X5R Dielectric General Specifications GENERAL DESCRIPTION • General Purpose Dielectric for Ceramic Capacitors • EIA Class II Dielectric • Temperature variation of capacitance is within ±15% from -55°C to +85°C • Well suited for decoupling and filtering applications • Available in High Capacitance values (up to 100µF) PART NUMBER (see page 2 for complete part number explanation) 2220 6 D 107 M A T 2 A Size (L" x W") Voltage 4 = 4V 6 = 6.3V Z = 10V Y = 16V 3 = 25V D = 35V 5 = 50V Dielectric D = X5R Capacitance Code (In pF) 2 Sig. Digits + Number of Zeros Capacitance Tolerance K = ±10% M = ±20% Failure Rate A = N/A Terminations T = Plated Ni and Sn Packaging 2 = 7" Reel 4 = 13" Reel 7 = Bulk Cass. 9 = Bulk Special Code A = Std. Temperature Coefficient 20 % Capacitance 15 10 5 0 -5 -10 -15 -20 -60 -40 -20 0 +20 +40 Temperature °C +60 +80 Insulation Resistance (Ohm-Farads) TYPICAL ELECTRICAL CHARACTERISTICS Insulation Resistance vs Temperature 10,000 1,000 100 0 0 20 40 60 80 100 120 Temperature °C 19 X5R Dielectric Specifications and Test Methods Parameter/Test Operating Temperature Range Capacitance Insulation Resistance X5R Specification Limits -55ºC to +85ºC Within specified tolerance ≤ 2.5% for ≥ 50V DC rating ≤ 3.0% for 25V DC rating ≤ 3.5% for 16V DC rating ≤ 5.0% for ≤ 10V DC rating 100,000MΩ or 500MΩ - µF, whichever is less Dielectric Strength No breakdown or visual defects Dissipation Factor Resistance to Flexure Stresses Appearance Capacitance Variation Dissipation Factor Insulation Resistance Solderability Resistance to Solder Heat Thermal Shock Load Life Load Humidity 20 Appearance Capacitance Variation Dissipation Factor Insulation Resistance Dielectric Strength Appearance Capacitance Variation Dissipation Factor Insulation Resistance Dielectric Strength Appearance Capacitance Variation Dissipation Factor Insulation Resistance Dielectric Strength Appearance Capacitance Variation Dissipation Factor Insulation Resistance Dielectric Strength No defects ≤ ±12% Measuring Conditions Temperature Cycle Chamber Freq.: 1.0 kHz ± 10% Voltage: 1.0Vrms ± .2V For Cap > 10 µF, 0.5Vrms @ 120Hz Charge device with rated voltage for 120 ± 5 secs @ room temp/humidity Charge device with 300% of rated voltage for 1-5 seconds, w/charge and discharge current limited to 50 mA (max) Deflection: 2mm Test Time: 30 seconds 1mm/sec Meets Initial Values (As Above) ≥ Initial Value x 0.3 ≥ 95% of each terminal should be covered with fresh solder No defects, <25% leaching of either end terminal 90 mm Dip device in eutectic solder at 230 ± 5ºC for 5.0 ± 0.5 seconds ≤ ±7.5% Meets Initial Values (As Above) Dip device in eutectic solder at 260ºC for 60 seconds. Store at room temperature for 24 ± 2 hours before measuring electrical properties. Meets Initial Values (As Above) Meets Initial Values (As Above) No visual defects Step 1: -55ºC ± 2º 30 ± 3 minutes ≤ ±7.5% Step 2: Room Temp ≤ 3 minutes Meets Initial Values (As Above) Step 3: +85ºC ± 2º 30 ± 3 minutes Meets Initial Values (As Above) Step 4: Room Temp ≤ 3 minutes Meets Initial Values (As Above) Repeat for 5 cycles and measure after 24 ± 2 hours at room temperature No visual defects ≤ ±12.5% ≤ Initial Value x 2.0 (See Above) ≥ Initial Value x 0.3 (See Above) Meets Initial Values (As Above) No visual defects ≤ ±12.5% ≤ Initial Value x 2.0 (See Above) ≥ Initial Value x 0.3 (See Above) Meets Initial Values (As Above) Charge device with 1.5X rated voltage in test chamber set at 85ºC ± 2ºC for 1000 hours (+48, -0). Note: Contact factory for specific high CV devices that are tested at 1.5X rated voltage. Remove from test chamber and stabilize at room temperature for 24 ± 2 hours before measuring. Store in a test chamber set at 85ºC ± 2ºC/ 85% ± 5% relative humidity for 1000 hours (+48, -0) with rated voltage applied. Remove from chamber and stabilize at room temperature and humidity for 24 ± 2 hours before measuring. X5R Dielectric Capacitance Range PREFERRED SIZES ARE SHADED SIZE 0201 0402 0603 0805 Soldering Packaging Reflow Only All Paper Reflow Only All Paper Reflow Only All Paper Reflow/Wave Paper/Embossed 1.60 ± 0.15 (0.063 ± 0.006) 0.81 ± 0.15 (0.032 ± 0.006) 0.35 ± 0.15 (0.014 ± 0.006) 10 16 2.01 ± 0.20 (0.079 ± 0.008) 1.25 ± 0.20 (0.049 ± 0.008) 0.50 ± 0.25 (0.020 ± 0.010) 16 25 A 0.33 (0.013) 4 6.3 25 35 6.3 10 35 L W 50 25 A A C C C C C C C C C C T C C C C C C G G G G G G G G G G G G G G G G G t G G G G N N N N N N N N N N N N N N N N N N 10 SIZE Letter Max. Thickness 4 A A A A A 25 A A A A A A A Cap (µF 10 Cap (pF) 1.00 ± 0.10 (0.040 ± 0.004) 0.50 ± 0.10 (0.020 ± 0.004) 0.25 ± 0.15 (0.010 ± 0.006) 6.3 10 16 (t) Terminal 0.60 ± 0.03 (0.024 ± 0.001) 0.30 ± 0.03 (0.011 ± 0.001) 0.15 ± 0.05 (0.006 ± 0.002) 16 (W) Width MM (in.) MM (in.) MM (in.) WVDC 100 150 220 330 470 680 1000 1500 2200 3300 4700 6800 0.010 0.015 0.022 0.033 0.047 0.068 0.10 0.15 0.22 0.33 0.47 0.68 1.0 1.5 2.2 3.3 4.7 6.8 10 22 47 100 WVDC (L) Length 16 25 4 6.3 0201 C 0.56 (0.022) E 0.71 (0.028) PAPER 10 16 25 4 0402 G 0.86 (0.034) J 0.94 (0.037) K 1.02 (0.040) 6.3 10 16 25 35 6.3 10 16 0603 M 1.27 (0.050) N 1.40 (0.055) P Q 1.52 1.78 (0.060) (0.070) EMBOSSED 25 35 50 0805 X 2.29 (0.090) Y 2.54 (0.100) Z 2.79 (0.110) 21 X5R Dielectric Capacitance Range PREFERRED SIZES ARE SHADED 1206 1210 1812 Reflow/Wave Paper/Embossed Reflow Only Paper/Embossed Reflow Only All Embossed 3.20 ± 0.20 (0.126 ± 0.008) 1.60 ± 0.20 (0.063 ± 0.008) 0.50 ± 0.25 (0.020 ± 0.010) 16 3.20 ± 0.20 (0.126 ± 0.008) 2.50 ± 0.20 (0.098 ± 0.008) 0.50 ± 0.25 (0.020 ± 0.010) 16 4.50 ± 0.30 (0.177 ± 0.012) 3.20 ± 0.20 (0.126 ± 0.008) 0.61 ± 0.36 (0.024 ± 0.014) 10 10 6.3 10 35 6.3 25 L W t M Q Q Q 6.3 Q Q Q Q Q Q Q 10 16 N X Z 25 Z Z Z 6.3 35 C 0.56 (0.022) E 0.71 (0.028) PAPER G 0.86 (0.034) Z Z Z Z Z Z 10 1206 A 0.33 (0.013) 25 22 35 SIZE Letter Max. Thickness 25 Cap (µF 6.3 Cap (pF) (t) Terminal (W) Width MM (in.) MM (in.) MM (in.) WVDC 100 150 220 330 470 680 1000 1500 2200 3300 4700 6800 0.010 0.015 0.022 0.033 0.047 0.068 0.10 0.15 0.22 0.33 0.47 0.68 1.0 1.5 2.2 3.3 4.7 6.8 10 22 47 100 WVDC (L) Length SIZE Soldering Packaging 16 25 35 6.3 10 1210 J 0.94 (0.037) K 1.02 (0.040) M 1.27 (0.050) N 1.40 (0.055) 1812 P Q 1.52 1.78 (0.060) (0.070) EMBOSSED X 2.29 (0.090) Y 2.54 (0.100) Z 2.79 (0.110) 25 T Packaging of Chip Components Automatic Insertion Packaging TAPE & REEL QUANTITIES All tape and reel specifications are in compliance with RS481. 8mm Paper or Embossed Carrier 12mm 0612, 0508, 0805, 1206, 1210 Embossed Only 1812, 1825 2220, 2225 1808 Paper Only 0201, 0306, 0402, 0603 Qty. per Reel/7" Reel 2,000, 3,000 or 4,000, 10,000, 15,000 3,000 500, 1,000 Contact factory for exact quantity Qty. per Reel/13" Reel Contact factory for exact quantity 5,000, 10,000, 50,000 10,000 4,000 Contact factory for exact quantity REEL DIMENSIONS Tape Size(1) A Max. B* Min. C D* Min. N Min. 8mm 330 (12.992) 1.5 (0.059) 13.0 +0.50 -0.20 -0.008 ) (0.512 +0.020 20.2 (0.795) W3 -0.0 8.40 +1.5 (0.331 +0.059 -0.0 ) 14.4 (0.567) 7.90 Min. (0.311) 10.9 Max. (0.429) -0.0 12.4 +2.0 -0.0 (0.488 +0.079 ) 18.4 (0.724) 11.9 Min. (0.469) 15.4 Max. (0.607) 50.0 (1.969) 12mm Metric dimensions will govern. English measurements rounded and for reference only. (1) For tape sizes 16mm and 24mm (used with chip size 3640) consult EIA RS-481 latest revision. 60 W2 Max. W1 Embossed Carrier Configuration 8 & 12mm Tape Only 10 PITCHES CUMULATIVE TOLERANCE ON TAPE ±0.2mm (±0.008) EMBOSSMENT P0 T2 T D0 P2 DEFORMATION BETWEEN EMBOSSMENTS Chip Orientation E1 A0 F TOP COVER TAPE B1 T1 W B0 K0 S1 E2 P1 MAX. CAVITY SIZE - SEE NOTE 1 CENTER LINES OF CAVITY B1 IS FOR TAPE READER REFERENCE ONLY INCLUDING DRAFT CONCENTRIC AROUND B0 D1 FOR COMPONENTS 2.00 mm x 1.20 mm AND LARGER (0.079 x 0.047) User Direction of Feed 8 & 12mm Embossed Tape Metric Dimensions Will Govern CONSTANT DIMENSIONS Tape Size 8mm and 12mm D0 1.50 (0.059 E +0.10 -0.0 +0.004 -0.0 ) P0 P2 1.75 ± 0.10 4.0 ± 0.10 2.0 ± 0.05 (0.069 ± 0.004) (0.157 ± 0.004) (0.079 ± 0.002) S1 Min. T Max. T1 0.60 (0.024) 0.60 (0.024) 0.10 (0.004) Max. VARIABLE DIMENSIONS Tape Size B1 Max. D1 Min. E2 Min. F P1 See Note 5 R Min. See Note 2 T2 W Max. A0 B0 K0 8mm 4.35 (0.171) 1.00 (0.039) 6.25 (0.246) 3.50 ± 0.05 4.00 ± 0.10 (0.138 ± 0.002) (0.157 ± 0.004) 25.0 (0.984) 2.50 Max. (0.098) 8.30 (0.327) See Note 1 12mm 8.20 (0.323) 1.50 (0.059) 10.25 (0.404) 5.50 ± 0.05 4.00 ± 0.10 (0.217 ± 0.002) (0.157 ± 0.004) 30.0 (1.181) 6.50 Max. (0.256) 12.3 (0.484) See Note 1 8mm 1/2 Pitch 4.35 (0.171) 1.00 (0.039) 6.25 (0.246) 3.50 ± 0.05 2.00 ± 0.10 (0.138 ± 0.002) (0.079 ± 0.004) 25.0 (0.984) 2.50 Max. (0.098) 8.30 (0.327) See Note 1 12mm Double Pitch 8.20 (0.323) 1.50 (0.059) 10.25 (0.404) 5.50 ± 0.05 8.00 ± 0.10 (0.217 ± 0.002) (0.315 ± 0.004) 30.0 (1.181) 6.50 Max. (0.256) 12.3 (0.484) See Note 1 NOTES: 1. The cavity defined by A0, B0, and K0 shall be configured to provide the following: Surround the component with sufficient clearance such that: a) the component does not protrude beyond the sealing plane of the cover tape. b) the component can be removed from the cavity in a vertical direction without mechanical restriction, after the cover tape has been removed. c) rotation of the component is limited to 20º maximum (see Sketches D & E). d) lateral movement of the component is restricted to 0.5mm maximum (see Sketch F). 2. Tape with or without components shall pass around radius “R” without damage. 3. Bar code labeling (if required) shall be on the side of the reel opposite the round sprocket holes. Refer to EIA-556. 4. B1 dimension is a reference dimension for tape feeder clearance only. 5. If P1 = 2.0mm, the tape may not properly index in all tape feeders. Top View, Sketch "F" Component Lateral Movements 0.50mm (0.020) Maximum 0.50mm (0.020) Maximum 61 Paper Carrier Configuration 8 & 12mm Tape Only 10 PITCHES CUMULATIVE TOLERANCE ON TAPE ±0.20mm (±0.008) P0 D0 T P2 E1 BOTTOM COVER TAPE TOP COVER TAPE F W E2 B0 G T1 T1 A0 CENTER LINES OF CAVITY CAVITY SIZE SEE NOTE 1 P1 User Direction of Feed 8 & 12mm Paper Tape Metric Dimensions Will Govern CONSTANT DIMENSIONS Tape Size 8mm and 12mm D0 1.50 (0.059 +0.10 -0.0 +0.004 -0.0 E ) P0 P2 1.75 ± 0.10 4.00 ± 0.10 2.00 ± 0.05 (0.069 ± 0.004) (0.157 ± 0.004) (0.079 ± 0.002) T1 G. Min. R Min. 0.10 (0.004) Max. 0.75 (0.030) Min. 25.0 (0.984) See Note 2 Min. VARIABLE DIMENSIONS P1 See Note 4 E2 Min. F W A0 B0 4.00 ± 0.10 (0.157 ± 0.004) 6.25 (0.246) 3.50 ± 0.05 (0.138 ± 0.002) 8.00 +0.30 -0.10 -0.004 ) (0.315 +0.012 See Note 1 12mm 4.00 ± 0.010 (0.157 ± 0.004) 10.25 (0.404) 5.50 ± 0.05 (0.217 ± 0.002) 12.0 ± 0.30 (0.472 ± 0.012) 8mm 1/2 Pitch 2.00 ± 0.05 (0.079 ± 0.002) 6.25 (0.246) 3.50 ± 0.05 (0.138 ± 0.002) -0.10 8.00 +0.30 (0.315 +0.012 -0.004 ) 12mm Double Pitch 8.00 ± 0.10 (0.315 ± 0.004) 10.25 (0.404) 5.50 ± 0.05 (0.217 ± 0.002) 12.0 ± 0.30 (0.472 ± 0.012) Tape Size 8mm NOTES: 1. The cavity defined by A0, B0, and T shall be configured to provide sufficient clearance surrounding the component so that: a) the component does not protrude beyond either surface of the carrier tape; b) the component can be removed from the cavity in a vertical direction without mechanical restriction after the top cover tape has been removed; c) rotation of the component is limited to 20º maximum (see Sketches A & B); d) lateral movement of the component is restricted to 0.5mm maximum (see Sketch C). 1.10mm (0.043) Max. for Paper Base Tape and 1.60mm (0.063) Max. for Non-Paper Base Compositions 2. Tape with or without components shall pass around radius “R” without damage. 3. Bar code labeling (if required) shall be on the side of the reel opposite the sprocket holes. Refer to EIA-556. 4. If P1 = 2.0mm, the tape may not properly index in all tape feeders. Top View, Sketch "C" Component Lateral 0.50mm (0.020) Maximum 0.50mm (0.020) Maximum Bar Code Labeling Standard AVX bar code labeling is available and follows latest version of EIA-556 62 T Bulk Case Packaging BENEFITS BULK FEEDER • Easier handling • Smaller packaging volume (1/20 of T/R packaging) • Easier inventory control Case • Flexibility • Recyclable Cassette Gate Shooter CASE DIMENSIONS Shutter Slider 12mm 36mm Mounter Head Expanded Drawing 110mm Chips Attachment Base CASE QUANTITIES Part Size Qty. (pcs / cassette) 0402 80,000 0603 15,000 0805 10,000 (T=.023") 8,000 (T=.031") 6,000 (T=.043") 1206 5,000 (T=.023") 4,000 (T=.032") 3,000 (T=.044") 63 Basic Capacitor Formulas XI. Equivalent Series Resistance (ohms) E.S.R. = (D.F.) (Xc) = (D.F.) / (2 π fC) I. Capacitance (farads) English: C = .224 K A TD .0884 KA Metric: C = TD XII. Power Loss (watts) Power Loss = (2 π fCV2) (D.F.) XIII. KVA (Kilowatts) KVA = 2 π fCV2 x 10 -3 II. Energy stored in capacitors (Joules, watt - sec) E = 1⁄2 CV2 XIV. Temperature Characteristic (ppm/°C) T.C. = Ct – C25 x 106 C25 (Tt – 25) III. Linear charge of a capacitor (Amperes) dV I=C dt XV. Cap Drift (%) C1 – C2 C.D. = C1 IV. Total Impedance of a capacitor (ohms) Z = R2S + (XC - XL )2 V. Capacitive Reactance (ohms) 1 xc = 2 π fC XVI. Reliability of Ceramic Capacitors Vt L0 X Tt Y = Lt Vo To ( ) ( ) VI. Inductive Reactance (ohms) xL = 2 π fL XVII. Capacitors in Series (current the same) Any Number: 1 = 1 + 1 --- 1 CT C1 C2 CN C1 C2 Two: CT = C1 + C2 VII. Phase Angles: Ideal Capacitors: Current leads voltage 90° Ideal Inductors: Current lags voltage 90° Ideal Resistors: Current in phase with voltage XVIII. Capacitors in Parallel (voltage the same) CT = C1 + C2 --- + CN VIII. Dissipation Factor (%) D.F.= tan (loss angle) = E.S.R. = (2 πfC) (E.S.R.) Xc IX. Power Factor (%) P.F. = Sine (loss angle) = Cos (phase angle) f P.F. = (when less than 10%) = DF XIX. Aging Rate A.R. = % D C/decade of time XX. Decibels db = 20 log V1 V2 X. Quality Factor (dimensionless) Q = Cotan (loss angle) = 1 D.F. METRIC PREFIXES Pico Nano Micro Milli Deci Deca Kilo Mega Giga Tera 64 X 10-12 X 10-9 X 10-6 X 10-3 X 10-1 X 10+1 X 10+3 X 10+6 X 10+9 X 10+12 x 100 SYMBOLS K = Dielectric Constant f = frequency Lt = Test life A = Area L = Inductance Vt = Test voltage TD = Dielectric thickness = Loss angle Vo = Operating voltage V = Voltage f = Phase angle Tt = Test temperature t = time X&Y = exponent effect of voltage and temp. To = Operating temperature Rs = Series Resistance Lo = Operating life General Description Basic Construction – A multilayer ceramic (MLC) capacitor is a monolithic block of ceramic containing two sets of offset, interleaved planar electrodes that extend to two opposite surfaces of the ceramic dielectric. This simple Ceramic Layer structure requires a considerable amount of sophistication, both in material and manufacture, to produce it in the quality and quantities needed in today’s electronic equipment. Electrode End Terminations Terminated Edge Terminated Edge Margin Electrodes Multilayer Ceramic Capacitor Figure 1 Formulations – Multilayer ceramic capacitors are available in both Class 1 and Class 2 formulations. Temperature compensating formulation are Class 1 and temperature stable and general application formulations are classified as Class 2. Class 1 – Class 1 capacitors or temperature compensating capacitors are usually made from mixtures of titanates where barium titanate is normally not a major part of the mix. They have predictable temperature coefficients and in general, do not have an aging characteristic. Thus they are the most stable capacitor available. The most popular Class 1 multilayer ceramic capacitors are C0G (NP0) temperature compensating capacitors (negative-positive 0 ppm/°C). Class 2 – EIA Class 2 capacitors typically are based on the chemistry of barium titanate and provide a wide range of capacitance values and temperature stability. The most commonly used Class 2 dielectrics are X7R and Y5V. The X7R provides intermediate capacitance values which vary only ±15% over the temperature range of -55°C to 125°C. It finds applications where stability over a wide temperature range is required. The Y5V provides the highest capacitance values and is used in applications where limited temperature changes are expected. The capacitance value for Y5V can vary from 22% to -82% over the -30°C to 85°C temperature range. All Class 2 capacitors vary in capacitance value under the influence of temperature, operating voltage (both AC and DC), and frequency. For additional information on performance changes with operating conditions, consult AVX’s software, SpiCap. 65 General Description EIA CODE Percent Capacity Change Over Temperature Range RS198 Temperature Range X7 X6 X5 Y5 Z5 -55°C to +125°C -55°C to +105°C -55°C to +85°C -30°C to +85°C +10°C to +85°C Code Percent Capacity Change D E F P R S T U V ±3.3% ±4.7% ±7.5% ±10% ±15% ±22% +22%, -33% +22%, - 56% +22%, -82% Effects of Voltage – Variations in voltage have little effect on Class 1 dielectric but does affect the capacitance and dissipation factor of Class 2 dielectrics. The application of DC voltage reduces both the capacitance and dissipation factor while the application of an AC voltage within a reasonable range tends to increase both capacitance and dissipation factor readings. If a high enough AC voltage is applied, eventually it will reduce capacitance just as a DC voltage will. Figure 2 shows the effects of AC voltage. Cap. Change vs. A.C. Volts X7R Capacitance Change Percent Table 1: EIA and MIL Temperature Stable and General Application Codes 50 40 30 20 10 0 12.5 EXAMPLE – A capacitor is desired with the capacitance value at 25°C to increase no more than 7.5% or decrease no more than 7.5% from -30°C to +85°C. EIA Code will be Y5F. Symbol Temperature Range A B C -55°C to +85°C -55°C to +125°C -55°C to +150°C Symbol R S W X Y Z Cap. Change Zero Volts Cap. Change Rated Volts +15%, -15% +22%, -22% +22%, -56% +15%, -15% +30%, -70% +20%, -20% +15%, -40% +22%, -56% +22%, -66% +15%, -25% +30%, -80% +20%, -30% Temperature characteristic is specified by combining range and change symbols, for example BR or AW. Specification slash sheets indicate the characteristic applicable to a given style of capacitor. 50 Figure 2 Capacitor specifications specify the AC voltage at which to measure (normally 0.5 or 1 VAC) and application of the wrong voltage can cause spurious readings. Figure 3 gives the voltage coefficient of dissipation factor for various AC voltages at 1 kilohertz. Applications of different frequencies will affect the percentage changes versus voltages. D.F. vs. A.C. Measurement Volts X7R 10.0 Dissipation Factor Percent MIL CODE 25 37.5 Volts AC at 1.0 KHz Curve 1 - 100 VDC Rated Capacitor 8.0 Curve 2 - 50 VDC Rated Capacitor Curve 3 - 25 VDC Rated Capacitor 6.0 Curve 3 Curve 2 4.0 Curve 1 2.0 0 .5 In specifying capacitance change with temperature for Class 2 materials, EIA expresses the capacitance change over an operating temperature range by a 3 symbol code. The first symbol represents the cold temperature end of the temperature range, the second represents the upper limit of the operating temperature range and the third symbol represents the capacitance change allowed over the operating temperature range. Table 1 provides a detailed explanation of the EIA system. 66 1.0 1.5 2.0 2.5 AC Measurement Volts at 1.0 KHz Figure 3 Typical effect of the application of DC voltage is shown in Figure 4. The voltage coefficient is more pronounced for higher K dielectrics. These figures are shown for room temperature conditions. The combination characteristic known as voltage temperature limits which shows the effects of rated voltage over the operating temperature range is shown in Figure 5 for the military BX characteristic. General Description tends to de-age capacitors and is why re-reading of capacitance after 12 or 24 hours is allowed in military specifications after dielectric strength tests have been performed. 2.5 Typical Curve of Aging Rate X7R 0 -2.5 +1.5 -5 0 -7.5 -10 25% 50% 75% Percent Rated Volts 100% Figure 4 Capacitance Change Percent Typical Cap. Change vs. Temperature X7R Capacitance Change Percent Capacitance Change Percent Typical Cap. Change vs. D.C. Volts X7R -1.5 -3.0 -4.5 -6.0 -7.5 +20 1 10 100 +10 0VDC 0 -10 Max. Aging Rate %/Decade None 2 7 Figure 6 -20 -30 -55 -35 Characteristic C0G (NP0) X7R, X5R Y5V 1000 10,000 100,000 Hours -15 +5 +25 +45 +65 +85 +105 +125 Temperature Degrees Centigrade Figure 5 Effects of Time – Class 2 ceramic capacitors change capacitance and dissipation factor with time as well as temperature, voltage and frequency. This change with time is known as aging. Aging is caused by a gradual re-alignment of the crystalline structure of the ceramic and produces an exponential loss in capacitance and decrease in dissipation factor versus time. A typical curve of aging rate for semistable ceramics is shown in Figure 6. If a Class 2 ceramic capacitor that has been sitting on the shelf for a period of time, is heated above its curie point, (125°C for 4 hours or 150°C for 1⁄2 hour will suffice) the part will de-age and return to its initial capacitance and dissipation factor readings. Because the capacitance changes rapidly, immediately after de-aging, the basic capacitance measurements are normally referred to a time period sometime after the de-aging process. Various manufacturers use different time bases but the most popular one is one day or twenty-four hours after “last heat.” Change in the aging curve can be caused by the application of voltage and other stresses. The possible changes in capacitance due to de-aging by heating the unit explain why capacitance changes are allowed after test, such as temperature cycling, moisture resistance, etc., in MIL specs. The application of high voltages such as dielectric withstanding voltages also Effects of Frequency – Frequency affects capacitance and impedance characteristics of capacitors. This effect is much more pronounced in high dielectric constant ceramic formulation than in low K formulations. AVX’s SpiCap software generates impedance, ESR, series inductance, series resonant frequency and capacitance all as functions of frequency, temperature and DC bias for standard chip sizes and styles. It is available free from AVX and can be downloaded for free from AVX website: www.avx.com. 67 General Description Effects of Mechanical Stress – High “K” dielectric ceramic capacitors exhibit some low level piezoelectric reactions under mechanical stress. As a general statement, the piezoelectric output is higher, the higher the dielectric constant of the ceramic. It is desirable to investigate this effect before using high “K” dielectrics as coupling capacitors in extremely low level applications. Reliability – Historically ceramic capacitors have been one of the most reliable types of capacitors in use today. The approximate formula for the reliability of a ceramic capacitor is: Lo = Lt Vt Vo where Lo = operating life Lt = test life Vt = test voltage Vo = operating voltage X Tt To Y Tt = test temperature and To = operating temperature in °C X,Y = see text Historically for ceramic capacitors exponent X has been considered as 3. The exponent Y for temperature effects typically tends to run about 8. A capacitor is a component which is capable of storing electrical energy. It consists of two conductive plates (electrodes) separated by insulating material which is called the dielectric. A typical formula for determining capacitance is: C = .224 KA t C = capacitance (picofarads) K = dielectric constant (Vacuum = 1) A = area in square inches t = separation between the plates in inches (thickness of dielectric) .224 = conversion constant (.0884 for metric system in cm) Capacitance – The standard unit of capacitance is the farad. A capacitor has a capacitance of 1 farad when 1 coulomb charges it to 1 volt. One farad is a very large unit and most capacitors have values in the micro (10-6), nano (10-9) or pico (10-12) farad level. Dielectric Constant – In the formula for capacitance given above the dielectric constant of a vacuum is arbitrarily chosen as the number 1. Dielectric constants of other materials are then compared to the dielectric constant of a vacuum. Dielectric Thickness – Capacitance is indirectly proportional to the separation between electrodes. Lower voltage requirements mean thinner dielectrics and greater capacitance per volume. Area – Capacitance is directly proportional to the area of the electrodes. Since the other variables in the equation are usually set by the performance desired, area is the easiest parameter to modify to obtain a specific capacitance within a material group. 68 Energy Stored – The energy which can be stored in a capacitor is given by the formula: E = 1⁄2CV2 E = energy in joules (watts-sec) V = applied voltage C = capacitance in farads Potential Change – A capacitor is a reactive component which reacts against a change in potential across it. This is shown by the equation for the linear charge of a capacitor: I ideal = C dV dt where I = Current C = Capacitance dV/dt = Slope of voltage transition across capacitor Thus an infinite current would be required to instantly change the potential across a capacitor. The amount of current a capacitor can “sink” is determined by the above equation. Equivalent Circuit – A capacitor, as a practical device, exhibits not only capacitance but also resistance and inductance. A simplified schematic for the equivalent circuit is: C = Capacitance L = Inductance Rp = Parallel Resistance Rs = Series Resistance RP L RS C Reactance – Since the insulation resistance (Rp) is normally very high, the total impedance of a capacitor is: Z= where R 2S + (XC - XL )2 Z = Total Impedance Rs = Series Resistance XC = Capacitive Reactance = XL = Inductive Reactance 1 2 π fC = 2 π fL The variation of a capacitor’s impedance with frequency determines its effectiveness in many applications. Phase Angle – Power Factor and Dissipation Factor are often confused since they are both measures of the loss in a capacitor under AC application and are often almost identical in value. In a “perfect” capacitor the current in the capacitor will lead the voltage by 90°. General Description di I (Ideal) I (Actual) Loss Angle Phase Angle f V IR s In practice the current leads the voltage by some other phase angle due to the series resistance RS. The complement of this angle is called the loss angle and: Power Factor (P.F.) = Cos f or Sine Dissipation Factor (D.F.) = tan for small values of the tan and sine are essentially equal which has led to the common interchangeability of the two terms in the industry. Equivalent Series Resistance – The term E.S.R. or Equivalent Series Resistance combines all losses both series and parallel in a capacitor at a given frequency so that the equivalent circuit is reduced to a simple R-C series connection. E.S.R. C Dissipation Factor – The DF/PF of a capacitor tells what percent of the apparent power input will turn to heat in the capacitor. Dissipation Factor = E.S.R. = (2 π fC) (E.S.R.) XC The watts loss are: Watts loss = (2 π fCV2 ) (D.F.) The dt seen in current microprocessors can be as high as 0.3 A/ns, and up to 10A/ns. At 0.3 A/ns, 100pH of parasitic inductance can cause a voltage spike of 30mV. While this does not sound very drastic, with the Vcc for microprocessors decreasing at the current rate, this can be a fairly large percentage. Another important, often overlooked, reason for knowing the parasitic inductance is the calculation of the resonant frequency. This can be important for high frequency, bypass capacitors, as the resonant point will give the most signal attenuation. The resonant frequency is calculated from the simple equation: 1 fres = 2 LC Insulation Resistance – Insulation Resistance is the resistance measured across the terminals of a capacitor and consists principally of the parallel resistance R P shown in the equivalent circuit. As capacitance values and hence the area of dielectric increases, the I.R. decreases and hence the product (C x IR or RC) is often specified in ohm faradsor more commonly megohm-microfarads. Leakage current is determined by dividing the rated voltage by IR (Ohm’s Law). Dielectric Strength – Dielectric Strength is an expression of the ability of a material to withstand an electrical stress. Although dielectric strength is ordinarily expressed in volts, it is actually dependent on the thickness of the dielectric and thus is also more generically a function of volts/mil. Dielectric Absorption – A capacitor does not discharge instantaneously upon application of a short circuit, but drains gradually after the capacitance proper has been discharged. It is common practice to measure the dielectric absorption by determining the “reappearing voltage” which appears across a capacitor at some point in time after it has been fully discharged under short circuit conditions. Corona – Corona is the ionization of air or other vapors which causes them to conduct current. It is especially prevalent in high voltage units but can occur with low voltages as well where high voltage gradients occur. The energy discharged degrades the performance of the capacitor and can in time cause catastrophic failures. Very low values of dissipation factor are expressed as their reciprocal for convenience. These are called the “Q” or Quality factor of capacitors. Parasitic Inductance – The parasitic inductance of capacitors is becoming more and more important in the decoupling of today’s high speed digital systems. The relationship between the inductance and the ripple voltage induced on the DC voltage line can be seen from the simple inductance equation: V = L di dt 69 Surface Mounting Guide MLC Chip Capacitors REFLOW SOLDERING D2 D1 D3 D4 D5 Dimensions in millimeters (inches) Case Size 0402 0603 0805 1206 1210 1808 1812 1825 2220 2225 D1 D2 D3 D4 D5 1.70 (0.07) 2.30 (0.09) 3.00 (0.12) 4.00 (0.16) 4.00 (0.16) 5.60 (0.22) 5.60 (0.22) 5.60 (0.22) 6.60 (0.26) 6.60 (0.26) 0.60 (0.02) 0.80 (0.03) 1.00 (0.04) 1.00 (0.04) 1.00 (0.04) 1.00 (0.04) 1.00 (0.04)) 1.00 (0.04) 1.00 (0.04) 1.00 (0.04) 0.50 (0.02) 0.70 (0.03) 1.00 (0.04) 2.00 (0.09) 2.00 (0.09) 3.60 (0.14) 3.60 (0.14) 3.60 (0.14) 4.60 (0.18) 4.60 (0.18) 0.60 (0.02) 0.80 (0.03) 1.00 (0.04) 1.00 (0.04) 1.00 (0.04) 1.00 (0.04) 1.00 (0.04) 1.00 (0.04) 1.00 (0.04) 1.00 (0.04) 0.50 (0.02) 0.75 (0.03) 1.25 (0.05) 1.60 (0.06) 2.50 (0.10) 2.00 (0.08) 3.00 (0.12) 6.35 (0.25) 5.00 (0.20) 6.35 (0.25) Component Pad Design Component pads should be designed to achieve good solder filets and minimize component movement during reflow soldering. Pad designs are given below for the most common sizes of multilayer ceramic capacitors for both wave and reflow soldering. The basis of these designs is: • Pad width equal to component width. It is permissible to decrease this to as low as 85% of component width but it is not advisable to go below this. • Pad overlap 0.5mm beneath component. • Pad extension 0.5mm beyond components for reflow and 1.0mm for wave soldering. WAVE SOLDERING D2 D1 Case Size 0603 0805 1206 D3 D4 D1 D2 D3 D4 D5 3.10 (0.12) 4.00 (0.15) 5.00 (0.19) 1.20 (0.05) 1.50 (0.06) 1.50 (0.06) 0.70 (0.03) 1.00 (0.04) 2.00 (0.09) 1.20 (0.05) 1.50 (0.06) 1.50 (0.06) 0.75 (0.03) 1.25 (0.05) 1.60 (0.06) Dimensions in millimeters (inches) D5 Component Spacing Preheat & Soldering For wave soldering components, must be spaced sufficiently far apart to avoid bridging or shadowing (inability of solder to penetrate properly into small spaces). This is less important for reflow soldering but sufficient space must be allowed to enable rework should it be required. The rate of preheat should not exceed 4°C/second to prevent thermal shock. A better maximum figure is about 2°C/second. For capacitors size 1206 and below, with a maximum thickness of 1.25mm, it is generally permissible to allow a temperature differential from preheat to soldering of 150°C. In all other cases this differential should not exceed 100°C. For further specific application or process advice, please consult AVX. Cleaning ≥1.5mm (0.06) ≥1mm (0.04) ≥1mm (0.04) 70 Care should be taken to ensure that the capacitors are thoroughly cleaned of flux residues especially the space beneath the capacitor. Such residues may otherwise become conductive and effectively offer a low resistance bypass to the capacitor. Ultrasonic cleaning is permissible, the recommended conditions being 8 Watts/litre at 20-45 kHz, with a process cycle of 2 minutes vapor rinse, 2 minutes immersion in the ultrasonic solvent bath and finally 2 minutes vapor rinse. Surface Mounting Guide MLC Chip Capacitors APPLICATION NOTES Wave 300 Storage Preheat Good solderability is maintained for at least twelve months, provided the components are stored in their “as received” packaging at less than 40°C and 70% RH. Terminations to be well soldered after immersion in a 60/40 tin/lead solder bath at 235 ± 5°C for 2 ± 1 seconds. Leaching Solder Temp. Solderability Terminations will resist leaching for at least the immersion times and conditions shown below. Termination Type Nickel Barrier Solder Solder Tin/Lead/Silver Temp. °C 60/40/0 260 ± 5 Natural Cooling 250 200 T 230°C to 250°C 150 100 50 Immersion Time Seconds 30 ± 1 0 1 to 2 min 3 sec. max (Preheat chips before soldering) T/maximum 150°C Recommended Soldering Profiles Lead-Free Wave Soldering The recommended peak temperature for lead-free wave soldering is 250°C-260°C for 3-5 seconds. The other parameters of the profile remains the same as above. The following should be noted by customers changing from lead based systems to the new lead free pastes. a) The visual standards used for evaluation of solder joints will need to be modified as lead free joints are not as bright as with tin-lead pastes and the fillet may not be as large. b) Resin color may darken slightly due to the increase in temperature required for the new pastes. c) Lead-free solder pastes do not allow the same self alignment as lead containing systems. Standard mounting pads are acceptable, but machine set up may need to be modified. Reflow 300 Natural Cooling Preheat Solder Temp. 250 200 220°C to 250°C 150 100 50 0 1min 10 sec. max 1min General (Minimize soldering time) Surface mounting chip multilayer ceramic capacitors are designed for soldering to printed circuit boards or other substrates. The construction of the components is such that they will withstand the time/temperature profiles used in both wave and reflow soldering methods. Temperature °C Lead-Free Reflow Profile 300 250 200 150 100 50 0 0 Handling 50 100 150 • Pre-heating: 150°C ±15°C / 60-90s • Max. Peak Gradient 2.5°C/s • Peak Temperature: 245°C ±5°C • Time at >230°C: 40s Max. 200 250 Time (s) 300 Chip multilayer ceramic capacitors should be handled with care to avoid damage or contamination from perspiration and skin oils. The use of tweezers or vacuum pick ups is strongly recommended for individual components. Bulk handling should ensure that abrasion and mechanical shock are minimized. Taped and reeled components provides the ideal medium for direct presentation to the placement machine. Any mechanical shock should be minimized during handling chip multilayer ceramic capacitors. Preheat It is important to avoid the possibility of thermal shock during soldering and carefully controlled preheat is therefore required. The rate of preheat should not exceed 4°C/second 71 Surface Mounting Guide MLC Chip Capacitors and a target figure 2°C/second is recommended. Although an 80°C to 120°C temperature differential is preferred, recent developments allow a temperature differential between the component surface and the soldering temperature of 150°C (Maximum) for capacitors of 1210 size and below with a maximum thickness of 1.25mm. The user is cautioned that the risk of thermal shock increases as chip size or temperature differential increases. Soldering Mildly activated rosin fluxes are preferred. The minimum amount of solder to give a good joint should be used. Excessive solder can lead to damage from the stresses caused by the difference in coefficients of expansion between solder, chip and substrate. AVX terminations are suitable for all wave and reflow soldering systems. If hand soldering cannot be avoided, the preferred technique is the utilization of hot air soldering tools. POST SOLDER HANDLING Once SMP components are soldered to the board, any bending or flexure of the PCB applies stresses to the soldered joints of the components. For leaded devices, the stresses are absorbed by the compliancy of the metal leads and generally don’t result in problems unless the stress is large enough to fracture the soldered connection. Ceramic capacitors are more susceptible to such stress because they don’t have compliant leads and are brittle in nature. The most frequent failure mode is low DC resistance or short circuit. The second failure mode is significant loss of capacitance due to severing of contact between sets of the internal electrodes. Cracks caused by mechanical flexure are very easily identified and generally take one of the following two general forms: Cooling Natural cooling in air is preferred, as this minimizes stresses within the soldered joint. When forced air cooling is used, cooling rate should not exceed 4°C/second. Quenching is not recommended but if used, maximum temperature differentials should be observed according to the preheat conditions above. Cleaning Flux residues may be hygroscopic or acidic and must be removed. AVX MLC capacitors are acceptable for use with all of the solvents described in the specifications MIL-STD202 and EIA-RS-198. Alcohol based solvents are acceptable and properly controlled water cleaning systems are also acceptable. Many other solvents have been proven successful, and most solvents that are acceptable to other components on circuit assemblies are equally acceptable for use with ceramic capacitors. Type A: Angled crack between bottom of device to top of solder joint. Type B: Fracture from top of device to bottom of device. Mechanical cracks are often hidden underneath the termination and are difficult to see externally. However, if one end termination falls off during the removal process from PCB, this is one indication that the cause of failure was excessive mechanical stress due to board warping. 72 Surface Mounting Guide MLC Chip Capacitors COMMON CAUSES OF MECHANICAL CRACKING REWORKING OF MLCs The most common source for mechanical stress is board depanelization equipment, such as manual breakapart, vcutters and shear presses. Improperly aligned or dull cutters may cause torqueing of the PCB resulting in flex stresses being transmitted to components near the board edge. Another common source of flexural stress is contact during parametric testing when test points are probed. If the PCB is allowed to flex during the test cycle, nearby ceramic capacitors may be broken. A third common source is board to board connections at vertical connectors where cables or other PCBs are connected to the PCB. If the board is not supported during the plug/unplug cycle, it may flex and cause damage to nearby components. Special care should also be taken when handling large (>6" on a side) PCBs since they more easily flex or warp than smaller boards. Solder Tip Preferred Method - No Direct Part Contact Thermal shock is common in MLCs that are manually attached or reworked with a soldering iron. AVX strongly recommends that any reworking of MLCs be done with hot air reflow rather than soldering irons. It is practically impossible to cause any thermal shock in ceramic capacitors when using hot air reflow. However direct contact by the soldering iron tip often causes thermal cracks that may fail at a later date. If rework by soldering iron is absolutely necessary, it is recommended that the wattage of the iron be less than 30 watts and the tip temperature be <300ºC. Rework should be performed by applying the solder iron tip to the pad and not directly contacting any part of the ceramic capacitor. Solder Tip Poor Method - Direct Contact with Part PCB BOARD DESIGN To avoid many of the handling problems, AVX recommends that MLCs be located at least .2" away from nearest edge of board. However when this is not possible, AVX recommends that the panel be routed along the cut line, adjacent to where the MLC is located. No Stress Relief for MLCs Routed Cut Line Relieves Stress on MLC 73