Calculate capacitor charge, energy, time constant, reactance, and series/parallel combinations. RC discharge curve and standard value reference.
Capacitors store electrical energy in an electric field. The three fundamental relationships — charge (Q = CV), energy (E = ½CV²), and time constant (τ = RC) — govern almost every capacitor application from simple timing circuits to industrial energy storage.
Understanding these relationships is essential for electronics design: selecting bypass capacitors, designing RC filters and timing circuits, sizing energy storage for cameras and defibrillators, and combining capacitors in series/parallel to achieve target values and voltage ratings.
This calculator computes all key capacitor properties from your inputs: stored charge and energy, RC time constant and discharge curve, reactance at a given frequency, impedance with series resistance, and equivalent values for series/parallel combinations. It includes an E12 standard value reference and visual discharge curve to help with component selection and circuit design. Check the example with realistic values before reporting. Use the steps shown to verify rounding and units. Cross-check this output using a known reference case.
Capacitor calculations involve multiple interrelated formulas with unit conversions across pF to F scales and time ranges from nanoseconds to seconds. Manual calculation is tedious and error-prone, especially when evaluating series/parallel combinations or time-domain behavior.
This calculator provides instant results for all capacitor properties, a visual discharge curve, and standard value reference. It is essential for electronics designers, physics students, and hobbyists selecting capacitors for specific circuits.
Charge: Q = CV. Energy: E = ½CV². Time constant: τ = RC. Discharge: V(t) = V₀·e^(−t/τ). Reactance: Xc = 1/(2πfC). Series: 1/C_total = Σ(1/Ci). Parallel: C_total = ΣCi.
Result: 1.2 mC charge, 7.2 mJ energy, 0.1 s time constant
A 100 µF capacitor at 12V stores Q = 100×10⁻⁶ × 12 = 1.2 mC of charge and E = ½ × 100×10⁻⁶ × 144 = 7.2 mJ of energy. With 1 kΩ resistance, τ = 1000 × 100×10⁻⁶ = 0.1 s. Full charge (99.3%) takes 5τ = 0.5 s.
**Ceramic capacitors** (pF to µF) offer low ESR, high frequency performance, and small size. C0G/NP0 types have stable capacitance; X7R and Y5V types trade stability for higher capacitance. Used for decoupling, RF filtering, and timing.
**Film capacitors** (nF to µF) provide tight tolerance, low ESR, and self-healing properties. Used in audio crossovers, precision timing, power factor correction, and safety-rated applications (X/Y caps).
**Electrolytic capacitors** (µF to F) offer the highest capacitance-to-volume ratio. Aluminum electrolytics are cheap but have high ESR and limited life. Tantalum types are smaller with lower ESR but can fail catastrophically if overvoltaged.
The RC time constant τ = RC governs countless circuits. In a 555 timer, the charge time through R₁ + R₂ and discharge through R₂ sets the oscillation frequency. In a debounce circuit, τ should be about 10-50 ms. In a power supply filter, τ should be much longer than the ripple period (1/f_ripple).
The discharge equation V(t) = V₀·e^(−t/RC) is exponential — the capacitor never fully discharges to zero, but after 5τ it is within 0.7% of the final value, which is close enough for nearly all practical purposes.
A 1000 µF/50V electrolytic stores 1.25 J. A camera flash unit might use 330 µF/300V for 14.85 J. Industrial capacitor banks for power factor correction use thousands of µF at hundreds of volts. Supercapacitors bridge the gap between capacitors and batteries, with energy density 10-100× higher than electrolytic capacitors but 10-100× lower than lithium batteries.
The time constant τ = RC is the time for a capacitor to charge to 63.2% of the supply voltage (or discharge to 36.8%). After 5τ, the capacitor is considered fully charged (99.3%).
As voltage increases, both the charge stored and the voltage increase proportionally. Since energy is charge times voltage (integrated), it scales as V². This is why supercapacitors at low voltage store less energy than small capacitors at high voltage.
In parallel, capacitances add (like resistors in series). In series, reciprocals add: 1/C_total = 1/C₁ + 1/C₂ (like resistors in parallel). Series combination reduces capacitance but increases voltage rating.
The dielectric material breakdown voltage determines the maximum safe operating voltage. Exceeding this causes the dielectric to fail, often catastrophically. Always use capacitors rated well above your circuit voltage.
Equivalent Series Resistance (ESR) is the parasitic resistance inside a capacitor. It causes heating during charge/discharge cycles and limits effectiveness at high frequencies. Ceramic and film capacitors have low ESR; electrolytics have higher ESR.
A 1F/5.5V supercapacitor stores E = ½ × 1 × 5.5² = 15.1 J. A 3000F/2.7V cell stores about 10,900 J (3 Wh). By comparison, a AA battery stores about 10,000 J — similar energy but delivered over hours, not seconds.