Extract: ● I E(x, t)=-9.25. cos (105nt+ ·x+ 18 3 The phase velocity. The period of the wave. ● The wavelength. • The direction of propagation. ● The attenuation number.

EMWAVE(NEED A NEAT HANDWRITTEN SOLUTION ONLY OTHERWISE DOWNVOTE)

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### Wave Analysis Consider the wave equation given by: \[ \vec{E}(x, t) = -\hat{y} 9.25 \cos \left(10^5 \pi t + \frac{\pi}{18} x + \frac{\pi}{3} \right) \] Let's extract some key properties of this wave: - **The Phase Velocity:** The phase velocity \( v_p \) of the wave. - **The Period of the Wave:** The period \( T \) of the wave. - **The Wavelength:** The distance \( \lambda \) between successive peaks of the wave. - **The Direction of Propagation:** The direction in which the wave is moving. - **The Attenuation Number:** Any attenuation factor, if present, that signifies how the wave diminishes in amplitude over distance or time. ### Analysis 1. **The Phase Velocity ( \( v_p \) ):** Phase velocity \( v_p \) is given by \( v_p = \frac{\omega}{k} \), where \( \omega \) is the angular frequency and \( k \) is the wave number. 2. **The Period of the Wave ( \( T \) ):** The period can be derived from the angular frequency \( \omega \) using \( T = \frac{2\pi}{\omega} \). 3. **The Wavelength ( \( \lambda \) ):** The wavelength can be found using the wave number \( k \) with the relation \( \lambda = \frac{2\pi}{k} \). 4. **The Direction of Propagation:** The wave propagates in a direction determined by the sign and coefficients of \( x \) and \( t \) in the cosine argument. 5. **The Attenuation Number:** The wave equation presents no exponential decay factors, so there is no attenuation implied in the provided equation. ### Detailed Derivation 1. **Finding \( k \) and \( \omega \):** From the given wave equation: \[ \vec{E}(x, t) = -\hat{y} 9.25 \cos \left(10^5 \pi t + \frac{\pi}{18} x + \frac{\pi}{3} \right) \] - \( \omega = 10^5 \pi \) -