Can anyone please clearly explain the difference between 1D, 2D, and 3D convolutions in CNN (Deep Learning) with examples?
I want to explain with picture from C3D.
In a nutshell, convolutional direction & output shape is important!
↑↑↑↑↑ 1D Convolutions  Basic ↑↑↑↑↑
 just 1direction (timeaxis) to calculate conv
 input = [W], filter = [k], output = [W]
 ex) input = [1,1,1,1,1], filter = [0.25,0.5,0.25], output = [1,1,1,1,1]
 outputshape is 1D array
 example) graph smoothing
tf.nn.conv1d code Toy Example
import tensorflow as tf
import numpy as np
sess = tf.Session()
ones_1d = np.ones(5)
weight_1d = np.ones(3)
strides_1d = 1
in_1d = tf.constant(ones_1d, dtype=tf.float32)
filter_1d = tf.constant(weight_1d, dtype=tf.float32)
in_width = int(in_1d.shape[0])
filter_width = int(filter_1d.shape[0])
input_1d = tf.reshape(in_1d, [1, in_width, 1])
kernel_1d = tf.reshape(filter_1d, [filter_width, 1, 1])
output_1d = tf.squeeze(tf.nn.conv1d(input_1d, kernel_1d, strides_1d, padding='SAME'))
print sess.run(output_1d)
↑↑↑↑↑ 2D Convolutions  Basic ↑↑↑↑↑
 2direction (x,y) to calculate conv
 outputshape is 2D Matrix
 input = [W, H], filter = [k,k] output = [W,H]
 example) Sobel Egde Fllter
tf.nn.conv2d  Toy Example
ones_2d = np.ones((5,5))
weight_2d = np.ones((3,3))
strides_2d = [1, 1, 1, 1]
in_2d = tf.constant(ones_2d, dtype=tf.float32)
filter_2d = tf.constant(weight_2d, dtype=tf.float32)
in_width = int(in_2d.shape[0])
in_height = int(in_2d.shape[1])
filter_width = int(filter_2d.shape[0])
filter_height = int(filter_2d.shape[1])
input_2d = tf.reshape(in_2d, [1, in_height, in_width, 1])
kernel_2d = tf.reshape(filter_2d, [filter_height, filter_width, 1, 1])
output_2d = tf.squeeze(tf.nn.conv2d(input_2d, kernel_2d, strides=strides_2d, padding='SAME'))
print sess.run(output_2d)
↑↑↑↑↑ 3D Convolutions  Basic ↑↑↑↑↑
 3direction (x,y,z) to calcuate conv
 outputshape is 3D Volume
 input = [W,H,L], filter = [k,k,d] output = [W,H,M]
 d < L is important! for making volume output
 example) C3D
tf.nn.conv3d  Toy Example
ones_3d = np.ones((5,5,5))
weight_3d = np.ones((3,3,3))
strides_3d = [1, 1, 1, 1, 1]
in_3d = tf.constant(ones_3d, dtype=tf.float32)
filter_3d = tf.constant(weight_3d, dtype=tf.float32)
in_width = int(in_3d.shape[0])
in_height = int(in_3d.shape[1])
in_depth = int(in_3d.shape[2])
filter_width = int(filter_3d.shape[0])
filter_height = int(filter_3d.shape[1])
filter_depth = int(filter_3d.shape[2])
input_3d = tf.reshape(in_3d, [1, in_depth, in_height, in_depth, 1])
kernel_3d = tf.reshape(filter_3d, [filter_depth, filter_height, filter_width, 1, 1])
output_3d = tf.squeeze(tf.nn.conv3d(input_3d, kernel_3d, strides=strides_3d, padding='SAME'))
print sess.run(output_3d)
↑↑↑↑↑ 2D Convolutions with 3D input  LeNet, VGG, ..., ↑↑↑↑↑
 Eventhough input is 3D ex) 224x224x3, 112x112x32
 outputshape is not 3D Volume, but 2D Matrix
 because filter depth = L must be matched with input channels = L
 2direction (x,y) to calcuate conv! not 3D
 input = [W,H,L], filter = [k,k,L] output = [W,H]
 outputshape is 2D Matrix
 what if we want to train N filters (N is number of filters)
 then output shape is (stacked 2D) 3D = 2D x N matrix.
conv2d  LeNet, VGG, ... for 1 filter
in_channels = 32 # 3 for RGB, 32, 64, 128, ...
ones_3d = np.ones((5,5,in_channels)) # input is 3d, in_channels = 32
# filter must have 3dshpae with in_channels
weight_3d = np.ones((3,3,in_channels))
strides_2d = [1, 1, 1, 1]
in_3d = tf.constant(ones_3d, dtype=tf.float32)
filter_3d = tf.constant(weight_3d, dtype=tf.float32)
in_width = int(in_3d.shape[0])
in_height = int(in_3d.shape[1])
filter_width = int(filter_3d.shape[0])
filter_height = int(filter_3d.shape[1])
input_3d = tf.reshape(in_3d, [1, in_height, in_width, in_channels])
kernel_3d = tf.reshape(filter_3d, [filter_height, filter_width, in_channels, 1])
output_2d = tf.squeeze(tf.nn.conv2d(input_3d, kernel_3d, strides=strides_2d, padding='SAME'))
print sess.run(output_2d)
conv2d  LeNet, VGG, ... for N filters
in_channels = 32 # 3 for RGB, 32, 64, 128, ...
out_channels = 64 # 128, 256, ...
ones_3d = np.ones((5,5,in_channels)) # input is 3d, in_channels = 32
# filter must have 3dshpae x number of filters = 4D
weight_4d = np.ones((3,3,in_channels, out_channels))
strides_2d = [1, 1, 1, 1]
in_3d = tf.constant(ones_3d, dtype=tf.float32)
filter_4d = tf.constant(weight_4d, dtype=tf.float32)
in_width = int(in_3d.shape[0])
in_height = int(in_3d.shape[1])
filter_width = int(filter_4d.shape[0])
filter_height = int(filter_4d.shape[1])
input_3d = tf.reshape(in_3d, [1, in_height, in_width, in_channels])
kernel_4d = tf.reshape(filter_4d, [filter_height, filter_width, in_channels, out_channels])
#output stacked shape is 3D = 2D x N matrix
output_3d = tf.nn.conv2d(input_3d, kernel_4d, strides=strides_2d, padding='SAME')
print sess.run(output_3d)
↑↑↑↑↑ Bonus 1x1 conv in CNN  GoogLeNet, ..., ↑↑↑↑↑
 1x1 conv is confusing when you think this as 2D image filter like sobel
 for 1x1 conv in CNN, input is 3D shape as above picture.
 it calculate depthwise filtering
 input = [W,H,L], filter = [1,1,L] output = [W,H]
 output stacked shape is 3D = 2D x N matrix.
tf.nn.conv2d  special case 1x1 conv
in_channels = 32 # 3 for RGB, 32, 64, 128, ...
out_channels = 64 # 128, 256, ...
ones_3d = np.ones((1,1,in_channels)) # input is 3d, in_channels = 32
# filter must have 3dshpae x number of filters = 4D
weight_4d = np.ones((3,3,in_channels, out_channels))
strides_2d = [1, 1, 1, 1]
in_3d = tf.constant(ones_3d, dtype=tf.float32)
filter_4d = tf.constant(weight_4d, dtype=tf.float32)
in_width = int(in_3d.shape[0])
in_height = int(in_3d.shape[1])
filter_width = int(filter_4d.shape[0])
filter_height = int(filter_4d.shape[1])
input_3d = tf.reshape(in_3d, [1, in_height, in_width, in_channels])
kernel_4d = tf.reshape(filter_4d, [filter_height, filter_width, in_channels, out_channels])
#output stacked shape is 3D = 2D x N matrix
output_3d = tf.nn.conv2d(input_3d, kernel_4d, strides=strides_2d, padding='SAME')
print sess.run(output_3d)
Animation (2D Conv with 3Dinputs)
 Original Link : LINK
 The author: Martin Görner
 Twitter: @martin_gorner
 Google +: plus.google.com/+MartinGorne
Bonus 1D Convolutions with 2D input
↑↑↑↑↑ 1D Convolutions with 1D input ↑↑↑↑↑
↑↑↑↑↑ 1D Convolutions with 2D input ↑↑↑↑↑
 Eventhough input is 2D ex) 20x14
 outputshape is not 2D , but 1D Matrix
 because filter height = L must be matched with input height = L
 1direction (x) to calcuate conv! not 2D
 input = [W,L], filter = [k,L] output = [W]
 outputshape is 1D Matrix
 what if we want to train N filters (N is number of filters)
 then output shape is (stacked 1D) 2D = 1D x N matrix.
Bonus C3D
in_channels = 32 # 3, 32, 64, 128, ...
out_channels = 64 # 3, 32, 64, 128, ...
ones_4d = np.ones((5,5,5,in_channels))
weight_5d = np.ones((3,3,3,in_channels,out_channels))
strides_3d = [1, 1, 1, 1, 1]
in_4d = tf.constant(ones_4d, dtype=tf.float32)
filter_5d = tf.constant(weight_5d, dtype=tf.float32)
in_width = int(in_4d.shape[0])
in_height = int(in_4d.shape[1])
in_depth = int(in_4d.shape[2])
filter_width = int(filter_5d.shape[0])
filter_height = int(filter_5d.shape[1])
filter_depth = int(filter_5d.shape[2])
input_4d = tf.reshape(in_4d, [1, in_depth, in_height, in_depth, in_channels])
kernel_5d = tf.reshape(filter_5d, [filter_depth, filter_height, filter_width, in_channels, out_channels])
output_4d = tf.nn.conv3d(input_4d, kernel_5d, strides=strides_3d, padding='SAME')
print sess.run(output_4d)
sess.close()
Input & Output in Tensorflow
Summary

9Considering your labor and clarity in the explanations, upvotes of 8 are too less. – user3282777 Sep 19 '17 at 13:21

2The 2d conv with 3d input is a nice touch. I would suggest an edit to include 1d conv with 2d input (e.g. a multichannel array) and compare the difference thereof with a 2d conv with 2d input. – SumNeuron Nov 12 '17 at 18:24


1

Why is the conv direction in 2d ↲. I have seen sources that claim that the direction is → for row
1
, then → for row1+stride
. Convolution itself is shift invariant, so why does the direction of convolution matter? – Minh Triet Mar 19 '18 at 14:11
CNN 1D,2D, or 3D refers to convolution direction, rather than input or filter dimension.
For 1 channel input, CNN2D equals to CNN1D is kernel length = input length. (1 conv direction)