-
Notifications
You must be signed in to change notification settings - Fork 1.7k
/
pattern_recognition.lua
85 lines (81 loc) · 3.64 KB
/
pattern_recognition.lua
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
require 'nn'
require 'paths'
if (not paths.filep("cifar10torchsmall.zip")) then
os.execute('wget -c https://s3.amazonaws.com/torch7/data/cifar10torchsmall.zip')
os.execute('unzip cifar10torchsmall.zip')
end
trainset = torch.load('cifar10-train.t7')
testset = torch.load('cifar10-test.t7')
classes = {'airplane', 'automobile', 'bird', 'cat',
'deer', 'dog', 'frog', 'horse', 'ship', 'truck'}
setmetatable(trainset,
{__index = function(t, i)
return {t.data[i], t.label[i]}
end}
);
trainset.data = trainset.data:double() -- convert the data from a ByteTensor to a DoubleTensor.
function trainset:size()
return self.data:size(1)
end
mean = {} -- store the mean, to normalize the test set in the future
stdv = {} -- store the standard-deviation for the future
for i=1,3 do -- over each image channel
mean[i] = trainset.data[{ {}, {i}, {}, {} }]:mean() -- mean estimation
print('Channel ' .. i .. ', Mean: ' .. mean[i])
trainset.data[{ {}, {i}, {}, {} }]:add(-mean[i]) -- mean subtraction
stdv[i] = trainset.data[{ {}, {i}, {}, {} }]:std() -- std estimation
print('Channel ' .. i .. ', Standard Deviation: ' .. stdv[i])
trainset.data[{ {}, {i}, {}, {} }]:div(stdv[i]) -- std scaling
end
net = nn.Sequential()
net:add(nn.SpatialConvolution(3, 6, 5, 5)) -- 3 input image channels, 6 output channels, 5x5 convolution kernel
net:add(nn.ReLU()) -- non-linearity
net:add(nn.SpatialMaxPooling(2,2,2,2)) -- A max-pooling operation that looks at 2x2 windows and finds the max.
net:add(nn.SpatialConvolution(6, 16, 5, 5))
net:add(nn.ReLU()) -- non-linearity
net:add(nn.SpatialMaxPooling(2,2,2,2))
net:add(nn.View(16*5*5)) -- reshapes from a 3D tensor of 16x5x5 into 1D tensor of 16*5*5
net:add(nn.Linear(16*5*5, 120)) -- fully connected layer (matrix multiplication between input and weights)
net:add(nn.ReLU()) -- non-linearity
net:add(nn.Linear(120, 84))
net:add(nn.ReLU()) -- non-linearity
net:add(nn.Linear(84, 10)) -- 10 is the number of outputs of the network (in this case, 10 digits)
net:add(nn.LogSoftMax()) -- converts the output to a log-probability. Useful for classification problems
criterion = nn.ClassNLLCriterion()
trainer = nn.StochasticGradient(net, criterion)
trainer.learningRate = 0.001
trainer.maxIteration = 5
trainer:train(trainset)
testset.data = testset.data:double() -- convert from Byte tensor to Double tensor
for i=1,3 do -- over each image channel
testset.data[{ {}, {i}, {}, {} }]:add(-mean[i]) -- mean subtraction
testset.data[{ {}, {i}, {}, {} }]:div(stdv[i]) -- std scaling
end
predicted = net:forward(testset.data[100])
print(classes[testset.label[100]])
print(predicted:exp())
for i=1,predicted:size(1) do
print(classes[i], predicted[i])
end
correct = 0
for i=1,10000 do
local groundtruth = testset.label[i]
local prediction = net:forward(testset.data[i])
local confidences, indices = torch.sort(prediction, true) -- true means sort in descending order
if groundtruth == indices[1] then
correct = correct + 1
end
end
print(correct, 100*correct/10000 .. ' % ')
class_performance = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0}
for i=1,10000 do
local groundtruth = testset.label[i]
local prediction = net:forward(testset.data[i])
local confidences, indices = torch.sort(prediction, true) -- true means sort in descending order
if groundtruth == indices[1] then
class_performance[groundtruth] = class_performance[groundtruth] + 1
end
end
for i=1,#classes do
print(classes[i], 100*class_performance[i]/1000 .. ' %')
end