{ "cells": [ { "cell_type": "markdown", "id": "f68fd76a", "metadata": { "origin_pos": 0 }, "source": [ "# 填充和步幅\n", ":label:`sec_padding`\n", "\n", "在前面的例子 :numref:`fig_correlation`中,输入的高度和宽度都为$3$,卷积核的高度和宽度都为$2$,生成的输出表征的维数为$2\\times2$。\n", "正如我们在 :numref:`sec_conv_layer`中所概括的那样,假设输入形状为$n_h\\times n_w$,卷积核形状为$k_h\\times k_w$,那么输出形状将是$(n_h-k_h+1) \\times (n_w-k_w+1)$。\n", "因此,卷积的输出形状取决于输入形状和卷积核的形状。\n", "\n", "还有什么因素会影响输出的大小呢?本节我们将介绍*填充*(padding)和*步幅*(stride)。假设以下情景:\n", "有时,在应用了连续的卷积之后,我们最终得到的输出远小于输入大小。这是由于卷积核的宽度和高度通常大于$1$所导致的。比如,一个$240 \\times 240$像素的图像,经过$10$层$5 \\times 5$的卷积后,将减少到$200 \\times 200$像素。如此一来,原始图像的边界丢失了许多有用信息。而*填充*是解决此问题最有效的方法;\n", "有时,我们可能希望大幅降低图像的宽度和高度。例如,如果我们发现原始的输入分辨率十分冗余。*步幅*则可以在这类情况下提供帮助。\n", "\n", "## 填充\n", "\n", "如上所述,在应用多层卷积时,我们常常丢失边缘像素。\n", "由于我们通常使用小卷积核,因此对于任何单个卷积,我们可能只会丢失几个像素。\n", "但随着我们应用许多连续卷积层,累积丢失的像素数就多了。\n", "解决这个问题的简单方法即为*填充*(padding):在输入图像的边界填充元素(通常填充元素是$0$)。\n", "例如,在 :numref:`img_conv_pad`中,我们将$3 \\times 3$输入填充到$5 \\times 5$,那么它的输出就增加为$4 \\times 4$。阴影部分是第一个输出元素以及用于输出计算的输入和核张量元素:\n", "$0\\times0+0\\times1+0\\times2+0\\times3=0$。\n", "\n", "![带填充的二维互相关。](../img/conv-pad.svg)\n", ":label:`img_conv_pad`\n", "\n", "通常,如果我们添加$p_h$行填充(大约一半在顶部,一半在底部)和$p_w$列填充(左侧大约一半,右侧一半),则输出形状将为\n", "\n", "$$(n_h-k_h+p_h+1)\\times(n_w-k_w+p_w+1)。$$\n", "\n", "这意味着输出的高度和宽度将分别增加$p_h$和$p_w$。\n", "\n", "在许多情况下,我们需要设置$p_h=k_h-1$和$p_w=k_w-1$,使输入和输出具有相同的高度和宽度。\n", "这样可以在构建网络时更容易地预测每个图层的输出形状。假设$k_h$是奇数,我们将在高度的两侧填充$p_h/2$行。\n", "如果$k_h$是偶数,则一种可能性是在输入顶部填充$\\lceil p_h/2\\rceil$行,在底部填充$\\lfloor p_h/2\\rfloor$行。同理,我们填充宽度的两侧。\n", "\n", "卷积神经网络中卷积核的高度和宽度通常为奇数,例如1、3、5或7。\n", "选择奇数的好处是,保持空间维度的同时,我们可以在顶部和底部填充相同数量的行,在左侧和右侧填充相同数量的列。\n", "\n", "此外,使用奇数的核大小和填充大小也提供了书写上的便利。对于任何二维张量`X`,当满足:\n", "1. 卷积核的大小是奇数;\n", "2. 所有边的填充行数和列数相同;\n", "3. 输出与输入具有相同高度和宽度\n", "则可以得出:输出`Y[i, j]`是通过以输入`X[i, j]`为中心,与卷积核进行互相关计算得到的。\n", "\n", "比如,在下面的例子中,我们创建一个高度和宽度为3的二维卷积层,并(**在所有侧边填充1个像素**)。给定高度和宽度为8的输入,则输出的高度和宽度也是8。\n" ] }, { "cell_type": "code", "execution_count": 1, "id": "ee25ca28", "metadata": { "execution": { "iopub.execute_input": "2023-08-18T07:00:27.440657Z", "iopub.status.busy": "2023-08-18T07:00:27.439788Z", "iopub.status.idle": "2023-08-18T07:00:28.396461Z", "shell.execute_reply": "2023-08-18T07:00:28.395508Z" }, "origin_pos": 2, "tab": [ "pytorch" ] }, "outputs": [ { "data": { "text/plain": [ "torch.Size([8, 8])" ] }, "execution_count": 1, "metadata": {}, "output_type": "execute_result" } ], "source": [ "import torch\n", "from torch import nn\n", "\n", "\n", "# 为了方便起见,我们定义了一个计算卷积层的函数。\n", "# 此函数初始化卷积层权重,并对输入和输出提高和缩减相应的维数\n", "def comp_conv2d(conv2d, X):\n", " # 这里的(1,1)表示批量大小和通道数都是1\n", " X = X.reshape((1, 1) + X.shape)\n", " Y = conv2d(X)\n", " # 省略前两个维度:批量大小和通道\n", " return Y.reshape(Y.shape[2:])\n", "\n", "# 请注意,这里每边都填充了1行或1列,因此总共添加了2行或2列\n", "conv2d = nn.Conv2d(1, 1, kernel_size=3, padding=1)\n", "X = torch.rand(size=(8, 8))\n", "comp_conv2d(conv2d, X).shape" ] }, { "cell_type": "markdown", "id": "f46e5ea5", "metadata": { "origin_pos": 5 }, "source": [ "当卷积核的高度和宽度不同时,我们可以[**填充不同的高度和宽度**],使输出和输入具有相同的高度和宽度。在如下示例中,我们使用高度为5,宽度为3的卷积核,高度和宽度两边的填充分别为2和1。\n" ] }, { "cell_type": "code", "execution_count": 2, "id": "5dadebb1", "metadata": { "execution": { "iopub.execute_input": "2023-08-18T07:00:28.400923Z", "iopub.status.busy": "2023-08-18T07:00:28.400085Z", "iopub.status.idle": "2023-08-18T07:00:28.406887Z", "shell.execute_reply": "2023-08-18T07:00:28.406085Z" }, "origin_pos": 7, "tab": [ "pytorch" ] }, "outputs": [ { "data": { "text/plain": [ "torch.Size([8, 8])" ] }, "execution_count": 2, "metadata": {}, "output_type": "execute_result" } ], "source": [ "conv2d = nn.Conv2d(1, 1, kernel_size=(5, 3), padding=(2, 1))\n", "comp_conv2d(conv2d, X).shape" ] }, { "cell_type": "markdown", "id": "5a303f4b", "metadata": { "origin_pos": 10 }, "source": [ "## 步幅\n", "\n", "在计算互相关时,卷积窗口从输入张量的左上角开始,向下、向右滑动。\n", "在前面的例子中,我们默认每次滑动一个元素。\n", "但是,有时候为了高效计算或是缩减采样次数,卷积窗口可以跳过中间位置,每次滑动多个元素。\n", "\n", "我们将每次滑动元素的数量称为*步幅*(stride)。到目前为止,我们只使用过高度或宽度为$1$的步幅,那么如何使用较大的步幅呢?\n", " :numref:`img_conv_stride`是垂直步幅为$3$,水平步幅为$2$的二维互相关运算。\n", "着色部分是输出元素以及用于输出计算的输入和内核张量元素:$0\\times0+0\\times1+1\\times2+2\\times3=8$、$0\\times0+6\\times1+0\\times2+0\\times3=6$。\n", "\n", "可以看到,为了计算输出中第一列的第二个元素和第一行的第二个元素,卷积窗口分别向下滑动三行和向右滑动两列。但是,当卷积窗口继续向右滑动两列时,没有输出,因为输入元素无法填充窗口(除非我们添加另一列填充)。\n", "\n", "![垂直步幅为 $3$,水平步幅为 $2$ 的二维互相关运算。](../img/conv-stride.svg)\n", ":label:`img_conv_stride`\n", "\n", "通常,当垂直步幅为$s_h$、水平步幅为$s_w$时,输出形状为\n", "\n", "$$\\lfloor(n_h-k_h+p_h+s_h)/s_h\\rfloor \\times \\lfloor(n_w-k_w+p_w+s_w)/s_w\\rfloor.$$\n", "\n", "如果我们设置了$p_h=k_h-1$和$p_w=k_w-1$,则输出形状将简化为$\\lfloor(n_h+s_h-1)/s_h\\rfloor \\times \\lfloor(n_w+s_w-1)/s_w\\rfloor$。\n", "更进一步,如果输入的高度和宽度可以被垂直和水平步幅整除,则输出形状将为$(n_h/s_h) \\times (n_w/s_w)$。\n", "\n", "下面,我们[**将高度和宽度的步幅设置为2**],从而将输入的高度和宽度减半。\n" ] }, { "cell_type": "code", "execution_count": 3, "id": "7b6ac278", "metadata": { "execution": { "iopub.execute_input": "2023-08-18T07:00:28.410395Z", "iopub.status.busy": "2023-08-18T07:00:28.410090Z", "iopub.status.idle": "2023-08-18T07:00:28.416621Z", "shell.execute_reply": "2023-08-18T07:00:28.415848Z" }, "origin_pos": 12, "tab": [ "pytorch" ] }, "outputs": [ { "data": { "text/plain": [ "torch.Size([4, 4])" ] }, "execution_count": 3, "metadata": {}, "output_type": "execute_result" } ], "source": [ "conv2d = nn.Conv2d(1, 1, kernel_size=3, padding=1, stride=2)\n", "comp_conv2d(conv2d, X).shape" ] }, { "cell_type": "markdown", "id": "e9e254ec", "metadata": { "origin_pos": 15 }, "source": [ "接下来,看(**一个稍微复杂的例子**)。\n" ] }, { "cell_type": "code", "execution_count": 4, "id": "6f1c0e6c", "metadata": { "execution": { "iopub.execute_input": "2023-08-18T07:00:28.422070Z", "iopub.status.busy": "2023-08-18T07:00:28.421461Z", "iopub.status.idle": "2023-08-18T07:00:28.429200Z", "shell.execute_reply": "2023-08-18T07:00:28.427969Z" }, "origin_pos": 17, "tab": [ "pytorch" ] }, "outputs": [ { "data": { "text/plain": [ "torch.Size([2, 2])" ] }, "execution_count": 4, "metadata": {}, "output_type": "execute_result" } ], "source": [ "conv2d = nn.Conv2d(1, 1, kernel_size=(3, 5), padding=(0, 1), stride=(3, 4))\n", "comp_conv2d(conv2d, X).shape" ] }, { "cell_type": "markdown", "id": "4674c8d4", "metadata": { "origin_pos": 20 }, "source": [ "为了简洁起见,当输入高度和宽度两侧的填充数量分别为$p_h$和$p_w$时,我们称之为填充$(p_h, p_w)$。当$p_h = p_w = p$时,填充是$p$。同理,当高度和宽度上的步幅分别为$s_h$和$s_w$时,我们称之为步幅$(s_h, s_w)$。特别地,当$s_h = s_w = s$时,我们称步幅为$s$。默认情况下,填充为0,步幅为1。在实践中,我们很少使用不一致的步幅或填充,也就是说,我们通常有$p_h = p_w$和$s_h = s_w$。\n", "\n", "## 小结\n", "\n", "* 填充可以增加输出的高度和宽度。这常用来使输出与输入具有相同的高和宽。\n", "* 步幅可以减小输出的高和宽,例如输出的高和宽仅为输入的高和宽的$1/n$($n$是一个大于$1$的整数)。\n", "* 填充和步幅可用于有效地调整数据的维度。\n", "\n", "## 练习\n", "\n", "1. 对于本节中的最后一个示例,计算其输出形状,以查看它是否与实验结果一致。\n", "1. 在本节中的实验中,试一试其他填充和步幅组合。\n", "1. 对于音频信号,步幅$2$说明什么?\n", "1. 步幅大于$1$的计算优势是什么?\n" ] }, { "cell_type": "markdown", "id": "a93cbfa0", "metadata": { "origin_pos": 22, "tab": [ "pytorch" ] }, "source": [ "[Discussions](https://discuss.d2l.ai/t/1851)\n" ] } ], "metadata": { "language_info": { "name": "python" }, "required_libs": [] }, "nbformat": 4, "nbformat_minor": 5 }