Resonant Frequency Calculator
Instantly convert resonant frequency with our free converter. See conversion tables, formulas, and step-by-step explanations.
Formula
f = 1 / (2 * pi * sqrt(L * C))
The resonant frequency is calculated using the inductance (L) in henries and capacitance (C) in farads. Q factor = (1/R)*sqrt(L/C) for series RLC. Bandwidth = f/Q. Characteristic impedance = sqrt(L/C).
Worked Examples
Example 1: AM Radio Tuning Circuit
Problem: An AM radio uses a 250 uH inductor. What capacitance tunes to 1000 kHz?
Solution: f = 1 / (2*pi*sqrt(L*C))\nRearranging: C = 1 / (4*pi^2*f^2*L)\nC = 1 / (4 * 9.8696 * (1e6)^2 * 250e-6)\nC = 1.013e-10 F = 101.3 pF
Result: 101.3 pF capacitor needed to resonate at 1 MHz with 250 uH
Example 2: Audio Crossover Filter
Problem: Design a resonant circuit at 3 kHz using a 10 mH inductor and find the Q with 50 ohm resistance.
Solution: f = 1/(2*pi*sqrt(L*C)), so C = 1/(4*pi^2*f^2*L)\nC = 1/(4*9.8696*9e6*0.01) = 2.814e-7 F = 281.4 nF\nQ = (1/50)*sqrt(0.01/2.814e-7) = 3.77
Result: C = 281.4 nF, Q = 3.77, BW = 796 Hz
Frequently Asked Questions
What is resonant frequency in an LC circuit?
Resonant frequency is the frequency at which an LC (inductor-capacitor) circuit naturally oscillates when energy is exchanged between the magnetic field of the inductor and the electric field of the capacitor. At resonance, the inductive reactance equals the capacitive reactance, and they cancel each other out. The formula is f = 1 / (2 * pi * sqrt(L * C)), where L is inductance in henries and C is capacitance in farads.
How does resistance affect resonant frequency?
In an ideal LC circuit with no resistance, the resonant frequency depends only on L and C. When resistance is added (RLC circuit), the undamped natural frequency remains the same, but the actual oscillation frequency (damped frequency) decreases slightly. The damping ratio determines whether the circuit oscillates (underdamped), critically damps, or overdamps. Resistance also broadens the bandwidth and reduces the Q factor.
Where are resonant circuits used in practice?
Resonant circuits are fundamental to radio tuning, where they select specific frequencies from the electromagnetic spectrum. They are used in bandpass filters, oscillators, impedance matching networks, wireless power transfer systems, and MRI machines. Crystal oscillators in computers use mechanical resonance of quartz crystals. Tesla coils use resonance to achieve extremely high voltages. Even musical instruments rely on acoustic resonance principles.
What formula does Resonant Frequency Calculator use?
The formula used is described in the Formula section on this page. It is based on widely accepted standards in the relevant field. If you need a specific reference or citation, the References section provides links to authoritative sources.
How do I interpret the result?
Results are displayed with a label and unit to help you understand the output. Many calculators include a short explanation or classification below the result (for example, a BMI category or risk level). Refer to the worked examples section on this page for real-world context.
How accurate are the results from Resonant Frequency Calculator?
All calculations use established mathematical formulas and are performed with high-precision arithmetic. Results are accurate to the precision shown. For critical decisions in finance, medicine, or engineering, always verify results with a qualified professional.