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clc;
close();
clear();
//page no 557
//prob no. 17.9
EIRP_dBW=47.8; //dBW
l=91-90; //Difference in longitude
L=32 //Latitude of New York
d_km=35.786*10^3*sqrt(1+0.42*(1-cos(L*%pi/180)*cos(l*%pi/180)));
mprintf('The distance is %.0f km \n',d_km)
f=3.9 //downlink frequency in GHz
alfa1_dB=20*log10(f)+20*log10(d_km)+92.44; //Path loss
mprintf('The path loss is %.2f dB \n',alfa1_dB)
F=1.778 //absolute noise figure
Te=(F-1)*290; //Noise temperature
mprintf('The Noise temperature of satellite reciever is %.2f K \n',Te)
Ti=150; //input noise temperature in K
Tsys=Ti+Te
mprintf('The system temperature of satellite reciever is %.2f K \n',Tsys)
G_dB=42 //satellite reciever antwnna gain
GT=G_dB-10*log10(Tsys); //G/T ratio in dB
mprintf('The G/T ratio for satellite reciever is %.2f dB/K \n',GT)
B=36*10^6 ;// Bandwidth in Hz
L_misc=1 //atmospheric loss
CN=EIRP_dBW-alfa1_dB+GT+228.6-10*log10(B)-L_misc; //C/N in dB
mprintf('The carrier power to noise ratio at the satellite reciever is %.1f dB \n',CN)
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