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Capacitor Code Calculator
Enter printed capacitor markings such as 104K, 223, 475, 4R7, or 226M to decode nominal capacitance units and related tolerance context. This capacitor code calculator focuses on standard 2-4 digit EIA-style numeric codes, optional tolerance suffix letters, and R-coded decimal markings, then reports capacitance in picofarads with automatic conversion to nF and uF. The surrounding reference content covers tolerance letters, temperature-coefficient codes, legacy color-band notes, and package-size tables so technicians and engineers can cross-check markings when selecting replacements or reviewing existing circuits.
Updated July 10, 2026
Enter the printed capacitor marking, such as 104K, 223, 475, 4R7, or 226M, to decode the capacitance units and tolerance context.
Use the marking, capacitor family, tolerance letter, and voltage rating fields before selecting a replacement.
Enter a common capacitor marking such as 104K, 475M, or 4R7 to decode the value and tolerance context
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Decode the marked value, then compare parts and meters that help confirm a low-voltage electronics example.
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How to Use
Capacitor Code Calculator: Component Identification and Code Interpretation
Enter the code printed on the component, including numbers and any tolerance letter. Select the capacitor family for context, then decode the capacitance or convert a known value back to a standard marking code. The calculator itself focuses on common numeric and R-coded markings; the later sections of this page cover legacy color-band notes and package-size references separately.
SMD and electrolytic capacitor code input notes
Use the calculator for printed value codes such as 104, 104K, 223, 475, 4R7, or 226M. SMD package codes such as 0603, 0805, and 1206 identify size, not capacitance, so they must be paired with the actual printed value, measurement, schematic, or datasheet. Electrolytic capacitors usually print direct uF, voltage, and polarity markings, such as 47 uF 25 V with a negative stripe, rather than a three-digit ceramic-style value code.
Step-by-step usage
- Choose Decode code to value, Convert value to code, or Tolerance and rating analysis depending on the task.
- Set the Capacitor Type to match the part family so you can review the correct tolerance and dielectric context.
- For decode, enter a common marking such as 104, 223, 475, 104K, or 4R7. For encode, enter the capacitance value and unit (pF, nF, µF, mF).
- When needed, add tolerance letter, voltage rating, and temperature coefficient so the calculator can report additional specification context.
- Review the returned capacitance in pF and scaled units together with any tolerance or temperature-coefficient notes, then confirm manufacturer-specific ratings from the datasheet.
Supported calculator modes
- Decode code to value: Enter a 2–4 digit code such as 104, 223, 475, or 4R7. The tool returns capacitance in pF plus scaled units (nF/µF) and shows the 10multiplier used.
- Convert value to code: Enter a capacitance value and unit (pF, nF, µF, mF). The tool generates a standard 2-3 digit marking code for common EIA-style markings.
- Reference sections on this page: Use the color-band notes and SMD case-size tables below as supporting reference material. The calculator does not take separate color-band or case-size inputs.
- Tolerance and rating analysis: When you already know the nominal value, use tolerance letter, voltage rating, and temperature coefficient inputs to interpret how the part behaves over temperature and applied voltage.
3-Digit Capacitor Code Reference After Using the Calculator
Use the calculator above for the actual marking on the component. This reference section explains the decoding rule after you enter the code; it does not replace the interactive decode result or the manufacturer datasheet.
- Three-digit numeric markings use the first two digits as significant figures and the third digit as the pF multiplier.
- R-coded markings use the letter R as a decimal point for small pF values.
- Tolerance suffixes such as J, K, or M should be entered with the marking so the calculator can keep capacitance and tolerance context together.
- Package numbers such as 0603, 0805, and 1206 identify physical size, so confirm the electrical value from the printed marking, schematic, measurement, or datasheet.
Key rule: decode the printed marking first, then convert the returned pF value into nF or uF only after the calculator has identified the numeric pattern and any tolerance suffix.
Common Capacitor Code Lookup Reference After Decoding
For common markings such as 104, 223, 475, 4R7, or 226M, enter the printed code in the calculator and use the returned pF, nF, and uF values before selecting a replacement. Keep the decoded value, tolerance suffix, capacitor family, and datasheet context together when you compare the result with a chart or parts list.
When you need a quick reference sheet instead of a one-off decode, use the Capacitor Code Chart, then move to the RC Circuit Calculator for timing networks or the Capacitor Calculator for reactance checks.
Understanding Capacitor Coding Systems and Standards
Capacitor code identification requires understanding multiple marking systems used by different manufacturers and capacitor technologies. Ceramic capacitors typically use 3-digit numeric codes, while tantalum and electrolytic capacitors may use direct value markings or alphanumeric codes. Surface-mount devices (SMD) use compact coding systems due to space constraints.
Professional electronics repair and circuit design depend on accurate capacitor identification for proper component replacement and circuit analysis. Incorrect capacitor values can cause circuit malfunction, oscillation, or component damage. The capacitor code calculator ensures accurate decoding across all common marking systems and capacitor types.
Capacitor Types and Their Marking Systems
| Capacitor Type | Marking System | Value Range | Common Applications |
|---|---|---|---|
| Ceramic Disc | 3-digit codes (104, 223) | 1pF - 10μF | Bypass, coupling, timing |
| MLCC (SMD) | Alphanumeric (C1608, 0805) | 0.5pF - 100μF | High-density circuits, mobile devices |
| Tantalum | Direct marking (47μF 16V) | 0.1μF - 1000μF | Power supplies, audio circuits |
| Electrolytic | Direct marking (1000μF 25V) | 1μF - 100,000μF | Power filtering, energy storage |
| Film | Color codes or direct marking | 100pF - 100μF | Precision circuits, motor starting |
Color band and dot codes on legacy capacitors
Older film and mica capacitors often use color bands or colored dots instead of numeric printing. The color sequence typically follows the same digit order as resistor color codes (black=0, brown=1, red=2, orange=3, yellow=4, green=5, blue=6, violet=7, gray=8, white=9), with additional bands indicating multiplier and tolerance. Many service manuals and manufacturer datasheets include a specific color chart for these parts. When decoding such components, use the capacitor code calculator together with a verified color-code reference or the original equipment documentation.
In practice, modern ceramic and tantalum capacitors rarely use full color-band codes; most parts now show numeric or alphanumeric codes. The color-band guidance in this section is primarily for vintage equipment restoration and troubleshooting legacy boards.
EIA 198 Standard SMD Capacitor Size Codes
| EIA Code | Metric Code | Dimensions (L×W mm) |
|---|---|---|
| 0201 | 0603 | 0.6 × 0.3 |
| 0402 | 1005 | 1.0 × 0.5 |
| 0603 | 1608 | 1.6 × 0.8 |
| 0805 | 2012 | 2.0 × 1.25 |
| 1206 | 3216 | 3.2 × 1.6 |
| 1210 | 3225 | 3.2 × 2.5 |
EIA 198 defines case-size designations for surface-mount ceramic capacitors. The 4-digit EIA code gives imperial dimensions in hundredths of an inch (length then width). For example, 0805 = 0.08" × 0.05" (2.0mm × 1.25mm). Metric codes (0603, 1005, 1608, 2012, 3216, 3225) use actual millimetre dimensions. This table effectively serves as an SMD capacitor size cross-reference chart between imperial and metric codes for common packages such as 0201, 0402, 0603, 0805, 1206 and 1210. Capacitance range and maximum voltage for a given case size depend strongly on dielectric type and manufacturer, so always confirm limits in the specific part datasheet.
Voltage Ratings and Derating Practice
Most capacitors mark voltage rating directly in volts (for example, 16V, 25V, 50V) or encode it in a manufacturer-specific part number. standard component marking practice covers generic marking systems, but in practice you should treat the datasheet as the authoritative source for the maximum continuous DC and AC voltage ratings of a given part family.
Design practice is to derate capacitors below their absolute maximum rating to improve lifetime and reliability:
- Ceramic MLCC (X7R/X5R): Common to design for about 50% of the DC voltage rating because capacitance drops significantly under DC bias and high field stress accelerates ageing.
- Electrolytic and tantalum: Many manufacturers recommend operating at no more than 70–80% of rated DC voltage, with deeper derating for high-reliability or high-ripple applications.
- Film capacitors in AC use: RMS voltage is lower than peak; design typically keeps peak AC voltage well below the DC rating to account for surge and harmonic content.
USB Power Delivery defines a set of common bus voltages (for example 5V, 9V, 15V, 20V, and extended-power profiles at higher voltages in newer revisions). When selecting decoupling and bulk capacitors on USB‑PD rails, use parts whose DC rating exceeds the highest possible bus voltage with an appropriate derating margin, based on the converter topology and manufacturer guidance. For a complete step-by-step design discussion, see the USB Power Delivery decoupling and capacitor selection guide.
A practical USB‑PD decoupling workflow is:
- Determine the maximum negotiated bus voltage and expected transient overshoot on the USB‑PD rail.
- Select a combination of local MLCCs (for high-frequency decoupling) and bulk capacitors (for lower-frequency energy storage) consistent with the controller or converter reference design.
- Apply voltage derating appropriate to the dielectric and technology (for example ~50% for X7R MLCCs on high‑dV/dt rails, 70–80% for many electrolytic/tantalum parts).
- Check effective capacitance under DC bias at the actual bus voltage using datasheet graphs or vendor tools, and verify the resulting impedance profile against your PD controller or power-stage specifications.
Advanced Capacitor Code Interpretation and Specifications
Temperature Coefficient Codes: Ceramic capacitors use temperature coefficient codes that indicate capacitance stability over temperature. C0G/NP0 capacitors typically maintain around ±30ppm/°C for precision applications, while X7R allows about ±15% capacitance change over −55°C to +125°C. Y5V capacitors offer high capacitance density but with roughly +22% to −82% variation over its rated range. For quantitative ΔC/C evaluation, see the temperature coefficient calculator.
| Code | Class | Temperature Range (°C) | ΔC/C₀ Over Range |
|---|---|---|---|
| C0G / NP0 | Class I | −55 to +125 | ≈ ±30 ppm/°C |
| X7R | Class II | −55 to +125 | ±15% |
| X5R | Class II | −55 to +85 | ±15% |
| Y5V | Class II | −30 to +85 | +22% / −82% |
| Z5U | Class II | +10 to +85 | +22% / −56% |
Voltage Rating Identification: Voltage codes use letters or numbers to indicate maximum working voltage. Understanding voltage ratings prevents component failure and ensures circuit reliability. Always derate capacitors to 50-80% of maximum voltage for long-term reliability, especially in switching applications.
Tolerance and Precision Specifications: Capacitor tolerance affects circuit performance in timing, filtering, and tuning applications. Precision circuits require tight tolerance capacitors (±1% to ±5%), while general applications can use standard tolerances (±10% to ±20%). The capacitor code calculator provides tolerance information for proper component selection.
Practical Capacitor Identification and Replacement Guidelines
Circuit repair requires understanding capacitor function and selecting appropriate replacements. Bypass capacitors need low ESR and appropriate frequency response, while timing capacitors require stable temperature coefficients. Use RC circuit and time constant calculators to verify timing circuit values. Power supply filtering capacitors must handle ripple current and voltage stress - calculate ripple specifications with RC filter design tools.
SMD capacitor identification becomes challenging due to miniaturization, requiring careful measurement and code interpretation. Package size codes (0402, 0603, 0805) indicate physical dimensions but not electrical specifications. The capacitor code calculator helps decode compact markings used on surface-mount components. For circuit analysis after component identification, use impedance calculators to determine capacitive reactance at operating frequency, and capacitor reactance tools for AC circuit design.
Quality control and component verification ensure circuit reliability and performance. Counterfeit capacitors may have incorrect markings or specifications, making code verification essential for critical applications. Professional component identification prevents circuit failures and ensures design integrity. Cross-reference decoded values with manufacturer datasheets and verify with resistor color code tools when identifying mixed component boards. For complete circuit analysis, combine capacitor identification with Ohm's law calculations and voltage divider tools.
Critical Safety Considerations and Component Selection
⚠️ VOLTAGE DERATING REQUIREMENTS
- Ceramic (X7R/X5R): Derate to 50% of rated voltage - capacitance drops significantly with DC bias. A 10µF/10V X7R may measure only 3-4µF at 10V applied.
- Electrolytic/Tantalum: Never exceed 80% of rated voltage. Use 50% derating for high-reliability applications. Operating at full voltage drastically reduces lifespan.
- Film Capacitors: Derate to 60-70% for AC applications due to peak voltage stress. 630VDC film caps are safe for 230VAC (325V peak).
- High-frequency/Switching: Additional 20% derating required due to ripple current heating and ESR losses in SMPS applications.
Polarity and Installation Safety
| Capacitor Type | Polarity | Reverse Voltage Tolerance | Failure Mode |
|---|---|---|---|
| Aluminum Electrolytic | Polarized (+/-) | -1V to -1.5V max | Venting, explosion, fire hazard |
| Tantalum | Polarized (+/-) | Zero tolerance | Catastrophic short, flame, PCB damage |
| Ceramic (MLCC) | Non-polarized | Bidirectional | Short circuit (no flames) |
| Film (Polyester, PP) | Non-polarized | Bidirectional | Self-healing or open circuit |
CRITICAL: Tantalum capacitors fail catastrophically when reverse-biased or over-voltaged - they can ignite and damage nearby components. Always verify polarity markings (stripe = negative terminal for aluminum electrolytic, positive for tantalum). Use fusing resistors (1-10Ω) in series with tantalum caps in high-surge applications.
Counterfeit Component Detection and Verification
Common counterfeit indicators in practice:
- Marking quality: Compare printing or laser etching against the manufacturer datasheet or known-good samples. Blurry, misaligned, or inconsistent markings are a warning sign.
- Measured capacitance: Use an LCR meter under conditions close to the datasheet test point. Significant deviation from the specified capacitance (after accounting for tolerance, temperature and DC bias) may indicate a non‑genuine or out‑of‑spec part.
- Losses and ESR: Excessively high ESR or dissipation factor compared with the datasheet values at the stated test frequency suggests ageing, damage, or counterfeit product.
- Internal construction: X‑ray inspection or destructive analysis can reveal abnormal electrode geometry or layer count compared with reference devices from the same series.
- Packaging and traceability: Check reel labels, lot codes, QR codes or serial numbers against information provided by the original manufacturer or their authorised distributors.
- Source of supply: Buying from franchised distributors or directly from the manufacturer greatly reduces counterfeit risk compared with uncontrolled secondary markets.
Testing procedure for suspected counterfeits: When in doubt, characterise samples against the manufacturer datasheet: measure capacitance and loss parameters at the specified test frequency and temperature, evaluate behaviour under DC bias where applicable, and perform limited thermal cycling if needed. Devices that consistently fall outside published limits, or whose markings and packaging cannot be reconciled with official documentation, should be treated as suspect and quarantined from production.
Common Applications
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Frequently Asked Questions
How do I read 3-digit capacitor codes and understand the units?
What do letters and tolerance codes mean in capacitor markings?
How do I identify different capacitor types and their marking systems?
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