Wave impedance
Wave impedance is a key property in the physics of wave propagation, representing the ratio of the transverse components of the driving force (such as pressure or electric field) to the resulting particle or field velocity in a medium, which governs reflection, transmission, and energy transfer at interfaces.[1] This concept applies across various domains, including electromagnetism, acoustics, and mechanics, where it quantifies the medium's opposition to wave motion analogous to electrical resistance.[2] In each field, wave impedance ensures efficient wave propagation when matched between source and load, minimizing losses due to reflections.[3] In electromagnetics, wave impedance for a plane wave in a non-conducting medium is defined as the ratio of the electric field strength \mathbf{E} to the magnetic field strength \mathbf{H}, given by Z = \sqrt{\mu / \epsilon}, where \mu is the magnetic permeability and \epsilon is the electric permittivity.[3] In free space, this intrinsic impedance Z_0 is approximately 377 ohms, derived from the speed of light c = 1 / \sqrt{\mu_0 \epsilon_0}.[3] It plays a crucial role in antenna design, transmission lines, and electromagnetic shielding, where mismatches lead to standing waves and signal attenuation.[1] In acoustics, wave impedance, often termed specific acoustic impedance, is the ratio of sound pressure p to particle velocity u, expressed for plane waves as z = \rho c, with \rho as the medium's density and c as the speed of sound.[2] This value, around 415 kg/(m²·s) for air at standard conditions, determines reflection coefficients at boundaries, such as between air and water, affecting sound transmission in architectural and medical ultrasound applications.[2] For mechanical waves on a string, impedance is Z = \sqrt{T \mu}, where T is tension and \mu is linear mass density, influencing wave speed and junction behaviors in vibrating systems.[4]Fundamentals
Definition
Wave impedance, also known as intrinsic impedance, is defined as the ratio of the transverse components of the electric field \mathbf{E}_t to the magnetic field \mathbf{H}_t in a propagating electromagnetic plane wave, expressed mathematically as Z = \frac{E_t}{H_t}.[5][6] This ratio characterizes the relationship between the fields perpendicular to the direction of propagation in unbounded media. For plane waves in isotropic, lossless media, the wave impedance derives directly from Maxwell's equations. Consider a monochromatic plane wave propagating in the z-direction, with fields \mathbf{E} = \tilde{\mathbf{E}} e^{i(kz - \omega t)} and \mathbf{H} = \tilde{\mathbf{H}} e^{i(kz - \omega t)}, where \tilde{\mathbf{E}} and \tilde{\mathbf{H}} are complex amplitudes transverse to \hat{z}. Faraday's law in phasor form gives \nabla \times \tilde{\mathbf{E}} = i \omega \mu \tilde{\mathbf{H}}, yielding i k \hat{z} \times \tilde{\mathbf{E}} = i \omega \mu \tilde{\mathbf{H}}, or \tilde{\mathbf{H}} = \frac{k}{\omega \mu} \hat{z} \times \tilde{\mathbf{E}}. Similarly, the Ampère-Maxwell law provides \nabla \times \tilde{\mathbf{H}} = -i \omega \varepsilon \tilde{\mathbf{E}}, leading to i k \hat{z} \times \tilde{\mathbf{H}} = -i \omega \varepsilon \tilde{\mathbf{E}}. Substituting the expression for \tilde{\mathbf{H}} and using the dispersion relation k = \omega \sqrt{\mu \varepsilon} (from the wave speed v = 1 / \sqrt{\mu \varepsilon}) results in Z = \sqrt{\frac{\mu}{\varepsilon}}.[7][6] In the SI system, the wave impedance has units of ohms (\Omega), analogous to electrical resistance, reflecting its role in relating electric and magnetic field strengths.[6] This quantity, often denoted as \eta for intrinsic impedance, depends solely on the medium's permeability \mu and permittivity \varepsilon.[5] It is distinct from the characteristic impedance of guided wave structures, such as transmission lines, which incorporates geometric factors in addition to material properties.[8]Physical significance
Wave impedance plays a crucial role in determining the behavior of electromagnetic waves at interfaces between different media. When a plane wave encounters a boundary, the mismatch in wave impedances Z_1 and Z_2 of the two media leads to partial reflection and transmission. The reflection coefficient \Gamma, defined as the ratio of the reflected electric field amplitude to the incident amplitude, is given by \Gamma = \frac{Z_2 - Z_1}{Z_2 + Z_1}. This coefficient quantifies the fraction of the wave that is reflected back, with |\Gamma| = 0 indicating perfect transmission when Z_1 = Z_2, and |\Gamma| = 1 for total reflection in cases of extreme mismatch, such as at a perfect conductor where Z_2 = 0.[9] The practical importance of wave impedance is most evident in impedance matching techniques, which aim to minimize reflections and maximize power transfer across interfaces, such as in antennas, transmission lines, and optical systems. By designing systems where the source and load impedances are equal (or complex conjugates for reactive components), reflections are eliminated, allowing nearly all incident power to be delivered to the load rather than being returned as standing waves or heat. This principle underpins efficient RF engineering, where unmatched impedances can result in significant signal loss and reduced system performance. For instance, in antenna design, matching the feed line impedance to the antenna ensures optimal radiation efficiency.[10][4] Wave impedance also connects directly to the energy flow in electromagnetic waves through the Poynting vector, which describes the directional power density. For a plane wave, the time-averaged Poynting vector magnitude S is S = \frac{1}{2} \frac{|E|^2}{Z}, where |E| is the electric field amplitude and Z is the wave impedance. This relation highlights how impedance governs the power carried by the wave: higher impedance reduces power density for a given field strength, influencing applications like radiation pressure and energy harvesting.[11] Conceptually, wave impedance serves as an analogy to the impedance in AC electrical circuits, where it represents the ratio of voltage to current, enabling similar analysis of power transfer and matching. Just as circuit impedance dictates maximum power delivery when source and load are matched, wave impedance provides a unified framework for understanding wave propagation and efficiency in distributed electromagnetic systems.[4]Plane Waves in Media
In free space
In free space, the wave impedance for electromagnetic plane waves, defined as the ratio of the transverse electric field to the transverse magnetic field, is known as the intrinsic impedance and denoted by \eta_0. This impedance arises from the fundamental properties of vacuum and is given by \eta_0 = \sqrt{\frac{\mu_0}{\varepsilon_0}}, where \mu_0 = 4\pi \times 10^{-7} H/m is the permeability of free space and \varepsilon_0 \approx 8.854 \times 10^{-12} F/m is the permittivity of free space.[3][12] The expression for \eta_0 can be derived from the speed of light in vacuum, c = \frac{1}{\sqrt{\mu_0 \varepsilon_0}} \approx 2.99792458 \times 10^8 m/s, which relates the vacuum constants through Maxwell's equations for wave propagation. Substituting this relation yields \eta_0 = \mu_0 c, providing an alternative form that emphasizes the connection to the propagation speed.[3][12] The numerical value of \eta_0 is approximately 376.73 \Omega, with the exact CODATA-recommended value being 376.730313412(59) \Omega.[13] In engineering contexts, it is often approximated as $120\pi \Omega \approx 377 \Omega.[14] For transverse electromagnetic (TEM) plane waves propagating in free space, the electric field \mathbf{E} and magnetic field \mathbf{H} are both transverse to the direction of propagation and mutually perpendicular, satisfying \mathbf{E} \perp \mathbf{H} \perp \mathbf{k} (where \mathbf{k} is the wave vector). The magnitudes obey |\mathbf{E}| / |\mathbf{H}| = \eta_0, ensuring the wave carries energy at the speed of light without dispersion in vacuum.[12][3]In unbounded dielectrics
In unbounded homogeneous isotropic dielectrics, the wave impedance for propagating plane waves is defined as the intrinsic impedance \eta = \sqrt{\frac{\mu}{\varepsilon_c}}, where \varepsilon_c = \varepsilon' - j \varepsilon'' is the complex permittivity that incorporates material losses.[15] This formulation arises from Maxwell's equations for time-harmonic fields in linear media, relating the transverse electric and magnetic field components of the wave.[16] For non-magnetic dielectrics where the permeability \mu = \mu_0, the expression simplifies to \eta = \frac{\eta_0}{\sqrt{\varepsilon_{r,c}}}, with \eta_0 \approx 377 \, \Omega as the free-space impedance and \varepsilon_{r,c} = \varepsilon_r' - j \varepsilon_r'' the complex relative permittivity.[17] The real part \varepsilon_r' determines the wave speed, while the imaginary part \varepsilon_r'' accounts for dissipation, making \eta complex in lossy cases. Conductivity \sigma contributes to the imaginary permittivity via \varepsilon'' = \frac{\sigma}{\omega}, where \omega is the angular frequency, rendering \eta complex and introducing an attenuation constant \alpha that causes exponential decay of the wave amplitude with propagation distance.[18] This loss mechanism converts electromagnetic energy into heat through ohmic dissipation, with the attenuation scaling as \alpha \approx \frac{\sigma}{2} \sqrt{\frac{\mu}{\varepsilon}} for low-loss dielectrics where conduction current is much less than displacement current (\sigma \ll \omega \varepsilon).[19] Representative examples illustrate the range: in fresh water at microwave frequencies (e.g., 3 GHz), with \varepsilon_r' \approx 80 and low conductivity \sigma \approx 0.01 \, \mathrm{S/m}, \eta \approx 42 \, \Omega; in low-loss glass (\varepsilon_r \approx 4.5), \eta \approx 178 \, \Omega.[20] These values, typically 10–200 \Omega for common dielectrics, are significantly lower than the free-space baseline of 377 \Omega, affecting reflection and transmission at interfaces.[21]Guided Electromagnetic Waves
Transmission lines
In transmission lines supporting transverse electromagnetic (TEM) modes, such as coaxial cables or parallel-wire lines, the wave impedance is characterized by the characteristic impedance Z_0, which represents the ratio of voltage to current for a traveling wave along the line. This quantity determines how signals propagate without distortion when the line is terminated in Z_0, analogous to the intrinsic impedance of plane waves but dependent on the line's geometry and filling materials.[22] The characteristic impedance arises from the telegrapher's equations, which model the distributed parameters of the line: series inductance per unit length L, shunt capacitance per unit length C, series resistance per unit length R, and shunt conductance per unit length G. For lossless lines (R = 0, G = 0), the equations simplify to describe wave propagation, yielding solutions for voltage V(z) = V_0^+ e^{-\gamma z} + V_0^- e^{\gamma z} and current I(z) = I_0^+ e^{-\gamma z} + I_0^- e^{\gamma z}, where \gamma = j\beta is the propagation constant with phase constant \beta = \omega \sqrt{LC}. Substituting into the telegrapher's equations relates the forward voltage and current waves via I_0^+ = V_0^+ / Z_0, leading to Z_0 = \sqrt{L/C}. The wave speed is v = 1/\sqrt{LC}, linking Z_0 to the propagation velocity, which equals the speed of light in the filling medium for TEM modes.[22] The value of Z_0 depends strongly on the transmission line's geometry, as L and C are determined by the conductor arrangement. For a coaxial line with inner conductor radius a and outer conductor inner radius b, the characteristic impedance in free space is Z_0 = \frac{\eta_0}{2\pi} \ln\left(\frac{b}{a}\right), where \eta_0 \approx 377 \, \Omega is the impedance of free space; this logarithmic dependence allows Z_0 to range from about 30 Ω to 100 Ω by varying b/a. For a twin-lead (two parallel wires) with wire radius a and center-to-center separation d (where d \gg 2a), Z_0 = \frac{\eta_0}{\pi} \ln\left(\frac{d}{a}\right), typically yielding higher values around 300 Ω for television applications. These expressions stem from solving Laplace's equation for the electrostatic fields to find C, combined with the magnetic energy to find L.[23][24] Filling the line with a dielectric material of relative permittivity \epsilon_r > 1 increases C proportionally to \epsilon_r while leaving L unchanged (assuming non-magnetic dielectric), reducing Z_0 by the factor $1/\sqrt{\epsilon_r}. For example, in a coaxial line, the filled Z_0 becomes \frac{\eta_0}{2\pi \sqrt{\epsilon_r}} \ln\left(\frac{b}{a}\right), which lowers impedance and slows wave propagation to c / \sqrt{\epsilon_r}, where c is the speed of light in vacuum; this is commonly used to achieve 50 Ω or 75 Ω standards in cables like RG-58.[23][25]Waveguides
In hollow waveguides, electromagnetic waves are confined and propagate as transverse electric (TE) or transverse magnetic (TM) modes, with wave impedances that depend on the mode type, operating frequency, and waveguide geometry. These impedances differ from the intrinsic impedance η of the unbounded medium, which serves as a reference for plane wave propagation. Unlike transmission lines supporting transverse electromagnetic (TEM) modes, waveguides exhibit cutoff frequencies below which modes do not propagate, leading to frequency-dependent dispersion and impedance variations. For TE modes, the wave impedance is defined as the ratio of transverse electric to transverse magnetic field components and is given byZ_{\text{TE}} = \frac{\eta}{\sqrt{1 - \left( \frac{f_c}{f} \right)^2}} ,
where f_c is the cutoff frequency of the mode and f is the operating frequency; this expression arises from the propagation constant \beta = k \sqrt{1 - (f_c/f)^2}, with k = 2\pi f / c the free-space wavenumber.[26][27] For TM modes, the wave impedance is
Z_{\text{TM}} = \eta \sqrt{1 - \left( \frac{f_c}{f} \right)^2} ,
reflecting the swapped roles of electric and magnetic fields in the mode structure.[26][27] These mode-dependent impedances are greater than or less than η, respectively, and both approach infinity or zero at cutoff (f \to f_c), emphasizing the dispersive nature of guided propagation. The cutoff frequency for modes in a rectangular waveguide of broader dimension a is f_c = m c / (2a), where m is an integer mode index (e.g., m=1 for the dominant TE_{10} mode) and c is the speed of light in the medium; this determines the minimum frequency for propagation and influences the impedance through the term (f_c/f)^2.[26] The waveguide wavelength \lambda_g, defined as \lambda_g = \lambda / \sqrt{1 - (f_c/f)^2 } where \lambda = c/f is the free-space wavelength, directly relates to the wave impedance since \beta = 2\pi / \lambda_g, and Z_{\text{TE}} = \eta k / \beta or Z_{\text{TM}} = \eta \beta / k; thus, as \lambda_g lengthens near cutoff (with \lambda_g \to \infty at f = f_c), Z_{\text{TE}} increases while Z_{\text{TM}} decreases.[26][27] In practical systems, transitions between waveguide sections or to other structures (e.g., coaxial lines) often introduce impedance mismatches due to differing mode impedances or dimensions, resulting in partial reflections that manifest as standing waves characterized by the voltage standing wave ratio (VSWR).[27][28] High VSWR (>2:1) can degrade power transfer efficiency and increase losses, necessitating matching elements like tapers or irises to minimize reflections and maintain low VSWR (<1.5:1) across the operating band.[28]