Reflexión electromagnética/Índice/Anexos y demostraciones


Español
Sumario 1 Anexos 1.1 Demostración Ecuación 3.19 1.2 Demostración del ángulo de Brewster 1.3 Demostración de la ecuación 3.20 1.4 Demostración ecuación 3.24 Anexos Demostración Ecuación 3.19 $ε_{i} = ε_{0} ε_{r}$ $μ = μ_{0} μ_{r}$ $z < 0 = ε_{1}, G_{1}, μ_{1}$ $z > 0 = ε_{2}, G_{2}, μ_{2}$ $ε_{i} = H_{i}$ $H_{i} = B_{i} \sin (90 - θ_{i})$ $B_{i} = ω \sqrt{μ_{i} ε_{i}}$ $ε_{r} = H_{r}$ $H_{r} = B_{r} \sin (90 - θ_{r})$ $B_{r} = ω \sqrt{μ_{r} ε_{r}}$ $ε_{t} = H_{t}$ $H_{t} = B_{t} \sin (90 - θ_{t})$ $B_{t} = ω \sqrt{μ_{t} ε_{t}}$ $ε_{i} + ε_{r} = ε_{t}$ $ε_{i} = ε_{r} + ε_{t}$ $ε_{r} = ε_{i} - ε_{t}$ $ε_{t} = ε_{i} - ε_{r}$ $ε_{i} = ε_{i} - ε_{t} + ε_{i} - ε_{r}$ $ε_{r} + ε_{t} = ε_{i} - ε_{t} + ε_{i} - ε_{r}$ $B_{r} \sin (θ_{r}) + B_{t} \sin (θ_{t}) = B_{i} \sin (θ_{i}) - B_{t} \sin (θ_{t}) + B_{i} \sin (θ_{i}) - B_{r} \sin (θ_{r})$ $θ = - B_{r} \sin (θ_{r}) + B_{t} \sin (θ_{t}) + B_{i} \sin (θ_{i}) - B_{t} \sin (θ_{t}) + B_{i} \sin (θ_{i}) - B_{r} \sin (θ_{r})$ $θ_{r} = B_{i} θ_{r} = θ_{i}$ $B_{t} \sin (θ_{t}) - B_{i} \sin (θ_{i}) = - ω \sqrt{μ_{r} ε_{r}} \sin (θ_{r}) - ω \sqrt{μ_{t} ε_{t}} \sin (θ_{t}) + ω \sqrt{μ_{i} ε_{i}} \sin (θ_{i}) - ω \sqrt{μ_{t} ε_{t}} \sin (θ_{t})$ $ω \sqrt{μ_{t} ε_{t}} \sin (θ_{t}) - ω \sqrt{μ_{i} ε_{i}} \sin (θ_{i}) = - ω \sqrt{μ_{r} ε_{r}} \sin (θ_{r}) - ω \sqrt{μ_{t} ε_{t}} \sin (θ_{t}) + ω \sqrt{μ_{i} ε_{i}} \sin (θ_{i}) - ω \sqrt{μ_{r} ε_{r}} \sin (θ_{r})$ $ω (\sqrt{μ_{t} ε_{t}} \sin (θ_{t}) - ω \sqrt{μ_{i} ε_{i}} \sin (θ_{i})) = - 2 ω \sqrt{μ_{r} ε_{r}} \sin (θ_{r}) - (ω \sqrt{μ_{t} ε_{t}} \sin (θ_{t}) + ω \sqrt{μ_{i} ε_{i}} \sin (θ_{i}))$ $η_{1} = μ_{i} ε_{i} = μ_{r} ε_{r} {η_{2} = μ}_{t} ε_{t}$ $ω (η_{2} \sin (θ_{t}) - η_{1} \sin (θ_{i})) = - ω B_{i} \sin (θ_{i}) + ω B_{r} \sin (θ_{r}) - ω (η_{2} \sin (θ_{t}) + η_{1} \sin (θ_{i}))$ $\frac{ω (η_{2} \sin (θ_{t}) - η_{1} \sin (θ_{i}))}{(η_{2} \sin (θ_{t}) - η_{1} \sin (θ_{i}))} = \frac{(ω + ω B_{r} \sin (θ_{r}))}{ω B_{i} \sin (θ_{i})}$ $Γ_{\| \|} = \frac{E_{r}}{E_{i}} = \frac{η_{2} s i n θ_{t} - η_{1} s i n θ_{i}}{η_{2} s i n θ_{t} + η_{1} s i n θ_{i}}$ Demostración del ángulo de Brewster Es importante mencionar que se demostrará en distintos espacios se probará: En primer lugar, es cuando la permitividad sea distinta en ambos medios. para demostrar se usan las ecuaciones 3.27 y 3.19 que relacionan la premitividad distinta $s i n (θ_{B}) = \sqrt{\frac{ε_{1}}{ε_{1} + ε_{2}}}$ Ec. 3.27 $Γ_{∥} = \frac{η_{2} \sin θ_{t} - η_{1} \sin θ_{i}}{η_{2} \sin θ_{t} + η_{1} \sin θ_{i}}$ Ec. 3.19 $0 = \frac{η_{2} \sin θ_{t} - η_{1} \sin θ_{i}}{η_{2} \sin θ_{t} + η_{1} \sin θ_{i}}$ $0 = η_{2} \sin θ_{t} - η_{1} \sin θ_{i}$ $\sqrt{\frac{μ_{2}}{ε_{2}}} \sin θ_{t} = \sqrt{\frac{μ_{1}}{ε_{1}}} \sin θ_{i}$ $\sqrt{μ_{2} ε_{1}} \sin θ_{t} = \sqrt{μ_{1} ε_{2}} \sin θ_{i}$ $μ_{2} ε_{1} \sin^{2} θ_{t} = μ_{1} ε_{2} \sin^{2} θ_{i}$ $\frac{μ_{1} ε_{2}}{μ_{2} ε_{1}} \sin^{2} θ_{i} = \sin^{2} θ_{t}$ $\frac{μ_{1} ε_{2}}{μ_{2} ε_{1}} \sin^{2} θ_{i} = (1 - \cos^{2} θ_{t})$ $\frac{μ_{1} ε_{2}}{μ_{2} ε_{1}} \sin^{2} θ_{i} = 1 - \frac{μ_{1} ε_{1}}{μ_{2} ε_{2}} \cos^{2} θ_{i}$ $(\frac{μ_{1} ε_{2}}{μ_{2} ε_{1}} - \frac{μ_{1} ε_{1}}{μ_{2} ε_{2}}) \sin^{2} θ_{i} = 1 - \frac{μ_{1} ε_{1}}{μ_{2} ε_{2}}$ $\frac{μ_{1}}{μ_{2}} (\frac{ε_{2}}{ε_{1}} - \frac{ε_{1}}{ε_{2}}) \sin^{2} θ_{i} = 1 - \frac{μ_{1} ε_{1}}{μ_{2} ε_{2}}$ $\sin^{2} θ_{i} = \frac{\frac{μ_{2}}{μ_{1}} - \frac{ε_{1}}{ε_{2}}}{\frac{ε_{2}}{ε_{1}} - \frac{ε_{1}}{ε_{2}}}$ $\sin θ_{i} = \sqrt{\frac{\frac{μ_{2}}{μ_{1}} - \frac{ε_{1}}{ε_{2}}}{\frac{ε_{2}}{ε_{1}} - \frac{ε_{1}}{ε_{2}}}}$ Para el angulo de brewster se puede considerar que: $μ_{2} = μ_{1}$ $\sin θ_{i} = \sqrt{\frac{1 - \frac{ε_{1}}{ε_{2}}}{\frac{ε_{2}}{ε_{1}} - \frac{ε_{1}}{ε_{2}}}}$ $\sin θ_{i} = \sqrt{\frac{\frac{ε_{2} - ε_{1}}{ε_{2}}}{\frac{ε_{2}^{2} - ε_{1}^{2}}{ε_{1} ε_{2}}}}$ $\sin θ_{i} = \sqrt{\frac{ε_{1} (ε_{2} - ε_{1})}{ε_{2}^{2} - ε_{1}^{2}}}$ $\sin θ_{i} = \sqrt{\frac{ε_{1} (ε_{2} - ε_{1})}{(ε_{2} - ε_{1}) (ε_{2} + ε_{1})}}$ En este punto se demostró de donde sale la ecuacion 3.27 cuando $μ_{2} = μ_{1}$ $s i n (θ_{B}) = \sqrt{\frac{ε_{1}}{ε_{1} + ε_{2}}}$ En segundo lugar, para el caso en el que la onda se propague en el espacio libre se usa la ecuacion 3.28 y la 3.24. $s i n (θ_{B}) = \frac{\sqrt{ε_{r} - 1}}{\sqrt{ε_{r}^{2} - 1}}$ Ec. 3.28 $Γ_{∥} = \frac{- ε_{r} \sin θ_{i} + \sqrt{ε_{r} - \cos^{2} θ_{i}}}{ε_{r} \sin θ_{i} + \sqrt{ε_{r} - \cos^{2} θ_{i}}}$ Ec. 3.24 Polarización vertical $0 = \frac{- ε_{r} \sin θ_{i} + \sqrt{ε_{r} - \cos^{2} θ_{i}}}{ε_{r} \sin θ_{i} + \sqrt{ε_{r} - \cos^{2} θ_{i}}}$ $0 = - ε_{r} \sin θ_{i} + \sqrt{ε_{r} - \cos^{2} θ_{i}}$ $ε_{r} \sin θ_{i} = \sqrt{ε_{r} - \cos^{2} θ_{i}}$ ${(ε_{r} \sin θ_{i})}^{2} = ε_{r} - \cos^{2} θ_{i}$ $ε_{r}^{2} \sin θ_{i}^{2} = ε_{r} - \cos^{2} θ_{i}$ $ε_{r}^{2} \sin θ_{i}^{2} = ε_{r} + \sin^{2} θ_{i} - 1$ $ε_{r}^{2} \sin θ_{i}^{2} - \sin^{2} θ_{i} = ε_{r} - 1$ $(ε_{r}^{2} - 1) \sin^{2} θ_{i} = ε_{r} - 1$ $\sin^{2} θ_{i} = \frac{ε_{r} - 1}{ε_{r}^{2} - 1}$ En este punto se demostró de donde sale la ecuacion 3.28 par el uso en espacio libre. $\sin θ_{i} = \sqrt{\frac{ε_{r} - 1}{ε_{r}^{2} - 1}}$ Demostración de la ecuación 3.20 La demostración de la ecuación presentada en el libro Rappaport, la ecuación 3.20 $\frac{E_{r}}{E_{i}} = \frac{η_{2} \sin θ_{t} - η_{1} * \sin θ_{i}}{η_{2} \sin θ_{t} + η_{1} * \sin θ_{i}}$ Partiendo de la ecuacion presentada anteriormente, empezaremos a hacer el analisis mediante la grafica b de la pagina 452 del libro de Matthew. $ε_{i} = ε_{0} + ε_{r}$ $z < 0 = ε_{1}, G_{1}, μ_{1}$ $z > 0 = ε_{2}, G_{2}, μ_{2}$ $ε_{i} = H_{i}$ $H_{i} = B_{i} \sin (θ_{i})$ $B_{i} = ω \sqrt{μ_{i} ε_{i}}$ $ε_{r} = H_{r}$ $H_{r} = B_{r} \sin (θ_{r})$ $B_{r} = ω \sqrt{μ_{r} ε_{r}}$ $ε_{t} = H_{t}$ $H_{t} = B_{t} \sin (θ_{t})$ $B_{t} = ω \sqrt{μ_{t} ε_{t}}$ $E_{i} + - E_{r} = E_{t}$ $E_{i} = E_{r} + E_{t}$ $E_{r} = E_{i} - E_{t}$ $E_{t} = E_{i} - E_{r}$ $E_{i} = E_{i} - E_{t} + E_{i} - E_{r}$ $E_{r} + E_{t} = E_{i} - E_{t} + E_{i} - E_{r}$ $B_{r} \sin (θ_{r}) + B_{t} \sin (θ_{t}) = B_{i} \sin (θ_{i}) - B_{t} \sin (θ_{t}) + B_{i} \sin (θ_{i}) - B_{r} \sin (θ_{r})$ $0 = - B_{r} \sin (θ_{r}) + B_{t} \sin (θ_{t}) + B_{i} \sin (θ_{i}) - B_{t} \sin (θ_{t}) + B_{i} \sin (θ_{i}) - B_{r} \sin (θ_{r})$ $θ_{r} = θ_{i}$ $B_{t} \sin (θ_{t}) - B_{i} \sin (θ_{i}) = - ω \sqrt{μ_{r} ε_{r}} \sin (θ_{r}) - ω \sqrt{μ_{t} ε_{t}} \sin (θ_{t}) + ω \sqrt{μ_{i} ε_{i}} \sin (θ_{i}) - ω \sqrt{μ_{t} ε_{t}} \sin (θ_{t})$ $ω \sqrt{μ_{t} ε_{t}} \sin (θ_{t}) - ω \sqrt{μ_{i} ε_{i}} \sin (θ_{i}) = - ω \sqrt{μ_{r} ε_{r}} \sin (θ_{r}) - ω \sqrt{μ_{t} ε_{t}} \sin (θ_{t}) + ω \sqrt{μ_{i} ε_{i}} \sin (θ_{i}) - ω \sqrt{μ_{r} ε_{r}} \sin (θ_{r})$ $ω (\sqrt{μ_{t} ε_{t}} \sin (θ_{t}) - ω \sqrt{μ_{i} ε_{i}} \sin (θ_{i})) = - 2 ω \sqrt{μ_{r} ε_{r}} \sin (θ_{r}) - ω (\sqrt{μ_{t} ε_{t}} \sin (θ_{t}) + ω \sqrt{μ_{i} ε_{i}} \sin (θ_{i}))$ $η_{1} = \sqrt{μ_{i} ε_{i}}$ $η_{2} = \sqrt{μ_{t} ε_{t}}$ $ω (η_{2} \sin (θ_{t}) - η_{1} \sin (θ_{i})) = - ω_{i} \sin (θ_{i}) + ω_{r} \sin (θ_{r}) - ω (η_{2} \sin (θ_{t}) + η_{1} \sin (θ_{i}))$ $ω \sin θ_{i} (η_{2} \sin θ_{t} - η_{1} \sin θ_{i}) / η_{1} \sin θ_{i} + \sin θ_{t} = ω + ω B_{r} \sin θ_{r}$ $η_{2} \sin θ_{t} - η_{1} \sin θ_{i}) / (η_{1} \sin θ_{i} + η_{2} \sin θ_{t}) = B_{r} \sin θ_{r} / B_{i} \sin θ_{i}$ $E_{i} = B_{i} \sin θ_{i}$ $E_{r} = B_{r} \sin θ_{r}$ Realizando los cambios correspondientes obtendremos la siguiente ecuacion: $Γ_{I} = \frac{ε_{r}}{ε_{i}} = \frac{η_{2} \sin (θ_{t}) - η_{1} \sin (θ_{i}))}{η_{2} \sin (θ_{t}) + η_{1} \sin (θ_{i}))}$ Demostración ecuación 3.24 $η_{1} = \sqrt{\frac{μ}{ϵ_{0}}} * η_{2} = \sqrt{{\frac{μ}{ϵ}}_{2}}$ $\sqrt{ϵ_{0} μ_{0}} \sin 90 - θ_{i} = \sqrt{ϵ_{2} μ_{0}} s i n 90 - θ_{t}$ $\sqrt{\frac{μ_{0} ϵ_{0}}{μ_{0} ϵ_{2}}} \sin (90 - θ_{i}) = \sin (90 - θ_{t})$ $\sqrt{\frac{ϵ_{0}}{ϵ_{2}}} \sin (90 - θ_{i}) = \sin (90 - θ_{t})$ Entidades trigonométricas $\sin (90 - θ_{i}) = \cos θ_{i}$ $\cos^{2} θ_{i} = 1 - \sin^{2} (90 - θ_{i})$ $(\sqrt{\frac{ϵ_{0}}{ϵ_{2}}} * \cos θ_{i} = \cos θ_{t})^{2}$ $\frac{ϵ_{0}}{ϵ_{2}} \cos^{2} θ_{i} = \cos^{2} θ_{t}$ $\frac{ϵ_{0}}{ϵ_{2}} \cos^{2} θ_{i} = 1 - \sin^{2} (θ_{t})$ $\sin^{2} (θ_{t}) = 1 - \frac{ϵ_{0}}{ϵ_{2}} \cos^{2} θ_{i}$ $(\frac{ϵ_{2}}{ϵ_{0}}) \sin^{2} (θ_{t}) = 1 - \frac{ϵ_{0}}{ϵ_{2}} \cos^{2} θ_{i} (\frac{ϵ_{2}}{ϵ_{0}})$ Permitividad del vacío: $ϵ_{r} = \frac{ϵ_{2}}{ϵ_{0}}$ $ϵ_{r} \sin^{2} θ_{t} = ϵ_{r} - \cos^{2} θ_{i}$ $\sqrt{(ϵ_{r} \sin^{2} θ_{t} = ϵ_{r} - \cos^{2} θ_{i})}$ $\sqrt{ϵ_{r}} \sin θ_{t} = \sqrt{ϵ_{r} - \cos^{2} θ_{i}}$ $Γ_{\| \|} = \frac{η_{2} s i n θ_{t} - η_{1} s i n θ_{i}}{η_{2} s i n θ_{t} + η_{1} s i n θ_{i}}$ $Γ_{\| \|} = \frac{\sqrt{ϵ_{r} - \cos^{2} θ_{i}} - ϵ_{r} \sin θ_{i}}{\sqrt{ϵ_{r} - \cos^{2} θ_{i}} + ϵ_{r} \sin θ_{i}}$ $Γ_{\| \|} = \frac{- ϵ_{r} \sin θ_{i} + \sqrt{ϵ_{r} - \cos^{2} θ_{i}}}{\sqrt{ϵ_{r} - \cos^{2} θ_{i}} + ϵ_{r} \sin θ_{i}}$ Se demuestra la ecuación 3.24 ESTE PROGRAMA REALIZA LA OPERACIÓN DE LA FUNCIÓN GAMA import keyword; #keyword.iskeyword('pass') import keyword import math from Lxtx2 import * print('Coeficiente de reflexión') print('presione 1 para continuar') S=int(input()) if (S==1): print('ingrese Efectividad relativa:') Er=int(input()) print('ingrese theta: ') T=int(input()) #print (Er, T) Gamma(Er,T) ( import keyword; keyword.iskeyword('pass') import keyword import math def Gamma(Er,T):\\ print ("en grados es:", math.radians(T)) n=(math.sin(math.radians(T))- math.sqrt(Er-(math.cos(math.radians(T))2))) d=(math.sin(math.radians(T))+ math.sqrt(Er-(math.cos(math.radians(T))2))) divi=n/d posi=abs(divi) print("Gama perpendicular es:",posi) ( import keyword; keyword.iskeyword('pass') import keyword import math def Gamma(Er,T): print ("en grados es:", math.radians(T)) n=(-Ermath.sin(math.radians(T))+ math.sqrt(Er-(math.cos(math.radians(T))2))) d=(Ermath.sin(math.radians(T))+ math.sqrt(Er-(math.cos(math.radians(T))**2 divi=n/d posi=abs(divi) print("Gama paralelo es:",posi) )

Reflexión electromagnética/Índice/Anexos y demostraciones

Anexos

Demostración Ecuación 3.19

Demostración del ángulo de Brewster

Demostración de la ecuación 3.20

Demostración ecuación 3.24

Menú de navegación

Buscar