I'm trying to implement a siamese network in caffe in which it is composed of two imagenets that don't share weights. So what I am basically trying to do is give each network an image, and in the end try to find out the distance between them for similarity, below is my prototxt. So my main question is what should I set my "num_output" too? I have only 2 classes for my training, 0 for wither they are not alike, and 1 for if they are similar.

```
name: "Siamese_ImageNet"
layers {
name: "data"
type: IMAGE_DATA
top: "data"
top: "label"
image_data_param {
source: "train1.txt"
batch_size: 32
new_height: 256
new_width: 256
}
include: { phase: TRAIN }
}
layers {
name: "data"
type: IMAGE_DATA
top: "data"
top: "label"
image_data_param {
source: "test1.txt"
batch_size: 32
new_height: 256
new_width: 256
}
include: { phase: TEST }
}
layers {
name: "data_p"
type: IMAGE_DATA
top: "data_p"
top: "label_p"
image_data_param {
source: "train2.txt"
batch_size: 32
new_height: 256
new_width: 256
}
include: { phase: TRAIN }
}
layers {
name: "data_p"
type: IMAGE_DATA
top: "data_p"
top: "label_p"
image_data_param {
source: "test2.txt"
batch_size: 32
new_height: 256
new_width: 256
}
include: { phase: TEST }
}
layers {
name: "conv1"
type: CONVOLUTION
bottom: "data"
top: "conv1"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
convolution_param {
num_output: 96
kernel_size: 11
stride: 4
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
}
layers {
name: "relu1"
type: RELU
bottom: "conv1"
top: "conv1"
}
layers {
name: "pool1"
type: POOLING
bottom: "conv1"
top: "pool1"
pooling_param {
pool: MAX
kernel_size: 3
stride: 2
}
}
layers {
name: "norm1"
type: LRN
bottom: "pool1"
top: "norm1"
lrn_param {
local_size: 5
alpha: 0.0001
beta: 0.75
}
}
layers {
name: "conv2"
type: CONVOLUTION
bottom: "norm1"
top: "conv2"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
convolution_param {
num_output: 256
pad: 2
kernel_size: 5
group: 2
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 1
}
}
}
layers {
name: "relu2"
type: RELU
bottom: "conv2"
top: "conv2"
}
layers {
name: "pool2"
type: POOLING
bottom: "conv2"
top: "pool2"
pooling_param {
pool: MAX
kernel_size: 3
stride: 2
}
}
layers {
name: "norm2"
type: LRN
bottom: "pool2"
top: "norm2"
lrn_param {
local_size: 5
alpha: 0.0001
beta: 0.75
}
}
layers {
name: "conv3"
type: CONVOLUTION
bottom: "norm2"
top: "conv3"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
convolution_param {
num_output: 384
pad: 1
kernel_size: 3
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
}
layers {
name: "relu3"
type: RELU
bottom: "conv3"
top: "conv3"
}
layers {
name: "conv4"
type: CONVOLUTION
bottom: "conv3"
top: "conv4"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
convolution_param {
num_output: 384
pad: 1
kernel_size: 3
group: 2
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 1
}
}
}
layers {
name: "relu4"
type: RELU
bottom: "conv4"
top: "conv4"
}
layers {
name: "conv5"
type: CONVOLUTION
bottom: "conv4"
top: "conv5"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
convolution_param {
num_output: 256
pad: 1
kernel_size: 3
group: 2
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 1
}
}
}
layers {
name: "relu5"
type: RELU
bottom: "conv5"
top: "conv5"
}
layers {
name: "pool5"
type: POOLING
bottom: "conv5"
top: "pool5"
pooling_param {
pool: MAX
kernel_size: 3
stride: 2
}
}
layers {
name: "fc6"
type: INNER_PRODUCT
bottom: "pool5"
top: "fc6"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
inner_product_param {
num_output: 4096
weight_filler {
type: "gaussian"
std: 0.005
}
bias_filler {
type: "constant"
value: 1
}
}
}
layers {
name: "relu6"
type: RELU
bottom: "fc6"
top: "fc6"
}
layers {
name: "drop6"
type: DROPOUT
bottom: "fc6"
top: "fc6"
dropout_param {
dropout_ratio: 0.5
}
}
layers {
name: "fc7"
type: INNER_PRODUCT
bottom: "fc6"
top: "fc7"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
inner_product_param {
num_output: 2
weight_filler {
type: "gaussian"
std: 0.005
}
bias_filler {
type: "constant"
value: 1
}
}
}
layers {
name: "relu7"
type: RELU
bottom: "fc7"
top: "fc7"
}
layers {
name: "drop7"
type: DROPOUT
bottom: "fc7"
top: "fc7"
dropout_param {
dropout_ratio: 0.5
}
}
layers {
name: "conv1_p"
type: CONVOLUTION
bottom: "data_p"
top: "conv1_p"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
convolution_param {
num_output: 96
kernel_size: 11
stride: 4
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
}
layers {
name: "relu1_p"
type: RELU
bottom: "conv1_p"
top: "conv1_p"
}
layers {
name: "pool1_p"
type: POOLING
bottom: "conv1_p"
top: "pool1_p"
pooling_param {
pool: MAX
kernel_size: 3
stride: 2
}
}
layers {
name: "norm1_p"
type: LRN
bottom: "pool1_p"
top: "norm1_p"
lrn_param {
local_size: 5
alpha: 0.0001
beta: 0.75
}
}
layers {
name: "conv2_p"
type: CONVOLUTION
bottom: "norm1_p"
top: "conv2_p"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
convolution_param {
num_output: 256
pad: 2
kernel_size: 5
group: 2
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 1
}
}
}
layers {
name: "relu2_p"
type: RELU
bottom: "conv2_p"
top: "conv2_p"
}
layers {
name: "pool2_p"
type: POOLING
bottom: "conv2_p"
top: "pool2_p"
pooling_param {
pool: MAX
kernel_size: 3
stride: 2
}
}
layers {
name: "norm2_p"
type: LRN
bottom: "pool2_p"
top: "norm2_p"
lrn_param {
local_size: 5
alpha: 0.0001
beta: 0.75
}
}
layers {
name: "conv3_p"
type: CONVOLUTION
bottom: "norm2_p"
top: "conv3_p"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
convolution_param {
num_output: 384
pad: 1
kernel_size: 3
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
}
layers {
name: "relu3_p"
type: RELU
bottom: "conv3_p"
top: "conv3_p"
}
layers {
name: "conv4_p"
type: CONVOLUTION
bottom: "conv3_p"
top: "conv4_p"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
convolution_param {
num_output: 384
pad: 1
kernel_size: 3
group: 2
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 1
}
}
}
layers {
name: "relu4_p"
type: RELU
bottom: "conv4_p"
top: "conv4_p"
}
layers {
name: "conv5_p"
type: CONVOLUTION
bottom: "conv4_p"
top: "conv5_p"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
convolution_param {
num_output: 256
pad: 1
kernel_size: 3
group: 2
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 1
}
}
}
layers {
name: "relu5_p"
type: RELU
bottom: "conv5_p"
top: "conv5_p"
}
layers {
name: "pool5_p"
type: POOLING
bottom: "conv5_p"
top: "pool5_p"
pooling_param {
pool: MAX
kernel_size: 3
stride: 2
}
}
layers {
name: "fc6_p"
type: INNER_PRODUCT
bottom: "pool5_p"
top: "fc6_p"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
inner_product_param {
num_output: 4096
weight_filler {
type: "gaussian"
std: 0.005
}
bias_filler {
type: "constant"
value: 1
}
}
}
layers {
name: "relu6_p"
type: RELU
bottom: "fc6_p"
top: "fc6_p"
}
layers {
name: "drop6_p"
type: DROPOUT
bottom: "fc6_p"
top: "fc6_p"
dropout_param {
dropout_ratio: 0.5
}
}
layers {
name: "fc7_p"
type: INNER_PRODUCT
bottom: "fc6_p"
top: "fc7_p"
blobs_lr: 1
blobs_lr: 2
weight_decay: 1
weight_decay: 0
inner_product_param {
num_output: 2
weight_filler {
type: "gaussian"
std: 0.005
}
bias_filler {
type: "constant"
value: 1
}
}
}
layers {
name: "relu7_p"
type: RELU
bottom: "fc7_p"
top: "fc7_p"
}
layers {
name: "drop7_p"
type: DROPOUT
bottom: "fc7_p"
top: "fc7_p"
dropout_param {
dropout_ratio: 0.5
}
}
layers {
name: "loss"
type: CONTRASTIVE_LOSS
contrastive_loss_param {
margin: 1.0
}
bottom: "fc7"
bottom: "fc7_p"
bottom: "label"
top: "loss"
}
```

My training file structure: 0 is dissimilar, 1 is similar

```
train1.txt:
/aer/img1_1.jpg 0
/aer/img1_2.jpg 1
/aer/img1_3.jpg 1
train2.txt:
/tpd/img2_1.jpg 0
/tpd/img2_2.jpg 1
/tpd/img2_3.jpg 1
```

`num_output`

are your referring to exactly? Does your model produce any errors? – Jonathan Nov 23 '16 at 15:29