603 R14S Series Resonant frequency<br>100<br>Typical values of  SRF with:<br> Series mounting<br> Horizontal orientation<br> 16 mil-thick Rogers 4003 substrate<br>10<br>SRF<br>1<br>0.1 1 10 100<br>Capacitance value (pF)<br>Resonant frequency (GHz)<br>**----- End of picture text -----**<br>


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0603 R14S Series Resonant frequency 0603 R14S Equivalent Series Resistance (ESR)<br>100<br>Typical values of  SRF with: Series mounting 280<br> Horizontal orientation<br> 16 mil-thick Rogers 4003 substrate 240<br>200 2.0 pF<br>160 4.7 pF<br>10 10 pF<br>120<br>39 pF<br>80<br>75 pF<br>SRF<br>40<br>Typical values 100 pF<br>0<br>0 500 1000 1500 2000<br>1<br>0.1 1 10 100 Freq (MHz)<br>Capacitance value (pF)<br>The Series Resonant Frequency is highly dependent on the substrate,<br>pad dimensions, and measurement method. The above chart is for<br>reference only.<br>0603 R14S Q factor 0603 R14S Max Current<br>10000<br>8 Estimated maximum current based on<br> Ambient temperature = 65 °C<br>7  Thermal resistance of  DUT on substrate  = 60°C/W<br>1000 2.0 pF 6  Infinite heatsinkDuty cycle=100% 100 pF<br>4.7 pF<br>5 75 pF<br>100 10 pF 4 39 pF<br>39 pF 3 10 pF<br>10 75 pF 2 4.7 pF<br>100 pF 1 2.0 pF<br>Typical values<br>1 0<br>0 500 1000 1500 2000 0 500 1000 1500 2000<br>Freq (MHz) Freq (MHz)<br>ESR (mΩ)<br>Resonant frequency (GHz)<br>Q factor<br>Maximum current (A rms)<br>**----- End of picture text -----**<br>


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RF CHARACTERISITCS - 0805 R15S SERIES More data at: https://jtisoft.johansontechnology.com 

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0805 R15S Series Resonant frequency<br>Typical values with:<br> Series mounting<br> Horizontal orientation<br>10  16 mil-thick Rogers 4003C  substrate<br>SRF<br>1<br>1 10 100<br>Capacitance value (pF)<br>Resonant frequency (GHz)<br>**----- End of picture text -----**<br>


The Series Resonant Frequency is highly dependent on the substrate, pad dimensions, and measurement method. The above chart is for reference only. 

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0805 R15S Q factor<br>10000<br>0.3 pF<br>1000 2.0 pF<br>4.7 pF<br>10 pF<br>100<br>39 pF<br>75 pF<br>10<br>100 pF<br>220 pF<br>Typical values<br>1<br>0 500 1000 1500 2000<br>Freq (MHz)<br>Q factor<br>**----- End of picture text -----**<br>


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0805 R15S Max Current vs. Cap. Value<br>**----- End of picture text -----**<br>


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100 Estimated maximum current based on  Ambient temperature = 65 °C<br> Thermal resistance of  DUT on substrate  = 40°C/W<br> Infinite heatsink 300 MHz<br> Duty cycle=100%<br>10 128 MHz<br>100 MHz<br>1 64 MHz<br>27 MHz<br>0.1 13 MHz<br>7 MHz<br>0.01<br>0.1 1 10 100<br>Capacitance value (pF)<br>Maximum current (A rms)<br>**----- End of picture text -----**<br>


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0805 R15S Equivalent Series Resistance (ESR)<br>300<br>250 0.3 pF<br>2.0 pF<br>200 4.7 pF<br>150 10 pF<br>39 pF<br>100<br>75 pF<br>50 100 pF<br>Typical values 220 pF<br>0<br>0 500 1000 1500 2000<br>Freq (MHz)<br>Effective capacitance value: 0805/R15S<br>400<br>Typical values on a 16 mil RO4003C<br>350<br>300<br>250<br>200<br>C(1 MHz) = 220 pF<br>150 C(1 MHz) = 100 pF<br>C(1 MHz) = 56 pF<br>100<br>50<br>0<br>0 200 400 600 800 1000 1200 1400 1600 1800 2000<br>Freq (MHz)<br>ESR (mΩ)<br>Effective Capacitance Value (pF)<br>**----- End of picture text -----**<br>


## 0805 R15S Max Current vs. Frequency 

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Estimated maximum current based on<br>10  Ambient temperature = 65 °C<br> Infinite heatsinkThermal resistance of  DUT on substrate  = 40°C/W 220 pF<br>8  Duty cycle=100% 100 pF<br>75 pF<br>6<br>39 pF<br>10 pF<br>4<br>4.7 pF<br>2 2.0 pF<br>0.3 pF<br>0<br>0 500 1000 1500 2000<br>Freq (MHz)<br>Maximum current (A rms)<br>**----- End of picture text -----**<br>


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## RF CHARACTERISTICS - 1111 S24E SERIES More data at: https://jtisoft.johansontechnology.com 

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1111 S42E Series Resonant frequency 1111 S42E Equivalent Series Resistance (ESR)<br>300<br>Typical values with:<br>10  Series mountingHorizontal orientation 250<br> 60 mil-thick Rogers 4350B  substrate<br>200 1.2 pF<br>4.7 pF<br>150<br>SRF 10 pF<br>1<br>100 33 pF<br>100 pF<br>50<br>300 pF<br>Typical values<br>0<br>0.1 0 500 1000 1500 2000<br>1 10 100 1000 Freq (MHz)<br>Capacitance value (pF)<br>ESR (mΩ)<br>Resonant frequency (GHz)<br>**----- End of picture text -----**<br>


The Series Resonant Frequency is highly dependent on the substrate, pad dimensions, and measurement method. The above chart is for reference only. 

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1111 S42E Q factor<br>10000<br>S42E<br>1000 0.2 pF<br>1.2 pF<br>100 4.7 pF<br>10 pF<br>33 pF<br>10<br>100 pF<br>Typical values 300 pF<br>1<br>0 500 1000 1500 2000<br>Freq (MHz)<br>Q factor<br>**----- End of picture text -----**<br>


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Effective capacitance value: 1111/S42E<br>400<br>Typical values on a 60-mil thick<br>350 Rogers 4350B substrate<br>300<br>250<br>C(1 MHz) = 300pF<br>200<br>C(1 MHz) = 100 pF<br>150 C(1 MHz) = 10 pF<br>100<br>50<br>0<br>0 500 1000 1500 2000<br>Freq (MHz)<br>Effective capacitance value (pF)<br>**----- End of picture text -----**<br>


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1111 S42E Max Current vs. Capacitance Value 1111 S42E Max Current vs. Frequency<br>1000 20<br>Estimated maximum current based on  Estimated maximum current based on<br>100  Infinite heatsinkDuty cycle=100%Thermal resistance of  DUT on substrate  = 20°C/WAmbient temperature = 65 °C 181614  Infinite heatsinkDuty cycle=100%Thermal resistance of  DUT on substrate  = 20°C/WAmbient temperature = 65 °C 300 pF100 pF<br>10 200 MHz 12 33 pF<br>10<br>100 MHz 10 pF<br>8<br>1 40 MHz 6 4.7 pF<br>4 1.2 pF<br>0.1 15 MHz 2 0.2 pF<br>0<br>7 MHz<br>0 500 1000 1500 2000<br>0.01<br>Freq (MHz)<br>0.1 1 10 100 1000<br>Capacitance value (pF)<br>Maximum Current (A rms)<br>Maximum Current (A rms)<br>**----- End of picture text -----**<br>


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## RF CHARACTERISTICS - 2525 S48E SERIES More data at: https://jtisoft.johansontechnology.com 

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2525 S48E Series Resonant Frequency 2525 S48E Equivalent Series Resistance (ESR)<br>10 140<br>Typical values of SRF when<br>measured on a 8720C VNA  120<br>using a shunt-through fixture<br>100<br>10 pF<br>80<br>22 pF<br>1 60 33 pF<br>40 130 pF<br>20 470 pF<br>SRF Typical values<br>0<br>0 50 100 150 200 250 300<br>0.1 Freq (MHz)<br>1 10 100 1000<br>Capacitance (pF)<br>ESR (mΩ)<br>Frequency (GHz)<br>**----- End of picture text -----**<br>


The Series Resonant Frequency is highly dependent on the substrate, pad dimensions, and measurement method. The above chart is for reference only. 

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2525 S48E Q factor<br>10000<br>1000<br>10 pF<br>100 22 pF<br>33 pF<br>10 130 pF<br>470 pF<br>Typical values<br>1<br>0 50 100 150 200 250 300<br>Freq (MHz)<br>Q factor<br>**----- End of picture text -----**<br>


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2525 S48E Max Current vs. Frequency<br>20<br>Estimated maximum current based on<br>18  Ambient temperature = 65 °C<br> Thermal resistance of  DUT on substrate  = 15°C/W<br>16  Infinite heatsink<br> Duty cycle=100%<br>14<br>12 470 pF<br>10 130 pF<br>8 33 pF<br>6 22 pF<br>4<br>10 pF<br>2<br>0<br>0 50 100 150 200 250 300<br>Freq (MHz)<br>Imax (A rms)<br>**----- End of picture text -----**<br>


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RF CHARACTERISTICS - 3838 S58E SERIES 

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3838 S58E Series Resonant frequency<br>10<br>Typical values of SRF when<br>measured on a 8720C VNA<br>using a shunt-through fixture<br>1<br>0.1<br>SRF<br>0.01<br>1 10 100 1000<br>Capacitance (pF)<br>Frequency (GHz)<br>**----- End of picture text -----**<br>


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3838 S58E Equivalent Series Resistance (ESR)<br>180<br>160<br>140<br>120<br>100 10 pF<br>80 47 pF<br>60 180 pF<br>40 1000 pF<br>20<br>Typical values<br>0<br>0 50 100 150 200 250 300<br>Freq (MHz)<br>ESR (mΩ)<br>**----- End of picture text -----**<br>


The Series Resonant Frequency is highly dependent on the substrate, pad dimensions, and measurement method. The above chart is for reference only. 

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3838 S58E Q factor<br>10000<br>1000<br>10 pF<br>100<br>47 pF<br>180 pF<br>10<br>1000 pF<br>Typical values<br>1<br>0 50 100 150 200 250 300<br>Freq (MHz)<br>Q factor<br>**----- End of picture text -----**<br>


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3838 S58E Max Current vs. Frequency<br>Estimated maximum current based on<br> Ambient temperature = 65 °C<br> Thermal resistance of  DUT on substrate  = 12°C/W<br>20  Infinite heatsink<br> Duty cycle=100%<br>15<br>10 pF<br>10 47 pF<br>180 pF<br>5 1000 pF<br>0<br>0 50 100 150 200 250 300<br>Freq (MHz)<br>Maximum current (A rms)<br>**----- End of picture text -----**<br>


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