1.问题描述:


2.部分程序:

function L_all = sova(rec_s, g, L_a, ind_dec) 
% This function implememts Soft Output Viterbi Algorithm in trace back mode
% Input:
% rec_s: scaled received bits. rec_s(k) = 0.5 * L_c(k) * y(k)
% L_c = 4 * a * Es/No, reliability value of the channel
% y: received bits
% g: encoder generator matrix in binary form, g(1,:) for feedback, g(2,:) for feedforward
% L_a: a priori information about the info. bits. Extrinsic info. from the previous
% component decoder
% ind_dec: index of the component decoder.
% =1: component decoder 1; The trellis is terminated to all zero state
% =2: component decoder 2; The trellis is not perfectly terminated.
% Output:
% L_all: log ( P(x=1|y) ) / ( P(x=-1|y) )
% % Frame size, info. + tail bits
L_total = length(L_a);
[n,K] = size(g);
m = K - 1;
nstates = 2^m;
Infty = 1e10;% SOVA window size. Make decision after 'delta' delay. Decide bit k when received bits
% for bit (k+delta) are processed. Trace back from (k+delta) to k.
delta = 30; % Set up the trellis defined by g.
[next_out, next_state, last_out, last_state] = trellis(g);% Initialize path metrics to -Infty
for t=1:L_total+1
for state=1:nstates
path_metric(state,t) = -Infty;
end
end% Trace forward to compute all the path metrics
path_metric(1,1) = 0;
for t=1:L_total
y = rec_s(2*t-1:2*t);
for state=1:nstates
sym0 = last_out(state,1:2);
sym1 = last_out(state,3:4);
state0 = last_state(state,1);
state1 = last_state(state,2);
Mk0 = y*sym0' - L_a(t)/2 + path_metric(state0,t);
Mk1 = y*sym1' + L_a(t)/2 + path_metric(state1,t);

if Mk0>Mk1
path_metric(state,t+1)=Mk0;
Mdiff(state,t+1) = Mk0 - Mk1;
prev_bit(state, t+1) = 0;
else
path_metric(state,t+1)=Mk1;
Mdiff(state,t+1) = Mk1 - Mk0;
prev_bit(state,t+1) = 1;
end end
end

% For decoder 1, trace back from all zero state,
% for decoder two, trace back from the most likely state
if ind_dec == 1
mlstate(L_total+1) = 1;
else
mlstate(L_total+1) = find( path_metric(:,L_total+1)==max(path_metric(:,L_total+1)) );
end% Trace back to get the estimated bits, and the most likely path
for t=L_total:-1:1
est(t) = prev_bit(mlstate(t+1),t+1);
mlstate(t) = last_state(mlstate(t+1), est(t)+1);
end% Find the minimum delta that corresponds to a compitition path with different info. bit estimation.
% Give the soft output
for t=1:L_total
llr = Infty;
for i=0:delta
if t+i<L_total+1
bit = 1-est(t+i);
temp_state = last_state(mlstate(t+i+1), bit+1);
for j=i-1:-1:0
bit = prev_bit(temp_state,t+j+1);
temp_state = last_state(temp_state, bit+1);
end
if bit~=est(t)
llr = min( llr,Mdiff(mlstate(t+i+1), t+i+1) );
end
end
end
L_all(t) = (2*est(t) - 1) * llr;
end


function L_all = logmapo(rec_s,g,L_a,ind_dec)
% Log_MAP algorithm using straightforward method to compute branch metrics
% no approximation is used.
% Can be simplified to Max-Log-MAP by using approximation ln(e^x+e^y) = max(x,y).
% Input: rec_s: scaled received bits.
% rec_s = 0.5 * L_c * yk = ( 2 * a * rate * Eb/N0 ) * yk
% g: code generator for the component RSC code, in binary matrix form.
% L_a: a priori info. for the current decoder,
% scrambled version of extrinsic Inftyo. of the previous decoder.
% ind_dec: index of decoder. Either 1 or 2.
% Encoder 1 is assumed to be terminated, while encoder 2 is open.
%
% Output: L_all: log-likelihood ratio of the symbols. Complete information. % Total number of bits: Inftyo. + tail
L_total = length(rec_s)/2;
[n,K] = size(g);
m = K - 1;
nstates = 2^m; % Set up the trellis
[next_out, next_state, last_out, last_state] = trellis(g);Infty = 1e10;
% Initialization of Alpha
Alpha(1,1) = 0;
Alpha(1,2:nstates) = -Infty*ones(1,nstates-1);% Initialization of Beta
if ind_dec==1
Beta(L_total,1) = 0;
Beta(L_total,2:nstates) = -Infty*ones(1,nstates-1);
elseif ind_dec==2
Beta(L_total,1:nstates) = zeros(1,nstates);
else
fprintf('ind_dec is limited to 1 and 2!\n');
end% Trace forward, compute Alpha
for k = 2:L_total+1
for state2 = 1:nstates
gamma = -Infty*ones(1,nstates);
gamma(last_state(state2,1)) = (-rec_s(2*k-3)+rec_s(2*k-2)*last_out(state2,2))....
-log(1+exp(L_a(k-1)));
gamma(last_state(state2,2)) = (rec_s(2*k-3)+rec_s(2*k-2)*last_out(state2,4))....
+L_a(k-1)-log(1+exp(L_a(k-1))); if(sum(exp(gamma+Alpha(k-1,:)))<1e-300)
Alpha(k,state2)=-Infty;
else
Alpha(k,state2) = log( sum( exp( gamma+Alpha(k-1,:) ) ) );
end
end
tempmax(k) = max(Alpha(k,:));
Alpha(k,:) = Alpha(k,:) - tempmax(k);
end % Trace backward, compute Beta
for k = L_total-1:-1:1
for state1 = 1:nstates
gamma = -Infty*ones(1,nstates);
gamma(next_state(state1,1)) = (-rec_s(2*k+1)+rec_s(2*k+2)*next_out(state1,2))....
-log(1+exp(L_a(k+1)));
gamma(next_state(state1,2)) = (rec_s(2*k+1)+rec_s(2*k+2)*next_out(state1,4))....
+L_a(k+1)-log(1+exp(L_a(k+1)));
if(sum(exp(gamma+Beta(k+1,:)))<1e-300)
Beta(k,state1)=-Infty;
else
Beta(k,state1) = log(sum(exp(gamma+Beta(k+1,:))));
end
end
Beta(k,:) = Beta(k,:) - tempmax(k+1);
end% Compute the soft output, log-likelihood ratio of symbols in the frame
for k = 1:L_total
for state2 = 1:nstates
gamma0 = (-rec_s(2*k-1)+rec_s(2*k)*last_out(state2,2))....
-log(1+exp(L_a(k)));
gamma1 = (rec_s(2*k-1)+rec_s(2*k)*last_out(state2,4))...
+L_a(k)-log(1+exp(L_a(k)));
temp0(state2) = exp(gamma0 + Alpha(k,last_state(state2,1)) + Beta(k,state2));
temp1(state2) = exp(gamma1 + Alpha(k,last_state(state2,2)) + Beta(k,state2));
end
L_all(k) = log(sum(temp1)) - log(sum(temp0));
end

        
   

 

3.仿真结论:

turbo译码Logmap算法和sova算法_sova

D36