How do I initialize weights and biases of a network (via e.g. He or Xavier initialization)?
10 Answers
Single layer
To initialize the weights of a single layer, use a function from torch.nn.init
. For instance:
conv1 = torch.nn.Conv2d(...)
torch.nn.init.xavier_uniform(conv1.weight)
Alternatively, you can modify the parameters by writing to conv1.weight.data
(which is a torch.Tensor
). Example:
conv1.weight.data.fill_(0.01)
The same applies for biases:
conv1.bias.data.fill_(0.01)
nn.Sequential
or custom nn.Module
Pass an initialization function to torch.nn.Module.apply
. It will initialize the weights in the entire nn.Module
recursively.
apply(fn): Applies
fn
recursively to every submodule (as returned by.children()
) as well as self. Typical use includes initializing the parameters of a model (see also torchnninit).
Example:
def init_weights(m):
if isinstance(m, nn.Linear):
torch.nn.init.xavier_uniform(m.weight)
m.bias.data.fill_(0.01)
net = nn.Sequential(nn.Linear(2, 2), nn.Linear(2, 2))
net.apply(init_weights)

10I found a
reset_parameters
method in the source code of many modules. Should I override the method for weight initialization?– Yang BoJun 26, 2018 at 6:02 
1what if I want to use a Normal distribution with some mean and std? Jul 4, 2018 at 21:16

34

1
nn.init.xavier_uniform
is now deprecated in favor ofnn.init.xavier_uniform_
Mar 8 at 12:14 
1@xjcl The default initialization for a
Linear
layer isinit.kaiming_uniform_(self.weight, a=math.sqrt(5))
.– PeiffapApr 29 at 1:04
We compare different mode of weightinitialization using the same neuralnetwork(NN) architecture.
All Zeros or Ones
If you follow the principle of Occam's razor, you might think setting all the weights to 0 or 1 would be the best solution. This is not the case.
With every weight the same, all the neurons at each layer are producing the same output. This makes it hard to decide which weights to adjust.
# initialize two NN's with 0 and 1 constant weights
model_0 = Net(constant_weight=0)
model_1 = Net(constant_weight=1)
 After 2 epochs:
Validation Accuracy
9.625%  All Zeros
10.050%  All Ones
Training Loss
2.304  All Zeros
1552.281  All Ones
Uniform Initialization
A uniform distribution has the equal probability of picking any number from a set of numbers.
Let's see how well the neural network trains using a uniform weight initialization, where low=0.0
and high=1.0
.
Below, we'll see another way (besides in the Net class code) to initialize the weights of a network. To define weights outside of the model definition, we can:
 Define a function that assigns weights by the type of network layer, then
 Apply those weights to an initialized model using
model.apply(fn)
, which applies a function to each model layer.
# takes in a module and applies the specified weight initialization
def weights_init_uniform(m):
classname = m.__class__.__name__
# for every Linear layer in a model..
if classname.find('Linear') != 1:
# apply a uniform distribution to the weights and a bias=0
m.weight.data.uniform_(0.0, 1.0)
m.bias.data.fill_(0)
model_uniform = Net()
model_uniform.apply(weights_init_uniform)
 After 2 epochs:
Validation Accuracy
36.667%  Uniform Weights
Training Loss
3.208  Uniform Weights
General rule for setting weights
The general rule for setting the weights in a neural network is to set them to be close to zero without being too small.
Good practice is to start your weights in the range of [y, y] where
y=1/sqrt(n)
(n is the number of inputs to a given neuron).
# takes in a module and applies the specified weight initialization
def weights_init_uniform_rule(m):
classname = m.__class__.__name__
# for every Linear layer in a model..
if classname.find('Linear') != 1:
# get the number of the inputs
n = m.in_features
y = 1.0/np.sqrt(n)
m.weight.data.uniform_(y, y)
m.bias.data.fill_(0)
# create a new model with these weights
model_rule = Net()
model_rule.apply(weights_init_uniform_rule)
below we compare performance of NN, weights initialized with uniform distribution [0.5,0.5) versus the one whose weight is initialized using general rule
 After 2 epochs:
Validation Accuracy
75.817%  Centered Weights [0.5, 0.5)
85.208%  General Rule [y, y)
Training Loss
0.705  Centered Weights [0.5, 0.5)
0.469  General Rule [y, y)
normal distribution to initialize the weights
The normal distribution should have a mean of 0 and a standard deviation of
y=1/sqrt(n)
, where n is the number of inputs to NN
## takes in a module and applies the specified weight initialization
def weights_init_normal(m):
'''Takes in a module and initializes all linear layers with weight
values taken from a normal distribution.'''
classname = m.__class__.__name__
# for every Linear layer in a model
if classname.find('Linear') != 1:
y = m.in_features
# m.weight.data shoud be taken from a normal distribution
m.weight.data.normal_(0.0,1/np.sqrt(y))
# m.bias.data should be 0
m.bias.data.fill_(0)
below we show the performance of two NN one initialized using uniformdistribution and the other using normaldistribution
 After 2 epochs:
Validation Accuracy
85.775%  Uniform Rule [y, y)
84.717%  Normal Distribution
Training Loss
0.329  Uniform Rule [y, y)
0.443  Normal Distribution

17What is the task you optimize for? And how can an all zeros solution give zero loss?– dedObedSep 26, 2019 at 11:02

7@ashunigion I think you misrepresent what Occam says: "entities should not be multiplied without necessity". He does not say you should pick up the simplest approach. If that was the case, then you should not have used a neural network in the first place. Feb 19, 2021 at 2:58

If you follow occam’s razor, you may also want to consider gaussian initialization, since that is the distribution with the highest entropy (for given variance), ie the "least informative"– NephanthApr 29 at 5:39
To initialize layers, you typically don't need to do anything.
PyTorch will do it for you. If you think about it, this makes a lot of sense. Why should we initialize layers, when PyTorch can do that following the latest trends?
For instance, the Linear
layer's __init__
method will do Kaiming He initialization:
init.kaiming_uniform_(self.weight, a=math.sqrt(5))
if self.bias is not None:
fan_in, _ = init._calculate_fan_in_and_fan_out(self.weight)
bound = 1 / math.sqrt(fan_in) if fan_in > 0 else 0
init.uniform_(self.bias, bound, bound)
Similarly, this holds for other layers types. For e.g., Conv2d
, check here.
NOTE: The advantage of proper initialization is faster training speed. If your problem requires special initialization, you can still do it afterwards.

2The default initialization doesn't always give the best results, though. I recently implemented the VGG16 architecture in Pytorch and trained it on the CIFAR10 dataset, and I found that just by switching to
xavier_uniform
initialization for the weights (with biases initialized to 0), rather than using the default initialization, my validation accuracy after 30 epochs of RMSprop increased from 82% to 86%. I also got 86% validation accuracy when using Pytorch's builtin VGG16 model (not pretrained), so I think I implemented it correctly. (I used a learning rate of 0.00001.)– littleOJul 6, 2020 at 19:55 
1This is because they haven't used Batch Norms in VGG16. It is true that proper initialization matters and that for some architectures you pay attention. For instance, if you use (nn.conv2d(), ReLU() sequence) you will init Kaiming He initialization designed for relu your conv layer. PyTorch cannot predict your activation function after the conv2d. This make sense if you evaluate the eignevalues, but typically you don't have to do much if you use Batch Norms, they will normalize outputs for you. If you plan to win to SotaBench competition it matters.– prostiJul 6, 2020 at 23:55
import torch.nn as nn
# a simple network
rand_net = nn.Sequential(nn.Linear(in_features, h_size),
nn.BatchNorm1d(h_size),
nn.ReLU(),
nn.Linear(h_size, h_size),
nn.BatchNorm1d(h_size),
nn.ReLU(),
nn.Linear(h_size, 1),
nn.ReLU())
# initialization function, first checks the module type,
# then applies the desired changes to the weights
def init_normal(m):
if type(m) == nn.Linear:
nn.init.uniform_(m.weight)
# use the modules apply function to recursively apply the initialization
rand_net.apply(init_normal)
If you want some extra flexibility, you can also set the weights manually.
Say you have input of all ones:
import torch
import torch.nn as nn
input = torch.ones((8, 8))
print(input)
tensor([[1., 1., 1., 1., 1., 1., 1., 1.],
[1., 1., 1., 1., 1., 1., 1., 1.],
[1., 1., 1., 1., 1., 1., 1., 1.],
[1., 1., 1., 1., 1., 1., 1., 1.],
[1., 1., 1., 1., 1., 1., 1., 1.],
[1., 1., 1., 1., 1., 1., 1., 1.],
[1., 1., 1., 1., 1., 1., 1., 1.],
[1., 1., 1., 1., 1., 1., 1., 1.]])
And you want to make a dense layer with no bias (so we can visualize):
d = nn.Linear(8, 8, bias=False)
Set all the weights to 0.5 (or anything else):
d.weight.data = torch.full((8, 8), 0.5)
print(d.weight.data)
The weights:
Out[14]:
tensor([[0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000],
[0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000],
[0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000],
[0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000],
[0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000],
[0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000],
[0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000],
[0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000, 0.5000]])
All your weights are now 0.5. Pass the data through:
d(input)
Out[13]:
tensor([[4., 4., 4., 4., 4., 4., 4., 4.],
[4., 4., 4., 4., 4., 4., 4., 4.],
[4., 4., 4., 4., 4., 4., 4., 4.],
[4., 4., 4., 4., 4., 4., 4., 4.],
[4., 4., 4., 4., 4., 4., 4., 4.],
[4., 4., 4., 4., 4., 4., 4., 4.],
[4., 4., 4., 4., 4., 4., 4., 4.],
[4., 4., 4., 4., 4., 4., 4., 4.]], grad_fn=<MmBackward>)
Remember that each neuron receives 8 inputs, all of which have weight 0.5 and value of 1 (and no bias), so it sums up to 4 for each.
Sorry for being so late, I hope my answer will help.
To initialise weights with a normal distribution
use:
torch.nn.init.normal_(tensor, mean=0, std=1)
Or to use a constant distribution
write:
torch.nn.init.constant_(tensor, value)
Or to use an uniform distribution
:
torch.nn.init.uniform_(tensor, a=0, b=1) # a: lower_bound, b: upper_bound
You can check other methods to initialise tensors here
Iterate over parameters
If you cannot use apply
for instance if the model does not implement Sequential
directly:
Same for all
# see UNet at https://github.com/milesial/PytorchUNet/tree/master/unet
def init_all(model, init_func, *params, **kwargs):
for p in model.parameters():
init_func(p, *params, **kwargs)
model = UNet(3, 10)
init_all(model, torch.nn.init.normal_, mean=0., std=1)
# or
init_all(model, torch.nn.init.constant_, 1.)
Depending on shape
def init_all(model, init_funcs):
for p in model.parameters():
init_func = init_funcs.get(len(p.shape), init_funcs["default"])
init_func(p)
model = UNet(3, 10)
init_funcs = {
1: lambda x: torch.nn.init.normal_(x, mean=0., std=1.), # can be bias
2: lambda x: torch.nn.init.xavier_normal_(x, gain=1.), # can be weight
3: lambda x: torch.nn.init.xavier_uniform_(x, gain=1.), # can be conv1D filter
4: lambda x: torch.nn.init.xavier_uniform_(x, gain=1.), # can be conv2D filter
"default": lambda x: torch.nn.init.constant(x, 1.), # everything else
}
init_all(model, init_funcs)
You can try with torch.nn.init.constant_(x, len(x.shape))
to check that they are appropriately initialized:
init_funcs = {
"default": lambda x: torch.nn.init.constant_(x, len(x.shape))
}
Cuz I haven't had the enough reputation so far, I can't add a comment under
the answer posted by prosti in Jun 26 '19 at 13:16.
def reset_parameters(self):
init.kaiming_uniform_(self.weight, a=math.sqrt(3))
if self.bias is not None:
fan_in, _ = init._calculate_fan_in_and_fan_out(self.weight)
bound = 1 / math.sqrt(fan_in)
init.uniform_(self.bias, bound, bound)
But I wanna point out that actually we know some assumptions in the paper of Kaiming He, Delving Deep into Rectifiers: Surpassing HumanLevel Performance on ImageNet Classification, are not appropriate, though it looks like the deliberately designed initialization method makes a hit in practice.
E.g., within the subsection of Backward Propagation Case, they assume that $w_l$ and $\delta y_l$ are independent of each other. But as we all known, take the score map $\delta y^L_i$ as an instance, it often is $y_isoftmax(y^L_i)=y_isoftmax(w^L_ix^L_i)$ if we use a typical cross entropy loss function objective.
So I think the true underlying reason why He's Initialization works well remains to unravel. Cuz everyone has witnessed its power on boosting deep learning training.
Here is the better way, just pass your whole model
import torch.nn as nn
def initialize_weights(model):
# Initializes weights according to the DCGAN paper
for m in model.modules():
if isinstance(m, (nn.Conv2d, nn.ConvTranspose2d, nn.BatchNorm2d)):
nn.init.normal_(m.weight.data, 0.0, 0.02)
# if you also want for linear layers ,add one more elif condition
If you see a deprecation warning (@Fábio Perez)...
def init_weights(m):
if type(m) == nn.Linear:
torch.nn.init.xavier_uniform_(m.weight)
m.bias.data.fill_(0.01)
net = nn.Sequential(nn.Linear(2, 2), nn.Linear(2, 2))
net.apply(init_weights)

1You can comment over there at Fábio Perez's answer to keep the answers clean. Oct 25, 2019 at 9:31