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- https://phys.libretexts.org/Bookshelves/Electricity_and_Magnetism/Electromagnetics_and_Applications_(Staelin)/13%3A_Acoustics/13.01%3A_Acoustic_WavesThis page provides an overview of wave phenomena with a focus on acoustic waves, comparing them to electromagnetic waves in theory and application. It discusses the mathematical formulation of acousti...This page provides an overview of wave phenomena with a focus on acoustic waves, comparing them to electromagnetic waves in theory and application. It discusses the mathematical formulation of acoustic wave equations, phase and group velocities, and their propagation characteristics. Key concepts such as acoustic impedance, intensity, and energy balance in resonators are explored, alongside practical examples.
- https://phys.libretexts.org/Bookshelves/Electricity_and_Magnetism/Electromagnetics_and_Applications_(Staelin)/08%3A_Fast_electronics_and_transient_behavior_on_TEM_lines/8.03%3A_Distortions_due_to_loss_and_dispersionThis page discusses the challenges posed by lossy transmission lines in electronics due to resistance and leakage, affecting signal integrity, particularly in integrated circuits. Key concepts include...This page discusses the challenges posed by lossy transmission lines in electronics due to resistance and leakage, affecting signal integrity, particularly in integrated circuits. Key concepts include the telegraphers' equations, frequency-dependent propagation, and the balance of R/L and G/C.
- https://phys.libretexts.org/Bookshelves/Electricity_and_Magnetism/Electromagnetics_and_Applications_(Staelin)/09%3A_Electromagnetic_Waves/9.01%3A_Waves_at_planar_boundaries_at_normal_incidenceThis page explores boundary value problems in electromagnetics, emphasizing the uniqueness of solutions from Maxwell's equations and boundary conditions. It presents a four-step method for solving the...This page explores boundary value problems in electromagnetics, emphasizing the uniqueness of solutions from Maxwell's equations and boundary conditions. It presents a four-step method for solving these problems and uses practical examples, including wave reflection at a perfect conductor and power reflection at a dielectric interface.
- https://phys.libretexts.org/Bookshelves/Electricity_and_Magnetism/Electromagnetics_and_Applications_(Staelin)/02%3A_Introduction_to_Electrodynamics/2.03%3A_Maxwell%E2%80%99s_equations%2C_waves%2C_and_polarization_in_the_frequency_domainThis page explores linear systems in relation to sinusoidal inputs, emphasizing wave manipulation through complex notation. It highlights the use of phasors in simplifying Maxwell's equations and deri...This page explores linear systems in relation to sinusoidal inputs, emphasizing wave manipulation through complex notation. It highlights the use of phasors in simplifying Maxwell's equations and deriving the Helmholtz wave equation. The relationship between phasor and time-domain expressions, governed by Faraday's law, is discussed alongside various polarization states, including linear and circular polarizations, and their representations.
- https://phys.libretexts.org/Bookshelves/Electricity_and_Magnetism/Electromagnetics_and_Applications_(Staelin)/10%3A_Antennas_and_Radiation/10.04%3A_Antenna_arraysThis page discusses enhancements in dipole antenna arrays, including increased gain, beam steering, and simultaneous transmissions through configurations and effective area adjustments. It highlights ...This page discusses enhancements in dipole antenna arrays, including increased gain, beam steering, and simultaneous transmissions through configurations and effective area adjustments. It highlights the use of mirrors to improve short dipole antenna gain and analysis of uniform dipole arrays, focusing on element factors and phase variations affecting radiation patterns.
