(Created page with "1) <math> \begin{align*} \bar{k} &= k_x\hat{x} + k_y\hat{y}\\ &=\frac{2\pi}{\lambda x}\hat{x} + \frac{2\pi}{\lambda y}\hat{y}\\ &=\frac{2\pi}{3}\hat{x} +\frac{2\pi}{4}\hat{y}...") |
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E_0e^{-j(\frac{\pi}{2})y_0}[1 + e^{-j(\frac{\pi}{2}+\phi)}] =0 | E_0e^{-j(\frac{\pi}{2})y_0}[1 + e^{-j(\frac{\pi}{2}+\phi)}] =0 | ||
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| − | must add phase of \phi = \frac{\pi}{2} | + | |
| − | 1+e^{-j(\pi)} = 1+(-1) = 0 | + | must add phase of <math>\phi = \frac{\pi}{2}</math><br> |
| − | length of T_1: \frac{\lambda}{2} = \frac{\pi}{\beta} = T_1 | + | <math> 1+e^{-j(\pi)} = 1+(-1) = 0</math><br> |
| − | length of T_2: \lambda = \frac{2\pi}{\beta} = T_2 | + | length of <math> T_1: \frac{\lambda}{2} = \frac{\pi}{\beta} = T_1</math><br> |
| − | T_2-T_1 = \frac{\pi}{\beta} = \frac{\lambda}{2} | + | length of <math> T_2: \lambda = \frac{2\pi}{\beta} = T_2</math><br> |
| + | <math> T_2-T_1 = \frac{\pi}{\beta} = \frac{\lambda}{2}</math><br> | ||
Revision as of 16:27, 11 June 2017
1)
$ \begin{align*} \bar{k} &= k_x\hat{x} + k_y\hat{y}\\ &=\frac{2\pi}{\lambda x}\hat{x} + \frac{2\pi}{\lambda y}\hat{y}\\ &=\frac{2\pi}{3}\hat{x} +\frac{2\pi}{4}\hat{y}\\ |\bar{k}| &= \sqrt{\frac{4\pi^2}{9} + \frac{4\pi^2}{16}} = \beta=\frac{\omega}{c}\\ \omega &= c\frac{\frac{4\pi^2(25)}{144}} = \frac{10\pi c}{12} = \frac{10\pi}{4}\cdot10^8\\ f &= \frac{\omega}{2\pi} = \frac{5}{4}\cdot10^8\frac{1}{5} \end{align*} $
$ \left\{ \begin{array}{ll} \bar{k} = k(\hat{x}\cos\theta+\hat{y}\sin\theta)\\ \cos\theta = \frac{\lambda}{3}\\ \sin\theta = \frac{\lambda}{4}\\ \end{array} \right.\\ \bar{k} = \frac{2\pi}{\lambda}\big(\hat{x}\frac{\lambda}{3}+\hat{y}\frac{\lambda}{4}\big) = \big(\hat{x}\frac{2\pi}{3}+\hat{y}\frac{2\pi}{4}\big) $
2)
$ \begin{align*} \bar{k} &= \beta\cos\theta\hat{x} + \beta\sin\theta\hat{y}\\ \beta_0\cos\theta &= \frac{2\pi}{3}\\ \cos\theta =\frac{2\pi}{3}\bigg[\frac{1}{|k|}\bigg] &= \frac{2\pi}{3}\bigg[\frac{12}{10\pi}\bigg] = \frac{4}{5} \\ \theta &= \cos^{-1}\big( \frac{4}{5}\big)=35^\circ \end{align*} $
$ \beta_0\sin\theta=\frac{2\pi}{4} \sin\theta = \big(\frac{\pi}{2}\big)\big(\frac{12}{10\pi}\big) \sin\theta = \frac{3}{5} $
3)
$ k=\frac{2\pi}{3}\hat{x} + \frac{2\pi}{4}\hat{y} |k| = \frac{5\pi}{6} \lambda_x = 3m \lambda_y = 4m $
4)
$ \bar{E} = E_0e^{-j(\bar{k}\cdot\bar{r})} = E_0e^{-j\big(\frac{2\pi}{3}x +\frac{\pi}{2}y\big)} \bar{E}(x=0) = E_0e^{-j\big(\frac{\pi}{2}y\big)} $ \tan\big(\frac{2\pi}{\lambda}\frac{\lambda}{2}\big)=\tan\pi=0\\ Z_{in} = \frac{Z_0(Z_i)}{Z_0} = Z_i\\ \underline{at top antenna}: \bar{E} - E_0e^{-j(\frac{\pi}{2})(y_0+1)}\\ \underline{at bottom antenna}: \bar{E} - E_0e^{-j(\frac{\pi}{2})y_0}\\ then: \frac{|v_1+v_2|}{|v_1|} = \frac{|E_0e^{-j(\frac{\pi}{2})y_0}[1+e^{-j\frac{\pi}{2})}]|}{|E_0e^{-j(\frac{\pi}{2})y_0}|}=|1+\cos(\frac{\pi}{2}) -j\sin\frac{\pi}{2}|=|1+0-j|\\
= \sqrt{2}
5)
$ \bar{E}|_{x=0} = E_0e^{-j(0+0)} = E_0 \frac{|v_1+v_2|}{|v_1|} = \frac{|E_0+E_0|}{|E_0|} = \frac{2|E_0|}{|E_0|} =2 $
6)
$ \begin{align*} \bar{E}_i &= E_0e^{-j(\frac{2\pi}{3}x+\frac{2\pi}{4}y)}\hat{k}_i\\ \bar{E}_r &= \Gamma E_0e^{-j(-\frac{2\pi}{3}x+\frac{2\pi}{4}y)}\hat{k}_r \end{align*} $ ---only x component changes\\ ---for maximum v want maximum |\bar{E}|\\ ---\Gamma = -1
$ \bar{E} = \bar{E}_i + \bar{E}_r = E_0[e^{-j(\frac{2\pi}{3}x+\frac{2\pi}{4}y)}\hat{k}_i - e^{-j(-\frac{2\pi}{3}x+\frac{2\pi}{4}y)}\hat{k}_r] \bar{k}_i = \cos\theta_i\hat{x} + \sin\theta_i\hat{y} k_r = -\cos\theta_i\hat{x} + \sin\theta_i\hat{y} $ \to maximum of \cos\theta is 1 so, x = 3m: $ \bar{E}_r = E_0[-e^{j(2\pi)}e^{-j(\frac{\pi}{2})y}\hat{k}_r] = -E_0e^{-j(\frac{\pi}{2})y}\hat{k}_r $
7)
$ V_{out}=V_1+V_2=0=E_1+E_2 E_0e^{-j(\frac{\pi}{2})y_0} + E_0e^{-j(\frac{\pi}{2})y_0+1} =0 E_0e^{-j(\frac{\pi}{2})y_0}[1 + e^{-j(\frac{\pi}{2}+\phi)}] =0 $
must add phase of $ \phi = \frac{\pi}{2} $
$ 1+e^{-j(\pi)} = 1+(-1) = 0 $
length of $ T_1: \frac{\lambda}{2} = \frac{\pi}{\beta} = T_1 $
length of $ T_2: \lambda = \frac{2\pi}{\beta} = T_2 $
$ T_2-T_1 = \frac{\pi}{\beta} = \frac{\lambda}{2} $
