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. 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 How to Order 252 S48 WVDC2 CASE SIZE R05 (0201) R07 (0402) R14 (0603) R15 (0805) S42 (1111) S48 (2525) S58 (3838) 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 Part Number written: 252S48E470KV4E E 470 K CAPACITANCE (pF) 1st two digits are significant; third digit denotes number of zeros, R = decimal. 100 = 10 pF 101 = 100 pF 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 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. V 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 Non1 Mag) 1 = Microstrip 2 = Axial Ribbon 3 = Axial Wire 4 = Radial Ribbon 5 = Radial Wire E PACKAGING S = Bulk W = Waffle Pack 0201 - 0603 Y = Paper 5" Reel T = Paper 7" Reel R1 = Paper 13" Reel J1 = Paper 5" Reel - -AEC QUALIFICATION AEC-Q200 qualification 3 (optional) Horizontally Oriented Electrodes 1 N = Paper 5" Reel - Vertically Oriented Electrodes 1 L = Paper 7" Reel - Horizontally Oriented Electrodes 1 V = 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 1 MARKING 3 = Cap Code & Tolerance 4 = No Marking 6 = EIA Code (Marking option is only available Q = Embossed 5" Reel Vertically Oriented Electrodes 1 G = Embossed 7" Reel Horizontally Oriented Electrodes 1 P = Embossed 7" Reel Vertically Oriented Electrodes Tape specifications conform to EIA RS481 on 0805 and larger case sizes) 1 - Not available for all MLCC - Call factory for info. - WVDC - Working Voltage DC. 3 -Qualification required for automotive application, Not available for all series - Call factory for info. 2 www.johansontechnology.com 7 Low ESR / High-Q Capacitor Selection Chart RF Power Applications EIA Size 0201 (R05) Cap. Value NPO (R05L) NPO (R05G) 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 25 V 0402 0603 0805 0805 (R07S) (R14S) (R15S) (R15G) 1111 (S42E) 2525 (S48E) 3838 (S58E) Capacitance pF 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9 2.0 2.1 2.2 2.4 2.7 3.0 3.3 3.6 3.9 4.3 4.7 5.1 5.6 6.2 6.8 7.5 8.2 9.1 10 11 12 13 15 16 18 20 22 24 27 30 33 Code 0R1 0R2 0R3 0R4 0R5 0R6 0R7 0R8 0R9 1R0 1R1 1R2 1R3 1R4 1R5 1R6 1R7 1R8 1R9 2R0 2R1 2R2 2R4 2R7 3R0 3R3 3R6 3R9 4R3 4R7 5R1 5R6 6R2 6R8 7R5 8R2 9R1 100 110 120 130 150 160 180 200 220 240 270 300 330 A B C D A** B C D F G J K 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/250 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50/200 V 50 V 50 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V Consult factory for Non-Standard values. **A tolerance only available for R07S (0402) and R14S(0603) caps 8 www.johansontechnology.com 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V Low ESR / High-Q Capacitor Selection Chart RF Power Applications EIA Size 0201 (R05) Cap. Value Capacitance pF 36 39 43 47 51 56 62 68 75 82 91 100 110 120 130 150 160 180 200 220 240 270 300 330 360 390 430 470 510 560 620 680 750 820 910 1000 1200 1500 1800 2200 2700 3300 3900 4700 5100 10000 Code 360 390 430 470 510 560 620 680 750 820 910 101 111 121 131 151 161 181 201 221 241 271 301 331 361 391 431 471 511 561 621 681 751 821 911 102 122 152 182 222 272 332 392 472 512 103 NPO (R05L) NP0 (R05G) 0402 0603 0805 0805 (R07S) (R14S) (R15S) (R15G) 1111 (S42E) 2525 (S48E) 3838 (S58E) Tolerance F G 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V 25/50 V J K G J 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 250 V 1000V 1000V 1000V 1000V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 500V 300V 300V 300V 300V 300V 300V 300V 200V 200V 200V 200V 200V 200V 200V 200V 200V 200V 200V 200V 200V 200V 200V 200V 200V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1500V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 600V 600V 600V 600V 600V 500V 500V 500V 500V 500V 500V K 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 1500V 1500V 1500V 1500V 1500V 1500V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 1000V 500V 500V 300V 300V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 3600V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 2500V 1000V 1000V 1000V 1000V 1000V 1000V 500V 500V 500V 500V 500V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V 7200V Consult factory for Non-Standard values. www.johansontechnology.com 9 Dielectric Characteristics NPO TEMPERATURE COEFFICIENT: 0 30ppm /C, -55 to 150C QUALITY FACTOR / DF: Q >1,000 @ 1KHz (C>1,000pF), Typical 10,000 (C<1,000 pF) INSULATION RESISTANCE: >100 G @ 25C,WVDC1; 125C IR is 10% of 25C rating DIELECTRIC STRENGTH: 500 V 2.5 X WVDC1 Min., 25C, 50 mA max 1000 V 1.5 X WVDC1 Min., 25C, 50 mA max > 1500 = 1 X WVDC1 Min., 25C, 50 mA max TEST PARAMETERS:: AVAILABLE CAPACITANCE: 1MHz 50kHz, 1.00.2 VRMS, 25C Size 0201: Size 0402: Size 0603: Size 0805: Size 1111: Size 2525: Size 3838: 0.2 - 100 pF 0.2 - 33 pF 0.2 - 100 pF 0.3 - 220 pF 0.2 - 1000 pF 1.0 - 2700 pF 1.0 - 5100 pF Mechanical & Environmental Characteristics SPECIFICATION SOLDERABILITY: RESISTANCE TO SOLDERING HEAT: TERMINAL ADHESION: PCB DEFLECTION: LIFE TEST: THERMAL CYCLE: HUMIDITY, STEADY STATE: HUMIDITY, LOW VOLTAGE: VIBRATION: Solder coverage 90% of metalized areas No termination degradation No mechanical damage Capacitance change: 2.5% or 0.25pF Q>500 I.R. >10 G Ohms DWV2: 2.5 x WVDC1 Termination should not pull off. Ceramic should remain undamaged. No mechanical damage. Capacitance change: 5% or 0.5pF whichever is greater. MIL-STD-202, Method 108l No mechanical damage Capacitance change: 3.0% or 0.3 pF Q>500 I.R. >1 G Ohms DWV2: 2.5 x WVDC1 No mechanical damage. Capacitance change: 2.5% or 0.25pF Q>2000 I.R. >10 G Ohms DWV2: 2.5 x WVDC1 No mechanical damage. Capacitance change: 5.0% or 0.50pF max. Q>300 I.R. 1 G-Ohm DWV2: 2.5 x WVDC1 No mechanical damage. Capacitance change: 5.0% or 0.50pF max. Q>300 I.R. = 1 G-Ohm min. DWV2: 2.5 x WVDC1 No mechanical damage. Capacitance change: 2.5% or 0.25pF Q>1000 I.R. 10 G-Ohm DWV2: 2.5 x WVDC1 TEST PARAMETERS Preheat chip to 120-150C for 60 sec., dip terminals in rosin flux then dip in Sn62 solder @ 2405C for 51 sec Preheat device to 80-100C for 60 sec. followed by 150-180C for 60 sec. Dip in 2605C solder for 101 sec. Measure after 242 hour cooling period Linear pull force3 exerted on axial leads soldered to each terminal. Glass epoxy PCB: 2 mm deflection Applied voltage: 200% of WVDC1 for capacitors rated at 500 volts DC or less. 100% of WVDC1 for capacitors rated at 1250 volts DC or less. Temperature: 1253C Test time: 1000+48-0 hours 5 cycles of: 303 minutes @ -55+0/-3C, 2-3 min. @ 25C, 303 min. @ +125+3/-0C, 2-3 min. @ 25C Measure after 242 hour cooling period Relative humidity: 90-95% Temperature: 402C Test time: 500 +12/-0 Hours Measure after 242 hour cooling period Applied voltage: 1.5 VDC, 50 mA max. Relative humidity: 852% Temperature: 402C Test time: 240 +12/-0 Hours Measure after 242 hour cooling period Cycle performed for 2 hours in each of three perpendicular directions Frequency range 10Hz to 55 Hz to 10 Hz traversed in 1 minute. Harmonic motion amplitude: 1.5mm 1 - WVDC - Working Voltage DC. - DWV - Dielectric Withstanding Voltage. - 0402 2.0lbs, 0603 4.0lbs (min). 4 - Whichever is less. AEC-Q200: Qualification required for automotive application - Not available for all series - Call factory for info. 2 3 10 www.johansontechnology.com Mechanical Characteristics Size Units EIA 0201 Metric (0603) EIA 0402 Metric (1005) EIA 0603 Metric (1608) EIA 0805 Metric (2012) In Length .024 .001 Width Thickness End Band .012 .001 .012 .001 .008 Max. (0.60 0.03) (0.30 0.03) (0.30 0.03) (0.20 Max.) In .040 .004 .020 .004 .020 .004 .010 .006 mm (1.02 0.1) (0.51 0.1) (0.51 0.1) (0.25 .15) .062 .006 .032 .006 .030 +.005/-.003 .014 .006 mm In mm In mm (1.57 0.15) (0.81 0.15) (0.76 +.13-.08) (0.35 .15) .050 .008 .040 .006 .020 .010 (2.03 0.20) (1.27 0.20) (1.02 .15) (0.50 .25) .080 .008 Horizontal and Verticle Oriented Capacitors Horizontal Electrode Orientation Applications & Features Vertical Electrode Orientation 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. www.johansontechnology.com 11 E-Series Terminations and Leads CHIP DIMENSIONS Size Termination S42E V,T S48E U,C S58E Units L Tol W 0.110 +.020 -.010 0.110 In mm 2.79 +0.51 -0.25 2.79 0.230 +.025 -.010 0.250 In mm 5.84 +0.63 -0.25 6.35 0.380 +.015 -.010 0.380 In mm 9.65 +0.38 -0.25 9.65 Tol T E/B For all E-Series Models: Tol +/- .015 0.102 Max. 0.015 Typ. +/- 0.008 +/- 0.38 2.59 Max. 0.38 Typ. +/- 0.20 +/- .015 0.150 Max. 0.025 Typ. +/- 0.38 3.81 Max. 0.63 Typ. +/- .010 0.170 Max. 0.025 Typ. +/- 0.25 4.32 Max. 0.63 Typ. OPERATING TEMP. : INSULATION RESISTANCE: TEMPERATURE COEFFICIENT: -55 to +125C >10G @ 25C 0 30ppm /C, -55 to 125C DISSIPATION FACTOR (TYP.): < 0.05% @ 1 MHz Drawings not to scale 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), Termination Code "2" e e W L X E/B X T LL Axial Wire Leads (Non-Magnetic), Termination Code "3" LL Radial Ribbon Leads (Non-Magnetic), Termination Code "4" e LL LL LL Radial Wire Leads (Non-Magnetic), Termination Code "5" e X LL T LL LL W W LL T LL W X X LL e Lead 1 Size LL(min) X Tol e e-Tol S42E 0.25 6.40 0.394 10.0 0.748 19.00 0.25 6.40 0.394 10.00 0.748 19.00 0.25 6.40 0.394 10.00 0.748 19.00 0.093 2.36 0.217 5.5 0.35 8.90 0.093 2.36 0.217 5.50 0.35 8.90 +/-0.005 +/- 0.13 +/- 0.02 +/- 0.50 +/- 0.02 +/- 0.50 +/-0.005 +/- 0.13 +/- 0.02 +/- 0.50 +/- 0.02 +/- 0.50 0.004 0.102 0.009 0.220 0.010 0.250 0.004 0.102 0.009 0.220 0.010 0.25 +/- 0.002 +/- 0.051 - 0.0019/+ 0.0031 - 0.050/+ 0.080 - 0.0019/+ 0.0039 - 0.050/+ 0.100 +/- 0.002 +/- 0.051 - 0.0019/+ 0.0031 - 0.050/+ 0.080 - 0.0019/+ 0.0039 - 0.050/+ 0.100 S48E S58E S42E 2 S48E S58E S42E 3 S48E S58E 12 e Lead 4 Size LL(min) X Tol e e-Tol S42E 0.352 8.90 0.501 12.70 0.886 22.50 0.25 6.40 0.394 10.00 0.748 19.00 0.093 2.36 0.217 5.50 0.35 8.90 +/-0.005 +/- 0.13 +/- 0.02 +/- 0.50 +/- 0.02 +/- 0.50 0.004 0.102 0.009 0.220 0.010 0.25 +/- 0.002 +/- 0.051 - 0.0019/+ 0.0031 - 0.050/+ 0.080 - 0.0019/+ 0.0039 - 0.050/+ 0.100 S48E S58E S42E 5 S48E S58E 0.020in (0.511) diameter wire 0.020in (0.511) diameter wire www.johansontechnology.com RF Characteristics - R05L Series Resonant Frequency : 0201/R05L 0201 R05L Resonant frequency Resonant frequency (GHz) 100 SRF 0201 R05L Equivalent Series Resistance (ESR) 300 Typical values of SRF with: Series mounting Horizontal orientation 14 mil-thick FR4 substrate 250 ESR (m) 200 10 3.0 pF 10 pF 150 33 pF 100 56 pF 50 100 pF Typical values 0 1 0 1 10 500 100 1000 1500 2000 Freq (MHz) Capacitance value (pF) The Series Resonant Frequency is highly dependent on the substrate, pad dimensions, and measurement method. The above chart is for reference only. 0201 R05L Q factor 0201 R05L Max Current 10000 Q factor 1000 3.0 pF 10 pF 100 33 pF 56 pF 10 Maximum current (A rms) 3 100 pF Estimated maximum current based on Ambient temperature = 65 C Thermal resistance of DUT on substrate = 300C/W Infinite heatsink Duty cycle=100% 2.5 2 3 pF 10 pF 1.5 33 pF 1 56 pF 0.5 100 pF 0 0 1 0 500 1000 1500 500 1000 1500 2000 Freq (MHz) 2000 Freq (MHz) RF Characteristics - R07S-Series 0402 R07S Equivalent Series Resistance (ESR) 250 Typical values of SRF with: Series mounting Horizontal orientation 16 mil-thick Rogers 4003 substrate 10 200 ESR (m) Resonant frequency (GHz) 0402 R07S Series Resonant frequency 2.2 pF 150 5.6 pF 100 10 pF 15 pF 50 SRF 33 pF Typical values 0 0 1 0.1 1 10 500 1000 1500 2000 Freq (MHz) Capacitance value (pF) The Series Resonant Frequency is highly dependent on the substrate, pad dimensions, and measurement method. The above chart is for reference only. www.johansontechnology.com 13 RF Characteristics R07S Series 0402 R07S Q factor 10000 Estimated maximum current based on Ambient temperature = 65 C Thermal resistance of DUT on substrate = 120C/W Infinite heatsink Duty cycle=100% 2.2 pF 5.6 pF 100 10 pF 15 pF 10 Maximum current (A rms) 4.5 1000 Q factor 0402 R07S Max Current 5 33 pF 4 3.5 3 33 pF 2.5 15 pF 2 10 pF 1.5 5.6 pF 1 0 Typical values 1 0 500 1000 2.2 pF 0.5 1500 0 2000 500 1000 1500 2000 Freq (MHz) Freq (MHz) RF Characteristics R14S Series 0603 R14S Series Resonant frequency 0603 R14S Equivalent Series Resistance (ESR) Typical values of SRF with: Series mounting Horizontal orientation 16 mil-thick Rogers 4003 substrate 280 240 ESR (m) Resonant frequency (GHz) 100 10 200 2.0 pF 160 4.7 pF 10 pF 120 39 pF 80 SRF 75 pF 40 0 0 1 0.1 1 10 100 pF Typical values 500 1000 1500 2000 Freq (MHz) 100 Capacitance value (pF) The Series Resonant Frequency is highly dependent on the substrate, pad dimensions, and measurement method. The above chart is for reference only. 0603 R14S Q factor 10000 0603 R14S Max Current 2.0 pF 1000 Q factor 4.7 pF 10 pF 100 39 pF 75 pF 10 Typical values 1 0 500 1000 Freq (MHz) 14 100 pF Maximum current (A rms) 8 Estimated maximum current based on Ambient temperature = 65 C Thermal resistance of DUT on substrate = 60C/W Infinite heatsink Duty cycle=100% 7 6 75 pF 4 39 pF 3 10 pF 2 4.7 pF 1 2.0 pF 0 1500 2000 100 pF 5 0 500 1000 Freq (MHz) www.johansontechnology.com 1500 2000 RF Characterisitcs - R15S Series 10 0805 R15S Equivalent Series Resistance (ESR) 300 Typical values with: Series mounting Horizontal orientation 16 mil-thick Rogers 4003C substrate 0.3 pF 250 ESR (m) Resonant frequency (GHz) 0805 R15S Series Resonant frequency 2.0 pF 200 4.7 pF 150 10 pF 39 pF 100 75 pF 100 pF 50 SRF 220 pF Typical values 0 0 1 1 10 500 1000 1500 2000 Freq (MHz) 100 Capacitance value (pF) The Series Resonant Frequency is highly dependent on the substrate, pad dimensions, and measurement method. The above chart is for reference only. 0805 R15S Q factor Effective capacitance value: 0805/R15S 1000 0.3 pF 400 2.0 pF 350 Q factor 4.7 pF 10 pF 100 39 pF 75 pF 10 100 pF 220 pF Typical values 1 0 500 1000 1500 Effective Capacitance Value (pF) 10000 300 250 200 100 50 0 2000 0 Maximum current (A rms) 300 MHz 100 MHz 1 64 MHz 27 MHz 0.1 13 MHz 7 MHz 0.01 10 600 800 1000 1200 1400 1600 1800 2000 100 Estimated maximum current based on Ambient temperature = 65 C Thermal resistance of DUT on substrate = 40C/W Infinite heatsink Duty cycle=100% 10 128 MHz 1 400 0805 R15S Max Current vs. Frequency Maximum current (A rms) Estimated maximum current based on Ambient temperature = 65 C Thermal resistance of DUT on substrate = 40C/W Infinite heatsink Duty cycle=100% 0.1 200 Freq (MHz) 0805 R15S Max Current vs. Cap. Value 10 C(1 MHz) = 220 pF C(1 MHz) = 100 pF C(1 MHz) = 56 pF 150 Freq (MHz) 100 Typical values on a 16 mil RO4003C 8 220 pF 100 pF 75 pF 6 39 pF 10 pF 4 4.7 pF 2.0 pF 2 0.3 pF 0 0 500 1000 1500 2000 Freq (MHz) Capacitance value (pF) www.johansontechnology.com 15 RF Characteristics - S24E Series Typical values with: Series mounting Horizontal orientation 60 mil-thick Rogers 4350B substrate 10 1111 S42E Equivalent Series Resistance (ESR) 300 250 1.2 pF 200 ESR (m) Resonant frequency (GHz) 1111 S42E Series Resonant frequency SRF 1 4.7 pF 150 10 pF 100 33 pF 100 pF 50 0.1 0 1 10 100 300 pF Typical values 0 500 1000 1000 1500 2000 Freq (MHz) Capacitance value (pF) The Series Resonant Frequency is highly dependent on the substrate, pad dimensions, and measurement method. The above chart is for reference only. 1111 S42E Q factor 10000 Effective capacitance value: 1111/S42E S42E Q factor 1.2 pF 4.7 pF 100 10 pF 33 pF 10 100 pF 300 pF Typical values 1 0 500 1000 1500 Effective capacitance value (pF) 0.2 pF 1000 400 Typical values on a 60-mil thick Rogers 4350B substrate 350 300 250 C(1 MHz) = 300pF 200 C(1 MHz) = 100 pF 150 C(1 MHz) = 10 pF 100 50 0 0 2000 500 1000 Freq (MHz) 1111 S42E Max Current vs. Capacitance Value Estimated maximum current based on Ambient temperature = 65 C Thermal resistance of DUT on substrate = 20C/W Infinite heatsink Duty cycle=100% 100 200 MHz 100 MHz 1 40 MHz 15 MHz 0.1 7 MHz 0.01 0.1 1 10 100 Estimated maximum current based on Ambient temperature = 65 C Thermal resistance of DUT on substrate = 20C/W Infinite heatsink Duty cycle=100% 18 10 1000 16 14 300 pF 100 pF 12 33 pF 10 10 pF 8 4.7 pF 6 4 1.2 pF 2 0.2 pF 0 0 500 1000 Freq (MHz) Capacitance value (pF) 16 2000 1111 S42E Max Current vs. Frequency 20 Maximum Current (A rms) Maximum Current (A rms) 1000 1500 Freq (MHz) www.johansontechnology.com 1500 2000 RF Characteristics - S48E Series 2525 S48E Series Resonant Frequency 10 2525 S48E Equivalent Series Resistance (ESR) 140 Typical values of SRF when measured on a 8720C VNA using a shunt-through fixture 120 ESR (m) Frequency (GHz) 100 1 10 pF 80 22 pF 60 33 pF 40 130 pF 470 pF 20 SRF Typical values 0 0 0.1 1 10 100 50 100 150 200 250 300 Freq (MHz) 1000 Capacitance (pF) The Series Resonant Frequency is highly dependent on the substrate, pad dimensions, and measurement method. The above chart is for reference only. 2525 S48E Q factor 2525 S48E Max Current vs. Frequency 20 10000 Estimated maximum current based on Ambient temperature = 65 C Thermal resistance of DUT on substrate = 15C/W Infinite heatsink Duty cycle=100% 18 16 10 pF 22 pF 100 33 pF 10 14 12 470 pF 10 130 pF 8 33 pF 6 22 pF 130 pF 4 470 pF 2 10 pF 0 Typical values 1 Imax (A rms) Q factor 1000 0 0 50 100 150 200 250 300 50 100 150 200 250 300 Freq (MHz) Freq (MHz) www.johansontechnology.com 17 RF Characteristics - S58E Series 3838 S58E Series Resonant frequency 10 3838 S58E Equivalent Series Resistance (ESR) 180 Typical values of SRF when measured on a 8720C VNA using a shunt-through fixture 160 120 ESR (m) Frequency (GHz) 140 1 0.1 100 10 pF 80 47 pF 60 180 pF 40 1000 pF 20 SRF 0.01 1 Typical values 0 10 100 0 1000 50 100 150 200 250 300 Freq (MHz) Capacitance (pF) The Series Resonant Frequency is highly dependent on the substrate, pad dimensions, and measurement method. The above chart is for reference only. 3838 S58E Q factor 3838 S58E Max Current vs. Frequency Q factor 1000 10 pF 100 47 pF 180 pF 10 1000 pF 0 50 100 150 Freq (MHz) 18 Estimated maximum current based on Ambient temperature = 65 C Thermal resistance of DUT on substrate = 12C/W Infinite heatsink Duty cycle=100% 20 15 10 pF 47 pF 10 180 pF 1000 pF 5 0 Typical values 1 Maximum current (A rms) 10000 200 250 300 0 50 100 150 Freq (MHz) www.johansontechnology.com 200 250 300