MLCC High-Q Caps Datasheet by Johanson Technology Inc.

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\252\ \S48HE\ \470\ \M \v\ ‘4‘ \E‘ \-AEC\
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These lines of multilayer capacitors have been developed for
High-Q and microwave applications.
The S-Series (R07S, R14S, R15S) capacitors give an ultra-
high Q performance, and exhibit NP0 temperature characteris-
tics.
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. They
are offered in chip (Ni barrier or Non-Magnetic Pt.-Ag) or in
Non-Magnetic leaded form.
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
MULTI-LAYER HIGH-Q CAPACITORS
HOW TO ORDER
Part Number written:
252S48E470KV4E
WVDC2
250 = 25 V
500 = 50V
201 = 200 V
251 = 250 V
501 = 500 V
102 = 1000 V
152 = 1500 V
252 = 2500 V
362 = 3600 V
722 = 7200 V
252
CASE SIZE
R05 (0201)
R07 (0402)
R14 (0603)
R15 (0805)
S42 (1111)
S48 (2525)
S58 (3838)
S48 470
TOLERANCE
< 10pF
A = ± 0.05 pF
B = ± 0.10 pF
C = ± 0.25 pF
D = ± 0.50 pF
≥ 10pF
F = ±1 %
G = ±2%
J = ±5%
K = ± 10%
For tolerance
availability, see
chart.
K
MARKING
3 = Cap Code
& Tolerance
4 = No Marking
6 = EIA Code
(Marking option is only available
on 0805 and larger case sizes)
4
TERMINATION
Nickel Barrier
V = Ni/Sn (Green)
T = Ni/SnPb
G = Ni/Au (Green)
Non-Mag1
U = Cu/Sn (Green)
C = Cu/SnPb
Leaded (All Non-
Mag)1
1 = Microstrip
2 = Axial Ribbon
3 = Axial Wire
4 = Radial Ribbon
5 = Radial Wire
V
CAPACITANCE (pF)
1st two digits are
significant; third digit
denotes number of
zeros, R = decimal.
100 = 10 pF
101 = 100 pF
PACKAGING
S = Bulk
W = Waffle Pack
0201 - 0603
Y = Paper 5” Reel
T = Paper 7” Reel
R1 = Paper 13” Reel
J1 = Paper 5” Reel -
Horizontally Oriented Electrodes
N1 = Paper 5” Reel -
Vertically Oriented Electrodes
L1 = Paper 7” Reel -
Horizontally Oriented Electrodes
V1 = Paper 7” Reel -
Vertically Oriented Electrodes
0805 - 3838
Z = Embossed 5” Reel
E = Embossed 7” Reel
U1 = Embossed 13” Reel
M1 = Embossed 5” Reel -
Horizontally Oriented Electrodes
Q1 = Embossed 5” Reel -
Vertically Oriented Electrodes
G1 = Embossed 7” Reel -
Horizontally Oriented Electrodes
P1 = Embossed 7” Reel -
Vertically Oriented Electrodes
Tape specifications
conform to EIA RS481
E
DIELECTRIC
S = Ultra High Q NPO
L = High Q NPO
E = Ultra High Q NPO,
High Voltage, High
Power
G = Fully Oriented,
Ultra High-Q NPO
E
1 - Not available for all MLCC - Call factory for info.
2 - WVDC - Working Voltage DC.
3 -Qualification required for automotive application, Not available for all series - Call factory for info.
QUALIFICATION
AEC-Q200
qualification 3
(optional)
-AEC
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RF Power Applications
0201 (R05) 0402
(R07S)
0603
(R14S)
0805
(R15S)
0805
(R15L)
1111
(S42E)
2525
(S48E)
3838
(S58E)
NPO
(R05L) NPO
(R05G)
Capacitance
pF Code
0.1 0R1
A
B
C
D
25/50 V 25 V 50/250 V 250 V
0.2 0R2 25/50 V 25 V 50/250 V 250 V 500V 1500V
0.3 0R3 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V
0.4 0R4 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V
0.5 0R5 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V
0.6 0R6 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
0.7 0R7 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
0.8 0R8 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
0.9 0R9 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
1.0 1R0 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
1.1 1R1 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
1.2 1R2 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
1.3 1R3 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
1.4 1R4 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
1.5 1R5 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
1.6 1R6 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
1.7 1R7 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
1.8 1R8 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
1.9 1R9 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
2.0 2R0 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
2.1 2R1 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
2.2 2R2 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
2.4 2R4 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
2.7 2R7 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
3.0 3R0 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
3.3 3R3 25/50 V 25 V 50/250 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
3.6 3R6 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
3.9 3R9 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
4.3 4R3 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
4.7 4R7 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
5.1 5R1 A**
B
C
D
25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
5.6 5R6 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
6.2 6R2 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
6.8 6R8 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
7.5 7R5 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
8.2 8R2 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
9.1 9R1 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
10 100
F
G
J
K
25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
11 110 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
12 120 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
13 130 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
15 150 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
16 160 25/50 V 25 V 50/200 V 250 V 250 V 500V 1500V 3600V 3600V 7200V
18 180 25/50 V 25 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
LOW ESR / HIGH-Q CAPACITOR SELECTION CHART
EIA Size
Cap. Value
Consult factory for Non-Standard values.
**A tolerance only available for R07S (0402) and R14S(0603) caps
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RF Power Applications
0201 (R05) 0402
(R07S)
0603
(R14S)
0805
(R15S)
0805
(R15L)
1111
(S42E)
2525
(S48E)
3838
(S58E)
NPO
(R05L) NP0
(R05G)
Capacitance Toler-
ance
pF Code
36 360
F
G
J
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 500V 200V 600V 2500V 3600V
270 271 500V 200V 600V 2500V 3600V
300 301 500V 200V 600V 1500V 3600V
330 331 500V 200V 600V 1500V 3600V
360 361 500V 200V 600V 1500V 3600V
390 391 500V 200V 500V 1500V 3600V
430 431
G
J
K
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
LOW ESR / HIGH-Q CAPACITOR SELECTION CHART
EIA Size
Cap. Value
Consult factory for Non-Standard values.
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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 force3 exerted 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.
LIFE TEST:
MIL-STD-202, Method 108l Applied voltage: 200% of WVDC1 for capacitors rated at 500 volts DC or less.
No mechanical damage 100% of WVDC1 for 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
DIELECTRIC CHARACTERISTICS NPO
0 ± 30ppm /°C, -55 to 150°C
Q
>1,000 @ 1KHz (C>1,000pF), Typical 10,000 (C<1,000 pF)
>100 G @ 25°C,WVDC1;
125°C IR is 10% of 25°C rating
1MHz
±
50kHz, 1.0
±
0.2VRMS for capacitance values 1,000pF
1kHZ
±
50Hz, 1.0
±
0.2VRMS for capacitance values > 1,000pF
500 V 2.5 X WVDC1 Min., 25°C, 50 mA max
1000 V ≤ 1.5 X WVDC1 Min., 25°C, 50 mA max
> 1500 = 1 X WVDC1 Min., 25°C, 50 mA max
TEMPERATURE COEFFICIENT:
QUALITY FACTOR / DF:
INSULATION RESISTANCE:
TEST PARAMETERS:
DIELECTRIC STRENGTH:
Size 1111: 0.2 - 1000 pF
Size 2525: 1.0 - 2700 pF
Size 3838: 1.0 - 5100 pF
AVAILABLE CAPACITANCE:
Size 0201: 0.2 - 100 pF
Size 0402: 0.2 - 33 pF
Size 0603: 0.2 - 100 pF
Size 0805: 0.3 - 220 pF
1 - WVDC - Working Voltage DC.
2 - DWV - Dielectric Withstanding Voltage.
3 - 0402 2.0lbs, 0603 4.0lbs (min).
AEC-Q200: Qualification required for automotive application - Not available for all series - Call factory for info.
Horizontal Electrode Orientation Vertical Electrode Orientation |l|l|
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BENIFITS OF USING ORIENTED CAPACITORS
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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)
MECHANICAL CHARACTERISTICS
Horizontal Electrode Orientation Vertical Electrode Orientation
HORIZONTAL AND VERTICLE ORIENTED CAPACITORS
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
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.
RoHS Compliant
T i 33 k tit A it: P w “Nun 4 Q P hi FL 41% -w “ its Ti. , Ti GE]
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Unleaded Termination Codes V (Ni/Sn),
T (Ni/SnPb), “U” (Cu/Sn non-mag), “C”
(Cu/SnPb non-mag)
Microstrip Ribbon Leads (Non-Magnetic),
Termination Code “1”
Axial Ribbon Leads (Non-Magnetic), Termi-
nation Code “2”
Axial Wire Leads (Non-Magnetic),
Termination Code “3”
Radial Ribbon Leads (Non-Magnetic), Ter-
mination Code “4”
Radial Wire Leads (Non-Magnetic),
Termination Code “5”
Termination Size Units L Tol W Tol T E / B Tol
V,T
U,C
S42E In 0.110 +.020 -.010 0.110 +/- .015 0.102 Max. 0.015 Typ. +/- 0.008
mm 2.79 +0.51 -0.25 2.79 +/- 0.38 2.59 Max. 0.38 Typ. +/- 0.20
S48E In 0.230 +.025 -.010 0.250 +/- .015 0.150 Max. 0.025 Typ.
mm 5.84 +0.63 -0.25 6.35 +/- 0.38 3.81 Max. 0.63 Typ.
S58E In 0.380 +.015 -.010 0.380 +/- .010 0.170 Max. 0.025 Typ.
mm 9.65 +0.38 -0.25 9.65 +/- 0.25 4.32 Max. 0.63 Typ.
For all E-Series Models:
OPERATING TEMP. :
-55 to +125°C
INSULATION RESISTANCE:
>10G @ 25°C
TEMPERATURE COEFFICIENT:
0 ± 30ppm /°C, -55 to
125°C
DISSIPATION FACTOR TYP.:
< 0.05% @ 1 MHz
E-SERIES TERMINATIONS AND LEADS
L
E/B
T
W
e
LL LL
X
e
LL LL
X
LL
W
X
XX
LL
eeLL
X
ee
LLLL
LLLL
W
T
W
T
Lead Size LL(min) X Tol ee-Tol
1
S42E 0.25 0.093 +/-0.005 0.004 +/- 0.002
6.40 2.36 +/- 0.13 0.102 +/- 0.051
S48E 0.394 0.217 +/- 0.02 0.009 - 0.0019/+ 0.0031
10.0 5.5 +/- 0.50 0.220 - 0.050/+ 0.080
S58E 0.748 0.35 +/- 0.02 0.010 - 0.0019/+ 0.0039
19.00 8.90 +/- 0.50 0.250 - 0.050/+ 0.100
2
S42E 0.25 0.093 +/-0.005 0.004 +/- 0.002
6.40 2.36 +/- 0.13 0.102 +/- 0.051
S48E 0.394 0.217 +/- 0.02 0.009 - 0.0019/+ 0.0031
10.00 5.50 +/- 0.50 0.220 - 0.050/+ 0.080
S58E 0.748 0.35 +/- 0.02 0.010 - 0.0019/+ 0.0039
19.00 8.90 +/- 0.50 0.25 - 0.050/+ 0.100
3
S42E 0.25
0.020in (0.511) diameter wire
6.40
S48E 0.394
10.00
S58E 0.748
19.00
CHIP DIMENSIONS
Drawings not to scale
Lead Size LL(min) X Tol ee-Tol
4
S42E 0.352 0.093 +/-0.005 0.004 +/- 0.002
8.90 2.36 +/- 0.13 0.102 +/- 0.051
S48E 0.501 0.217 +/- 0.02 0.009 - 0.0019/+ 0.0031
12.70 5.50 +/- 0.50 0.220 - 0.050/+ 0.080
S58E 0.886 0.35 +/- 0.02 0.010 - 0.0019/+ 0.0039
22.50 8.90 +/- 0.50 0.25 - 0.050/+ 0.100
5
S42E 0.25
0.020in (0.511) diameter wire
6.40
S48E 0.394
10.00
S58E 0.748
19.00
Rest-mam Frequency : 0201mm
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RF CHARACTERISTICS - 0402 R07S SERIES
More data at: https://jtisoft.johansontechnology.com
RF CHARACTERISTICS - 0201 R05L SERIES
More data at: https://jtisoft.johansontechnology.com
Resonant Frequency : 0201/R05L
1
10
100
110 100
Resonant frequency (GHz)
Capacitance value (pF)
SRF
0201 R05L Resonant frequency
Typical values of SRF with:
Series mounting
Horizontal orientation
14 mil-thick FR4 substrate
0
50
100
150
200
250
300
0500 1000 1500 2000
ESR (mΩ)
Freq (MHz)
3.0 pF
10 pF
33 pF
56 pF
100 pF
0201 R05L Equivalent Series Resistance (ESR)
Typical values
1
10
100
1000
10000
0500 1000 1500 2000
Q factor
Freq (MHz)
3.0 pF
10 pF
33 pF
56 pF
100 pF
0201 R05L Q factor
0
0.5
1
1.5
2
2.5
3
0500 1000 1500 2000
Maximum current (A rms)
Freq (MHz)
3 pF
10 pF
33 pF
56 pF
100 pF
Estimated maximum current based on
Ambient temperature = 65 °C
Thermal resistance of DUT on
substrate = 300°C/W
Infinite heatsink
Duty cycle=100%
0201 R05L Max Current
1
10
0.1 110
Resonant frequency (GHz)
Capacitance value (pF)
SRF
Typical values of SRF with:
Series mounting
Horizontal orientation
16 mil-thick Rogers 4003 substrate
0402 R07S Series Resonant frequency
0
50
100
150
200
250
0500 1000 1500 2000
ESR (mΩ)
Freq (MHz)
2.2 pF
5.6 pF
10 pF
15 pF
33 pF
Typical values
0402 R07S Equivalent Series Resistance (ESR)
The Series Resonant Frequency is highly dependent on the substrate,
pad dimensions, and measurement method. The above chart is for
reference only.
The Series Resonant Frequency is highly dependent on the substrate, pad
dimensions, and measurement method. The above chart is for reference only.
0603 R145 Series Resonant frequency m (mm Maximum current [A rms)
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RF CHARACTERISTICS 0402 R07S SERIES
More data at: https://jtisoft.johansontechnology.com
RF CHARACTERISTICS 0603 R14S SERIES
More data at: https://jtisoft.johansontechnology.com
1
10
100
1000
10000
0500 1000 1500 2000
Q factor
Freq (MHz)
2.2 pF
5.6 pF
10 pF
15 pF
33 pF
Typical values
0402 R07S Q factor
1
10
100
0.1 110 100
SRF
Typical values of SRF with:
Series mounting
Horizontal orientation
16 mil-thick Rogers 4003 substrate
0603 R14S Equivalent Series Resistance (ESR)
Typical values
0
40
80
120
160
200
240
280
0500 1000 1500 2000
ESR (mΩ)
Freq (MHz)
2.0 pF
4.7 pF
10 pF
39 pF
75 pF
100 pF
0603 R14S Q factor
1
10
100
1000
10000
0500 1000 1500 2000
Q factor
Freq (MHz)
2.0 pF
4.7 pF
10 pF
39 pF
75 pF
100 pF
Typical values
0603 R14S Max Current
0
1
2
3
4
5
6
7
8
0500 1000 1500 2000
Maximum current (A rms)
Freq (MHz)
100 pF
75 pF
39 pF
10 pF
4.7 pF
2.0 pF
Estimated maximum current based on
Ambient temperature = 65 °C
Thermal resistance of DUT on substrate = 60°C/W
Infinite heatsink
Duty cycle=100%
0402 R07S Max Current
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
0500 1000 1500 2000
Maximum current (A rms)
Freq (MHz)
33 pF
15 pF
10 pF
5.6 pF
2.2 pF
Estimated maximum current based on
Ambient temperature = 65 °C
Thermal resistance of DUT on substrate = 120°C/W
Infinite heatsink
Duty cycle=100%
The Series Resonant Frequency is highly dependent on the substrate,
pad dimensions, and measurement method. The above chart is for
reference only.
E 11)..
15
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RF CHARACTERISITCS - 0805 R15S SERIES
More data at: https://jtisoft.johansontechnology.com
Effective capacitance value: 0805/R15S
0
50
100
150
200
250
300
350
400
0200 400 600 800 1000 1200 1400 1600 1800 2000
Effective Capacitance Value (pF)
Freq (MHz)
C(1 MHz) = 220 pF
C(1 MHz) = 100 pF
C(1 MHz) = 56 pF
Typical values on a 16 mil RO4003C
0805 R15S Series Resonant frequency
1
10
110 100
Resonant frequency (GHz)
Capacitance value (pF)
SRF
Typical values with:
Series mounting
Horizontal orientation
16 mil-thick Rogers 4003C substrate
0805 R15S Equivalent Series Resistance (ESR)
0
50
100
150
200
250
300
0500 1000 1500 2000
ESR (mΩ)
Freq (MHz)
0.3 pF
2.0 pF
4.7 pF
10 pF
39 pF
75 pF
100 pF
220 pF
Typical values
0805 R15S Q factor
1
10
100
1000
10000
0500 1000 1500 2000
Q factor
Freq (MHz)
0.3 pF
2.0 pF
4.7 pF
10 pF
39 pF
75 pF
100 pF
220 pF
Typical values
0805 R15S Max Current vs. Cap. Value
0.01
0.1
1
10
100
0.1 110 100
Maximum current (A rms)
Capacitance value (pF)
300 MHz
128 MHz
100 MHz
64 MHz
27 MHz
13 MHz
7 MHz
Estimated maximum current based on
Ambient temperature = 65 °C
Thermal resistance of DUT on substrate = 40°C/W
Infinite heatsink
Duty cycle=100%
0805 R15S Max Current vs. Frequency
0
2
4
6
8
10
0500 1000 1500 2000
Maximum current (A rms)
Freq (MHz)
220 pF
100 pF
75 pF
39 pF
10 pF
4.7 pF
2.0 pF
0.3 pF
Estimated maximum current based on
Ambient temperature = 65 °C
Thermal resistance of DUT on substrate = 40°C/W
Infinite heatsink
Duty cycle=100%
The Series Resonant Frequency is highly dependent on the substrate,
pad dimensions, and measurement method. The above chart is for
reference only.
ResonamlrlquencleHz) Q (actor 1111 542: Equivalent Series Resistance (ESR)
16
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RF CHARACTERISTICS - 1111 S24E SERIES
More data at: https://jtisoft.johansontechnology.com
Effective capacitance value: 1111/S42E
0
50
100
150
200
250
300
350
400
0500 1000 1500 2000
Effective capacitance value (pF)
Freq (MHz)
C(1 MHz) = 300pF
C(1 MHz) = 100 pF
C(1 MHz) = 10 pF
Typical values on a 60-mil thick
Rogers 4350B substrate
0.1
1
10
110 100 1000
Resonant frequency (GHz)
Capacitance value (pF)
SRF
Typical values with:
Series mounting
Horizontal orientation
60 mil-thick Rogers 4350B substrate
1111 S42E Series Resonant frequency
0
50
100
150
200
250
300
0500 1000 1500 2000
ESR (mΩ)
Freq (MHz)
1.2 pF
4.7 pF
10 pF
33 pF
100 pF
300 pF
Typical values
1111 S42E Equivalent Series Resistance (ESR)
1
10
100
1000
10000
0500 1000 1500 2000
Q factor
Freq (MHz)
S42E
0.2 pF
1.2 pF
4.7 pF
10 pF
33 pF
100 pF
300 pF
1111 S42E Q factor
Typical values
0.01
0.1
1
10
100
1000
0.1 110 100 1000
Maximum Current (A rms)
Capacitance value (pF)
200 MHz
100 MHz
40 MHz
15 MHz
7 MHz
Estimated maximum current based on
Ambient temperature = 65 °C
Thermal resistance of DUT on substrate = 20°C/W
Infinite heatsink
Duty cycle=100%
1111 S42E Max Current vs. Capacitance Value
1111 S42E Max Current vs. Frequency
0
2
4
6
8
10
12
14
16
18
20
0500 1000 1500 2000
Maximum Current (A rms)
Freq (MHz)
300 pF
100 pF
33 pF
10 pF
4.7 pF
1.2 pF
0.2 pF
Estimated maximum current based on
Ambient temperature = 65 °C
Thermal resistance of DUT on substrate = 20°C/W
Infinite heatsink
Duty cycle=100%
The Series Resonant Frequency is highly dependent on the substrate,
pad dimensions, and measurement method. The above chart is for
reference only.
1525 548: Max Currem vs. Frequency
17
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RF CHARACTERISTICS - 2525 S48E SERIES
More data at: https://jtisoft.johansontechnology.com
0.1
1
10
110 100 1000
Frequency (GHz)
Capacitance (pF)
SRF
2525 S48E Series Resonant Frequency
Typical values of SRF when
measured on a 8720C VNA
using a shunt-through fixture
2525 S48E Q factor
1
10
100
1000
10000
050 100 150 200 250 300
Q factor
Freq (MHz)
10 pF
22 pF
33 pF
130 pF
470 pF
Typical values
2525 S48E Max Current vs. Frequency
0
2
4
6
8
10
12
14
16
18
20
050 100 150 200 250 300
Imax (A rms)
Freq (MHz)
470 pF
130 pF
33 pF
22 pF
10 pF
Estimated maximum current based on
Ambient temperature = 65 °C
Thermal resistance of DUT on substrate = 15°C/W
Infinite heatsink
Duty cycle=100%
2525 S48E Equivalent Series Resistance (ESR)
0
20
40
60
80
100
120
140
050 100 150 200 250 300
ESR (mΩ)
Freq (MHz)
10 pF
22 pF
33 pF
130 pF
470 pF
Typical values
The Series Resonant Frequency is highly dependent on the substrate,
pad dimensions, and measurement method. The above chart is for
reference only.
f“'\\ .383 3.))...
18
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RF CHARACTERISTICS - 3838 S58E SERIES
0.01
0.1
1
10
110 100 1000
Frequency (GHz)
Capacitance (pF)
SRF
Typical values of SRF when
measured on a 8720C VNA
using a shunt-through fixture
3838 S58E Series Resonant frequency
3838 S58E Equivalent Series Resistance (ESR)
0
20
40
60
80
100
120
140
160
180
050 100 150 200 250 300
ESR (mΩ)
Freq (MHz)
10 pF
47 pF
180 pF
1000 pF
Typical values
3838 S58E Q factor
1
10
100
1000
10000
050 100 150 200 250 300
Q factor
Freq (MHz)
10 pF
47 pF
180 pF
1000 pF
Typical values
3838 S58E Max Current vs. Frequency
0
5
10
15
20
050 100 150 200 250 300
Maximum current (A rms)
Freq (MHz)
10 pF
47 pF
180 pF
1000 pF
Estimated maximum current based on
Ambient temperature = 65 °C
Thermal resistance of DUT on substrate = 12°C/W
Infinite heatsink
Duty cycle=100%
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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