Definition and Concept
Basic Definition
Reactance: opposition to alternating current (AC) caused by inductors and capacitors. Unlike resistance, reactance stores energy temporarily in magnetic or electric fields. Unit: ohm (Ω).
Distinction from Resistance
Resistance: dissipates energy as heat, frequency-independent. Reactance: stores and returns energy, frequency-dependent. Both combine to form impedance.
Physical Origin
Inductive reactance: induced voltage opposes current change via magnetic field. Capacitive reactance: voltage lag due to energy storage in electric field.
Inductive Reactance
Mechanism
Inductor resists changes in current. Magnetic flux linkage induces counter electromotive force (emf). Result: current lags voltage.
Formula
XL = 2πfLWhere XL is inductive reactance, f is frequency (Hz), L is inductance (H).
Characteristics
Increases linearly with frequency. Zero reactance at DC (f=0). High reactance at high frequencies.
Capacitive Reactance
Mechanism
Capacitor stores energy in electric field. Current leads voltage due to charging/discharging cycles.
Formula
XC = 1 / (2πfC)Where XC is capacitive reactance, f is frequency (Hz), C is capacitance (F).
Characteristics
Decreases with increasing frequency. Infinite reactance at DC (f=0). Low reactance at high frequencies.
Frequency Dependence
Overall Effect
Reactance magnitude varies with frequency: inductive reactance ∝ f, capacitive reactance ∝ 1/f.
Frequency Response
Inductors block high-frequency signals less effectively; capacitors block low-frequency signals more effectively.
Resonance
At resonant frequency, inductive and capacitive reactances equal; overall reactance zero, circuit purely resistive.
Phase Relationship
Inductive Reactance Phase
Voltage leads current by 90°; current lags voltage.
Capacitive Reactance Phase
Current leads voltage by 90°; voltage lags current.
Combined Effects
Net reactance phase angle depends on relative magnitudes of inductive and capacitive reactance.
Impedance and Reactance
Definition of Impedance
Impedance (Z): complex opposition to AC, combining resistance (R) and reactance (X).
Mathematical Form
Z = R + jXj: imaginary unit, X = XL - XC.
Magnitude and Phase
|Z| = √(R² + X²)θ = arctan(X / R)Magnitude: total opposition; phase angle: voltage-current phase difference.
Reactance Calculation
Inductive Reactance Calculation Example
Given L = 10 mH, f = 1 kHz:
XL = 2π × 1000 × 0.01 = 62.8 ΩCapacitive Reactance Calculation Example
Given C = 1 μF, f = 1 kHz:
XC = 1 / (2π × 1000 × 1×10⁻⁶) = 159.15 ΩNet Reactance
If both in series: X = XL - XC = 62.8 - 159.15 = -96.35 Ω (capacitive net reactance).
Reactance in AC Circuits
Series Circuits
Reactances add algebraically: total reactance X = XL - XC. Determines frequency response and phase shift.
Parallel Circuits
Calculate admittance Y = 1 / Z; reactances combine inversely: 1/X = 1/XL - 1/XC.
Resonant Circuits
At resonance, reactances cancel: XL = XC. Circuit behaves purely resistive; maximum current flow.
| Circuit Type | Total Reactance | Phase Angle |
|---|---|---|
| Series LC | X = XL - XC | Varies with X |
| Parallel LC | 1/X = 1/XL - 1/XC | Varies with admittance |
Applications
Filters
Reactance controls frequency selectivity in low-pass, high-pass, band-pass, and band-stop filters.
Tuning Circuits
Resonant circuits use reactance balance for frequency tuning in radios, TVs, oscillators.
Power Factor Correction
Capacitive reactance offsets inductive reactance to improve power factor in electrical systems.
Signal Processing
Reactance properties exploited in phase shifters, delay lines, impedance matching.
Measurement Techniques
Impedance Analyzers
Measure magnitude and phase of impedance; extract reactance using complex calculations.
LCR Meters
Measure inductance (L) and capacitance (C) directly; compute reactance from frequency.
Network Analyzers
Frequency sweep measurements yield reactance vs frequency curves; useful for component characterization.
Limitations and Assumptions
Ideal Components
Reactance formulas assume ideal inductors and capacitors; real devices exhibit resistance and nonlinearity.
Frequency Range
At very high frequencies, parasitic effects and skin effect alter reactance behavior.
Temperature Effects
Component values vary with temperature, affecting reactance and circuit performance.
Summary
Reactance: frequency-dependent opposition to AC from inductors and capacitors. Inductive reactance increases with frequency; capacitive reactance decreases. Reactance causes phase shifts and combines with resistance as impedance. Crucial in AC circuit analysis, filter design, resonance, and power systems.
References
- S. Ramo, J. Whinnery, T. Van Duzer, Fields and Waves in Communication Electronics, Wiley, 3rd ed., 1994, pp. 120-150.
- L. O. Chua, C. A. Desoer, E. S. Kuh, Linear and Nonlinear Circuits, McGraw-Hill, 1987, pp. 75-110.
- J. D. Ryder, Networks, Lines and Fields, Prentice Hall, 2nd ed., 1997, pp. 98-130.
- R. E. Collin, Foundations for Microwave Engineering, Wiley-IEEE Press, 2nd ed., 2001, pp. 45-60.
- F. F. Mazda, Electromagnetic Theory and Applications, Cambridge University Press, 2010, pp. 210-245.