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test_Trans.m
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% This script test under 10-fold Cross Validation, divided by ID, how dtfv works
% Using transcript feature
function prob = test_Trans(part, method)
run('../../../toolbox/vlfeat-0.9.20/toolbox/vl_setup')
addpath('../../../toolbox/libsvm/matlab');
%part = 1;
trainfile = ['../Scripts_by_ID/trainVideo',num2str(part),'.txt'];
testfile = ['../Scripts_by_ID/testVideo',num2str(part),'.txt'];
feapath = '../dataset_trial/TranFeats/';
%Build dictionary
if ~exist('Tran_words.mat', 'file')
traindic = ['../Scripts_by_ID/trainVideo0.txt'];
testdic = ['../Scripts_by_ID/testVideo0.txt'];
fid = fopen(traindic);
Ctr = textscan(fid, '%s');
fclose(fid);
fid = fopen(testdic);
Cte = textscan(fid, '%s');
fclose(fid);
data = [];
num_tr = length(Ctr{1})/2;
for i = 1:num_tr
[pathstr,name,ext] = fileparts(Ctr{1}{2*i-1});
feafile = fullfile(feapath, [name, '.txt.npy.mat']);
load(feafile);
data = [data; reshape(A, size(A,2), size(A,3))];
end
num_te = length(Cte{1})/2;
for i = 1:num_te
[pathstr,name,ext] = fileparts(Cte{1}{2*i-1});
feafile = fullfile(feapath, [name, '.txt.npy.mat']);
load(feafile);
data = [data; reshape(A, size(A,2), size(A,3))];
end
fprintf('Total word number is %d.\n', size(data,1));
save('Tran_words.mat', 'data');
else
load('Tran_words.mat');
fprintf('Load words finished.\n');
end
% Dictionary
numClusters = 64;
if ~exist('Tran_dict.mat', 'file')
fprintf('Start building dictionary.\n');
data = data';
[means, covariances, priors] = vl_gmm(data, numClusters);
fprintf('Build dictionary finished.\n');
save('Tran_dict.mat','means', 'covariances', 'priors');
else
load('Tran_dict.mat');
end
% Load data
fid = fopen(trainfile);
C = textscan(fid, '%s');
fclose(fid);
fea_dim = 2*300*numClusters;%+24576+27648;
num_v = length(C{1})/2;
train_fea = zeros(num_v, fea_dim);
train_lab = zeros(num_v, 1);
for i = 1:num_v
[pathstr,name,ext] = fileparts(C{1}{2*i-1});
s = findstr(name, 'lie');
lab = isempty(s);
feafile = fullfile(feapath, [name, '.txt.npy.mat']);
load(feafile);
tmpdata = reshape(A, size(A,2), size(A,3))';
encoding = vl_fisher(tmpdata, means, covariances, priors);
train_fea(i,:) = encoding';
train_lab(i) = lab;
end
%% test phase
fid = fopen(testfile);
C = textscan(fid, '%s');
fclose(fid);
num_v = length(C{1})/2;
test_fea = zeros(num_v, fea_dim);
test_lab = zeros(num_v, 1);
for i = 1:num_v
[pathstr,name,ext] = fileparts(C{1}{2*i-1});
s = findstr(name, 'lie');
lab = isempty(s);
feafile = fullfile(feapath, [name, '.txt.npy.mat']);
load(feafile);
tmpdata = reshape(A, size(A,2), size(A,3))';
encoding = vl_fisher(tmpdata, means, covariances, priors);
test_fea(i,:) = encoding';
test_lab(i) = lab;
end
switch(method)
case 'NN'
net = feedforwardnet(10);
net.trainFcn = 'trainscg';
net = configure(net, train_fea', train_lab');
net = train(net, train_fea', train_lab');
prob = net(test_fea');
case 'tree'
tc = fitctree(train_fea, train_lab);
[label,score,node,cnum] = predict(tc, test_fea);
prob = score(:,1);
case 'randforest'
BaggedEnsemble = TreeBagger(50,train_fea,train_lab,'OOBPred','On');
[label,scores] = predict(BaggedEnsemble, test_fea);
prob = scores(:,1);
case 'bayes'
flag = bitand(var(train_fea(train_lab==1,:))>1e-10,var(train_fea(train_lab==0,:))>1e-10); %clear 0 variance features
O1 = fitNaiveBayes(train_fea(:,flag), train_lab);
C1 = posterior(O1, test_fea(:,flag));
prob = C1(:,1);
case 'log'
B = glmfit(train_fea, [train_lab ones(size(train_lab,1),1)], 'binomial', 'link', 'logit');
Z = repmat(B(1), size(test_lab,1),1) + test_fea*B(2:end);
prob = 1 ./ (1 + exp(-Z));
prob = 1-prob;
case 'boost'
ens = fitensemble(train_fea,train_lab,'AdaBoostM1',100,'Tree')
[~, prob] = predict(ens,test_fea)
prob = prob(:,1);
case 'linearsvm'
%model = svmtrain(train_lab, tmptrain_fea, '-t 0 -q -b 1');
%fprintf('Finished training.\n');
%[pred, acc, prob] = svmpredict(test_lab, tmptest_fea, model, '-q -b 1');
%prob = prob(:,2);
model = svmtrain(train_lab, train_fea, '-t 0 -q');
[pred, acc, prob] = svmpredict(test_lab, test_fea, model, '-q');
lie_id = find(prob<0);
if ~isempty(lie_id)
if pred(lie_id(1)) == 0
isign = -1;
else
isign = 1;
end
else
if pred(1) == 1
isign = -1;
else
isign = 1;
end
end
prob = isign*prob;
case 'kernelsvm'
%model = svmtrain(train_lab, tmptrain_fea, '-t 0 -q -b 1');
%fprintf('Finished training.\n');
%[pred, acc, prob] = svmpredict(test_lab, tmptest_fea, model, '-q -b 1');
%prob = prob(:,2);
model = svmtrain(train_lab, train_fea, '-t 1 -c 1 -g 1 -q');
[pred, acc, prob] = svmpredict(test_lab, test_fea, model, '-q');
lie_id = find(prob<0);
if ~isempty(lie_id)
if pred(lie_id(1)) == 0
isign = -1;
else
isign = 1;
end
else
if pred(1) == 1
isign = -1;
else
isign = 1;
end
end
prob = isign*prob;
end