I am new to caffe and I have trouble understanding caffe. I have a trained model in caffe and i also have the train.net and deploy.net model. I am trying something similar to semantic segmentation. The aim is to predict which are sky pixels in an image and which is ground. I have with me the pretrained caffe model and train.net and deploy.net files. The input data format for caffe here is lmdb. I am not sure how to use caffe to predict based on the new input image. Also, can Caffe give output as an image?

Here is the deploy.net file that i am using

```
name: "DeepBlueSky"
input: "data"
input_dim: 1
input_dim: 3
input_dim: 240
input_dim: 320
layers {
name: "dummy_data"
type: DUMMY_DATA
top: "label_0"
dummy_data_param {
data_filler {
type: "constant"
std: .5
}
num: 1
channels: 1
height: 240
width: 320
}
}
layers {
name: "combine_1"
type: CONCAT
bottom: "data"
bottom: "label_0"
top: "combine_1"
concat_param {
concat_dim: 1
}
}
layers {
name: "conv1_1"
type: CONVOLUTION
bottom: "combine_1"
top: "conv1_1"
blobs_lr: 1
blobs_lr: 2
convolution_param {
num_output: 20
pad: 4
kernel_size: 9
stride: 1
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
param: "conv1_blob_W"
param: "conv1_blob_b"
}
layers {
name: "act1_1"
type: TANH
bottom: "conv1_1"
top: "conv1_1"
}
layers {
name: "conv2_1"
type: CONVOLUTION
bottom: "conv1_1"
top: "conv2_1"
blobs_lr: 1
blobs_lr: 2
convolution_param {
num_output: 15
pad: 4
kernel_size: 9
stride: 1
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
param: "conv2_blob_W"
param: "conv2_blob_b"
}
layers {
name: "act2_1"
type: TANH
bottom: "conv2_1"
top: "conv2_1"
}
layers {
name: "conv3_1"
type: CONVOLUTION
bottom: "conv2_1"
top: "conv3_1"
blobs_lr: 1
blobs_lr: 2
convolution_param {
num_output: 1
pad: 0
kernel_size: 1
stride: 1
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
param: "conv3_blob_W"
param: "conv3_blob_b"
}
layers {
name: "act3_1"
type: SIGMOID
bottom: "conv3_1"
top: "label_1"
}
layers {
name: "combine_2"
type: CONCAT
bottom: "data"
bottom: "label_1"
top: "combine_2"
concat_param {
concat_dim: 1
}
}
layers {
name: "conv1_2"
type: CONVOLUTION
bottom: "combine_2"
top: "conv1_2"
blobs_lr: 1
blobs_lr: 2
convolution_param {
num_output: 20
pad: 4
kernel_size: 9
stride: 1
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
param: "conv1_blob_W"
param: "conv1_blob_b"
}
layers {
name: "act1_2"
type: TANH
bottom: "conv1_2"
top: "conv1_2"
}
layers {
name: "conv2_2"
type: CONVOLUTION
bottom: "conv1_2"
top: "conv2_2"
blobs_lr: 1
blobs_lr: 2
convolution_param {
num_output: 15
pad: 4
kernel_size: 9
stride: 1
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
param: "conv2_blob_W"
param: "conv2_blob_b"
}
layers {
name: "act2_2"
type: TANH
bottom: "conv2_2"
top: "conv2_2"
}
layers {
name: "conv3_2"
type: CONVOLUTION
bottom: "conv2_2"
top: "conv3_2"
blobs_lr: 1
blobs_lr: 2
convolution_param {
num_output: 1
pad: 0
kernel_size: 1
stride: 1
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
param: "conv3_blob_W"
param: "conv3_blob_b"
}
layers {
name: "act3_2"
type: SIGMOID
bottom: "conv3_2"
top: "label_2"
}
layers {
name: "combine_3"
type: CONCAT
bottom: "data"
bottom: "label_2"
top: "combine_3"
concat_param {
concat_dim: 1
}
}
layers {
name: "conv1_3"
type: CONVOLUTION
bottom: "combine_3"
top: "conv1_3"
blobs_lr: 1
blobs_lr: 2
convolution_param {
num_output: 20
pad: 4
kernel_size: 9
stride: 1
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
param: "conv1_blob_W"
param: "conv1_blob_b"
}
layers {
name: "act1_3"
type: TANH
bottom: "conv1_3"
top: "conv1_3"
}
layers {
name: "conv2_3"
type: CONVOLUTION
bottom: "conv1_3"
top: "conv2_3"
blobs_lr: 1
blobs_lr: 2
convolution_param {
num_output: 15
pad: 4
kernel_size: 9
stride: 1
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
param: "conv2_blob_W"
param: "conv2_blob_b"
}
layers {
name: "act2_3"
type: TANH
bottom: "conv2_3"
top: "conv2_3"
}
layers {
name: "conv3_3"
type: CONVOLUTION
bottom: "conv2_3"
top: "conv3_3"
blobs_lr: 1
blobs_lr: 2
convolution_param {
num_output: 1
pad: 0
kernel_size: 1
stride: 1
weight_filler {
type: "gaussian"
std: 0.01
}
bias_filler {
type: "constant"
value: 0
}
}
param: "conv3_blob_W"
param: "conv3_blob_b"
}
layers {
name: "act3_3"
type: SIGMOID
bottom: "conv3_3"
top: "label_3"
}
```

`caffe.Net(deployfile, model_weights, caffe.TEST)`

. Set`net.blobs['data'].data[...] = your input image`

. And then forward pass the data through the network using`net.forward()`

. – Ibrahim Yousuf Apr 23 at 10:07