% OFDM_basic.m
clear all
NgType=1; % Ng Type=1/2 for cyclic prefix/zero padding
if NgType==1
nt='CP';
elseif NgType==2
nt='ZP';
end
Ch=1; % Ch=0/1 for AWGN/multipath channel
if Ch==0, chType='AWGN'; Target_neb=100; else chType='CH'; Target_neb=500; end
figure(Ch+1), clf %清除前面的figure
PowerdB=[0 -8 -17 -21 -25]; % Channel tap power profile ’dB’
Delay=[0 3 5 6 8]; % Channel delay ’sample’
Power=10.^(PowerdB/10); % Channel tap power profile ’linear scale’
Ntap=length(PowerdB); % Chanel tap number
Lch=Delay(end)+1; % Channel length
Nbps=4;
M=2^Nbps; % Modulation order=2/4/6 for QPSK/16QAM/64QAM
Nfft=64; % FFT size
Ng=16; % GI (Guard Interval) length (Ng=0 for no GI)
Nsym=Nfft+Ng; % Symbol duration
Nvc=Nfft/4; % Nvc=0: no VC (virtual carrier)
Nused=Nfft-Nvc;
EbN0=[0:5:30]; % Eb N0用冒号表示非相邻的多个元素
N_iter=1e5; % Number of iterations for each Eb N0迭代次数
Nframe=3; % Number of symbols per frame每一帧的符号数
sigPow=0; % Signal power initialization初始信号功率
file_name=['OFDM_BER_' chType '_''GL' num2str(Ng) ' .dat '];
fid=fopen(file_name,'w+');
norms=[1 sqrt(2) 0 sqrt(10) 0 sqrt(42)]; % BPSK 4-QAM 16-QAM
for i=0:length(EbN0) %返回行数和列数两者之间数值较大的那一个值
randn('state',0);
rand('state',0);
Ber2=ber_QAM(0,0,0); % BER initialization 初始化BER
Neb=0; Ntb=0; % Initialize the number of error/total bits
for m=1:N_iter
% Tx______________________________________________________________
X= randi(M-1,1,Nused*Nframe); % bit: integer vector
Xmod= qammod(X,M,0,'gray')/norms(Nbps); %正交幅度调制调制QAM
if NgType~=2, x_GI=zeros(1,Nframe*Nsym);
elseif NgType==2, x_GI= zeros(1,Nframe*Nsym+Ng);
% Extend an OFDM symbol by Ng zeros
end
kk1=[1:Nused/2]; kk2=[Nused/2+1:Nused]; kk3=1:Nfft; kk4=1:Nsym;
for k=1:Nframe
if Nvc~=0, X_shift= [0 Xmod(kk2) zeros(1,Nvc-1) Xmod(kk1)];
else X_shift= [Xmod(kk2) Xmod(kk1)];
end
x= ifft(X_shift);
x_GI(kk4)= guard_interval(Ng,Nfft,NgType,x);
kk1=kk1+Nused; kk2= kk2+Nused; kk3=kk3+Nfft; kk4=kk4+Nsym;
end
if Ch==0, y= x_GI; % No channel
else % Multipath fading channel
channel=(randn(1,Ntap)+j*randn(1,Ntap)).*sqrt(Power/2);
h=zeros(1,Lch); h(Delay+1)=channel; % cir: channel impulse response
y = conv(x_GI,h);
end
if i==0 % Only to measure the signal power for adding AWGN noise
y1=y(1:Nframe*Nsym); sigPow = sigPow + y1*y1'; continue;
end
% Add AWGN noise________________________________________________
snr = EbN0(i)+10*log10(Nbps*(Nused/Nfft)); % SNR vs. Eb/N0 by Eq.(4.28)
noise_mag = sqrt((10.^(-snr/10))*sigPow/2);
y_GI = y + noise_mag*(randn(size(y))+j*randn(size(y)));
% Rx_____________________________________________________________
kk1=(NgType==2)*Ng+[1:Nsym]; kk2=1:Nfft;
kk3=1:Nused; kk4=Nused/2+Nvc+1:Nfft; kk5=(Nvc~=0)+[1:Nused/2];
if Ch==1
H= fft([h zeros(1,Nfft-Lch)]); % Channel frequency response
H_shift(kk3)= [H(kk4) H(kk5)];
end
for k=1:Nframe
Y(kk2)= fft(remove_GI(Ng,Nsym,NgType,y_GI(kk1)));
Y_shift=[Y(kk4) Y(kk5)];
if Ch==0, Xmod_r(kk3) = Y_shift;
else Xmod_r(kk3)=Y_shift./H_shift; % Equalizer - channel compensation
end
kk1=kk1+Nsym; kk2=kk2+Nfft; kk3=kk3+Nused; kk4=kk4+Nfft;
kk5=kk5+Nfft;
end
X_r=qamdemod(Xmod_r*norms(Nbps),M,0,'gray');
Neb=Neb+sum(sum(de2bi(X_r,Nbps)~=de2bi(X,Nbps)));
Ntb=Ntb+Nused*Nframe*Nbps; %[Ber,Neb,Ntb]=ber(bit_Rx,bit,Nbps);
if Neb>Target_neb, break; end
end
if i==0, sigPow= sigPow/Nsym/Nframe/N_iter;
else
Ber = Neb/Ntb;
fprintf('EbN0=%3d[dB], BER=%4d/%8d =%11.3e\n', ......
EbN0(i), Neb,Ntb,Ber)
fprintf(fid, '%d\t%11.3e\n', EbN0(i), Ber);
if Ber<1e-6, break; end
end
end
if (fid~=0), fclose(fid); end
plot_ber(file_name,Nbps);