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我有个问题。我有一个运行良好的网络我想做回归。但是,当我尝试将其用于分类时(在进行了所谓的适当更改之后),我遇到了一些问题。我有 9 节课,但问题是网络以我不清楚的方式输出我。它为每个对象输出一个 9x1 向量,这很好,但里面的值不是概率。我尝试将 softmax 输出转换为 probabilities(exp(1)/(exp(1)+..+exp(n))) 但没有影响。我正在使用 caffe 和 matcaffe 。我想要的是网络告诉我它属于哪个类的输入。基本上在输出中我想要一个代表我的班级的单个值。我正在附上我的 prototxt 文件。`

name: "Zeiler_conv5"

input: "data"
input_dim: 1
input_dim: 3
input_dim: 224
input_dim: 224

input: "rois"
input_dim: 1 # to be changed on-the-fly to num ROIs
input_dim: 5 # [batch ind, x1, y1, x2, y2] zero-based indexing
input_dim: 1
input_dim: 1

input: "labels"
input_dim: 1 # to be changed on-the-fly to match num ROIs
input_dim: 1
input_dim: 1
input_dim: 1

input: "bbox_targets"
input_dim: 1  # to be changed on-the-fly to match num ROIs
input_dim: 84 # 4 * (K+1) (=21) classes
input_dim: 1
input_dim: 1

input: "bbox_loss_weights"
input_dim: 1  # to be changed on-the-fly to match num ROIs
input_dim: 84 # 4 * (K+1) (=21) classes
input_dim: 1
input_dim: 1

input: "angle_head"
input_dim: 1  # to be changed on-the-fly to match num ROIs
input_dim: 9 # 9 (-180:45:180) classes
input_dim: 1
input_dim: 1

input: "angle_head_weight"
input_dim: 1  # to be changed on-the-fly to match num ROIs
input_dim: 9 # 9 (-180:45:180) classes
input_dim: 1
input_dim: 1


layer {
    name: "conv1"
    type: "Convolution"
    bottom: "data"
    top: "conv1"
    param {
        lr_mult: 0.0
    }
    param {
        lr_mult: 0.0
    }
    convolution_param {
        num_output: 96
        kernel_size: 7
        pad: 3
        stride: 2
        weight_filler {
            type: "gaussian"
            std: 0.01
        }
        bias_filler {
            type: "constant"
            value: 0
        }
    }
}

layer {
    name: "relu1"
    type: "ReLU"
    bottom: "conv1"
    top: "conv1"
}

layer {
    name: "norm1"
    type: "LRN"
    bottom: "conv1"
    top: "norm1"
    lrn_param {
        local_size: 3
        alpha: 0.00005
        beta: 0.75
        norm_region: WITHIN_CHANNEL
    }
}

layer {
    name: "pool1"
    type: "Pooling"
    bottom: "norm1"
    top: "pool1"
    pooling_param {
        kernel_size: 3
        stride: 2
        pad: 1
        pool: MAX
    }
}

layer {
    name: "conv2"
    type: "Convolution"
    bottom: "pool1"
    top: "conv2"
    param {
        lr_mult: 0.0
    }
    param {
        lr_mult: 0.0
    }
    convolution_param {
        num_output: 256
        kernel_size: 5
        pad: 2
        stride: 2
        weight_filler {
            type: "gaussian"
            std: 0.01
        }
        bias_filler {
            type: "constant"
            value: 1
        }
    }
}

layer {
    name: "relu2"
    type: "ReLU"
    bottom: "conv2"
    top: "conv2"
}

layer {
    name: "norm2"
    type: "LRN"
    bottom: "conv2"
    top: "norm2"
    lrn_param {
        local_size: 3
        alpha: 0.00005
        beta: 0.75
        norm_region: WITHIN_CHANNEL
    }
}

layer {
    name: "pool2"
    type: "Pooling"
    bottom: "norm2"
    top: "pool2"
    pooling_param {
        kernel_size: 3
        stride: 2
        pad: 1
        pool: MAX
    }
}

layer {
    name: "conv3"
    type: "Convolution"
    bottom: "pool2"
    top: "conv3"
    param {
        lr_mult: 0.0
    }
    param {
        lr_mult: 0.0
    }
    convolution_param {
        num_output: 384
        kernel_size: 3
        pad: 1
        stride: 1
        weight_filler {
            type: "gaussian"
            std: 0.01
        }
        bias_filler {
            type: "constant"
            value: 0
        }
    }
}

layer {
    name: "relu3"
    type: "ReLU"
    bottom: "conv3"
    top: "conv3"
}

layer {
    name: "conv4"
    type: "Convolution"
    bottom: "conv3"
    top: "conv4"
    param {
        lr_mult: 0.0
    }
    param {
        lr_mult: 0.0
    }
    convolution_param {
        num_output: 384
        kernel_size: 3
        pad: 1
        stride: 1
        weight_filler {
            type: "gaussian"
            std: 0.01
        }
        bias_filler {
            type: "constant"
            value: 1
        }
    }
}

layer {
    name: "relu4"
    type: "ReLU"
    bottom: "conv4"
    top: "conv4"
}

layer {
    name: "conv5"
    type: "Convolution"
    bottom: "conv4"
    top: "conv5"
    param {
        lr_mult: 0.0
    }
    param {
        lr_mult: 0.0
    }
    convolution_param {
        num_output: 256
        kernel_size: 3
        pad: 1
        stride: 1
        weight_filler {
            type: "gaussian"
            std: 0.01
        }
        bias_filler {
            type: "constant"
            value: 1
        }
    }
}

layer {
    name: "relu5"
    type: "ReLU"
    bottom: "conv5"
    top: "conv5"
}

layer {
    bottom: "conv5"
    bottom: "rois"
    top: "pool5"
    name: "roi_pool5"
    type: "ROIPooling"
    roi_pooling_param {
        pooled_w: 6
        pooled_h: 6
        spatial_scale: 0.0625  # (1/16)
    }
}

layer {
    bottom: "pool5"
    top: "fc6"
    name: "fc6"
    param {
        lr_mult: 1.0
    }
    param {
        lr_mult: 2.0
    }
    type: "InnerProduct"
    inner_product_param {
        num_output: 4096
    }
}

layer {
    bottom: "fc6"
    top: "fc6"
    name: "relu6"
    type: "ReLU"
}

layer {
    bottom: "fc6"
    top: "fc6"
    name: "drop6"
    type: "Dropout"
    dropout_param {
        dropout_ratio: 0.5
        scale_train: false
    }
}

layer {
    bottom: "fc6"
    top: "fc7"
    name: "fc7"
    param {
        lr_mult: 1.0
    }
    param {
        lr_mult: 2.0
    }
    type: "InnerProduct"
    inner_product_param {
        num_output: 4096
    }
}

layer {
    bottom: "fc7"
    top: "fc7"
    name: "relu7"
    type: "ReLU"
}

layer {
    bottom: "fc7"
    top: "fc7"
    name: "drop7"
    type: "Dropout"
    dropout_param {
        dropout_ratio: 0.5
        scale_train: false
    }
}

layer {
    bottom: "fc7"
    top: "cls_score"
    name: "cls_score"
    param {
        lr_mult: 1.0
    }
    param {
        lr_mult: 2.0
    }
    type: "InnerProduct"
    inner_product_param {
        num_output: 21
        weight_filler {
            type: "gaussian"
            std: 0.01
        }
        bias_filler {
            type: "constant"
            value: 0
        }
    }
}

layer {
    bottom: "fc7"
    top: "angle_pred"
    name: "angle_pred"
    type: "InnerProduct"
    param {
        lr_mult: 1.0
    }
    param {
        lr_mult: 2.0
    }
    inner_product_param {
        num_output: 9
        weight_filler {
            type: "gaussian"
            std: 0.001
        }
        bias_filler {
            type: "constant"
            value: 0
        }
    }
}

layer {
    bottom: "fc7"
    top: "bbox_pred"
    name: "bbox_pred"
    type: "InnerProduct"
    param {
        lr_mult: 1.0
    }
    param {
        lr_mult: 2.0
    }
    inner_product_param {
        num_output: 84
        weight_filler {
            type: "gaussian"
            std: 0.001
        }
        bias_filler {
            type: "constant"
            value: 0
        }
    }
}

layer {
    name: "loss"
    type: "SoftmaxWithLoss"
    bottom: "cls_score"
    bottom: "labels"
    top: "loss_cls"
    loss_weight: 0
}

layer {
    name: "accuarcy"
    type: "Accuracy"
    bottom: "cls_score"
    bottom: "labels"
    top: "accuarcy"
}

layer {
    name: "loss_angle"
    type: "SmoothL1Loss"
    bottom: "angle_pred"
    bottom: "angle_head"
    bottom: "angle_head_weight"
    top: "loss_angle"
    loss_weight: 1
}

layer {
    name: "loss_bbox"
    type: "SmoothL1Loss"
    bottom: "bbox_pred"
    bottom: "bbox_targets"
    bottom: "bbox_loss_weights"
    top: "loss_bbox"
    loss_weight: 0
}

`

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2 回答 2

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您在输出层使用了 softmax 函数将神经网络模型生成的分数转换为概率。现在您需要考虑最大概率,与最大概率相关的类别就是您的答案。顺便问一下,softmax 函数没有效果是什么意思?Softmax 函数也会给你一个向量,而不是单个值。您可以根据概率决定分类器预测的最终类别是什么。

于 2016-10-24T01:09:37.767 回答
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我认为您上传的文件是培训 prototxt 文件。您已经使用了SoftmaxWithLoss图层。这一层不会给你概率。在部署时将其替换为SoftMaxlayer 以获得每个类的概率。

于 2016-10-25T07:51:02.780 回答