# How to visualize a neural network

I want to draw a dynamic picture for a neural network to watch the weights changed and the activation of neurons during learning. How could I simulate the process in Python?

More precisely, if the network shape is: [1000, 300, 50], then I wish to draw a three layer NN which contains 1000, 300 and 50 neurons respectively. Further, I hope the picture could reflect the saturation of neurons on each layer during each epoch.

I've no idea about how to do it. Can someone shed some light on me?

• – Fredrik Pihl Apr 27 '15 at 7:53
• Do they need to be visible all at the same time (with values)? – Caramiriel Apr 27 '15 at 8:03
• @Caramiriel Yes. Are there any packages supporting this needs? – fishiwhj Apr 27 '15 at 8:11

## 5 Answers

I adapted some parts to the answer of Milo

``````from matplotlib import pyplot
from math import cos, sin, atan

class Neuron():
def __init__(self, x, y):
self.x = x
self.y = y

def draw(self, neuron_radius):
circle = pyplot.Circle((self.x, self.y), radius=neuron_radius, fill=False)
pyplot.gca().add_patch(circle)

class Layer():
def __init__(self, network, number_of_neurons, number_of_neurons_in_widest_layer):
self.vertical_distance_between_layers = 6
self.horizontal_distance_between_neurons = 2
self.neuron_radius = 0.5
self.number_of_neurons_in_widest_layer = number_of_neurons_in_widest_layer
self.previous_layer = self.__get_previous_layer(network)
self.y = self.__calculate_layer_y_position()
self.neurons = self.__intialise_neurons(number_of_neurons)

def __intialise_neurons(self, number_of_neurons):
neurons = []
x = self.__calculate_left_margin_so_layer_is_centered(number_of_neurons)
for iteration in xrange(number_of_neurons):
neuron = Neuron(x, self.y)
neurons.append(neuron)
x += self.horizontal_distance_between_neurons
return neurons

def __calculate_left_margin_so_layer_is_centered(self, number_of_neurons):
return self.horizontal_distance_between_neurons * (self.number_of_neurons_in_widest_layer - number_of_neurons) / 2

def __calculate_layer_y_position(self):
if self.previous_layer:
return self.previous_layer.y + self.vertical_distance_between_layers
else:
return 0

def __get_previous_layer(self, network):
if len(network.layers) > 0:
return network.layers[-1]
else:
return None

def __line_between_two_neurons(self, neuron1, neuron2):
angle = atan((neuron2.x - neuron1.x) / float(neuron2.y - neuron1.y))
x_adjustment = self.neuron_radius * sin(angle)
y_adjustment = self.neuron_radius * cos(angle)
line = pyplot.Line2D((neuron1.x - x_adjustment, neuron2.x + x_adjustment), (neuron1.y - y_adjustment, neuron2.y + y_adjustment))
pyplot.gca().add_line(line)

def draw(self, layerType=0):
for neuron in self.neurons:
neuron.draw( self.neuron_radius )
if self.previous_layer:
for previous_layer_neuron in self.previous_layer.neurons:
self.__line_between_two_neurons(neuron, previous_layer_neuron)
# write Text
x_text = self.number_of_neurons_in_widest_layer * self.horizontal_distance_between_neurons
if layerType == 0:
pyplot.text(x_text, self.y, 'Input Layer', fontsize = 12)
elif layerType == -1:
pyplot.text(x_text, self.y, 'Output Layer', fontsize = 12)
else:
pyplot.text(x_text, self.y, 'Hidden Layer '+str(layerType), fontsize = 12)

class NeuralNetwork():
def __init__(self, number_of_neurons_in_widest_layer):
self.number_of_neurons_in_widest_layer = number_of_neurons_in_widest_layer
self.layers = []
self.layertype = 0

def add_layer(self, number_of_neurons ):
layer = Layer(self, number_of_neurons, self.number_of_neurons_in_widest_layer)
self.layers.append(layer)

def draw(self):
pyplot.figure()
for i in range( len(self.layers) ):
layer = self.layers[i]
if i == len(self.layers)-1:
i = -1
layer.draw( i )
pyplot.axis('scaled')
pyplot.axis('off')
pyplot.title( 'Neural Network architecture', fontsize=15 )
pyplot.show()

class DrawNN():
def __init__( self, neural_network ):
self.neural_network = neural_network

def draw( self ):
widest_layer = max( self.neural_network )
network = NeuralNetwork( widest_layer )
for l in self.neural_network:
network.add_layer(l)
network.draw()
``````

Now the layers are also labeled, the axis are deleted and constructing the plot is easier. It's simply done by:

``````network = DrawNN( [2,8,8,1] )
network.draw()
``````

Here a net with the following structure is constructed:

• Hi, recently found your NN visualisation. I've tried it but it didn't work for me. More specifically, the error I get is name 'plotNN' is not defined. I've checked the indentations but I couldn't make it work @OliBlum – Yags Jul 16 '18 at 15:56
• `DrawNN( [2,8,8,1] ).draw()` works. I also ajusted this in my post – Oliver Wilken Jul 17 '18 at 8:34
• sorry, I still couldn't get it to work @OliBlum – Yags Jul 17 '18 at 9:31
• what is the error message now? – Oliver Wilken Jul 17 '18 at 10:39
• name network is not defined – Yags Jul 17 '18 at 10:40

The Python library matplotlib provides methods to draw circles and lines. It also allows for animation.

I've written some sample code to indicate how this could be done. My code generates a simple static diagram of a neural network, where each neuron is connected to every neuron in the previous layer. Further work would be required to animate it. ``````from matplotlib import pyplot
from math import cos, sin, atan

class Neuron():
def __init__(self, x, y):
self.x = x
self.y = y

def draw(self):
circle = pyplot.Circle((self.x, self.y), radius=neuron_radius, fill=False)
pyplot.gca().add_patch(circle)

class Layer():
def __init__(self, network, number_of_neurons):
self.previous_layer = self.__get_previous_layer(network)
self.y = self.__calculate_layer_y_position()
self.neurons = self.__intialise_neurons(number_of_neurons)

def __intialise_neurons(self, number_of_neurons):
neurons = []
x = self.__calculate_left_margin_so_layer_is_centered(number_of_neurons)
for iteration in xrange(number_of_neurons):
neuron = Neuron(x, self.y)
neurons.append(neuron)
x += horizontal_distance_between_neurons
return neurons

def __calculate_left_margin_so_layer_is_centered(self, number_of_neurons):
return horizontal_distance_between_neurons * (number_of_neurons_in_widest_layer - number_of_neurons) / 2

def __calculate_layer_y_position(self):
if self.previous_layer:
return self.previous_layer.y + vertical_distance_between_layers
else:
return 0

def __get_previous_layer(self, network):
if len(network.layers) > 0:
return network.layers[-1]
else:
return None

def __line_between_two_neurons(self, neuron1, neuron2):
angle = atan((neuron2.x - neuron1.x) / float(neuron2.y - neuron1.y))
x_adjustment = neuron_radius * sin(angle)
y_adjustment = neuron_radius * cos(angle)
line = pyplot.Line2D((neuron1.x - x_adjustment, neuron2.x + x_adjustment), (neuron1.y - y_adjustment, neuron2.y + y_adjustment))
pyplot.gca().add_line(line)

def draw(self):
for neuron in self.neurons:
neuron.draw()
if self.previous_layer:
for previous_layer_neuron in self.previous_layer.neurons:
self.__line_between_two_neurons(neuron, previous_layer_neuron)

class NeuralNetwork():
def __init__(self):
self.layers = []

def add_layer(self, number_of_neurons):
layer = Layer(self, number_of_neurons)
self.layers.append(layer)

def draw(self):
for layer in self.layers:
layer.draw()
pyplot.axis('scaled')
pyplot.show()

if __name__ == "__main__":
vertical_distance_between_layers = 6
horizontal_distance_between_neurons = 2
neuron_radius = 0.5
number_of_neurons_in_widest_layer = 4
network = NeuralNetwork()
network.add_layer(3)
network.add_layer(4)
network.add_layer(1)
network.draw()
``````

To implement what Mykhaylo has suggested, I've slightly modified the Milo's code in order to allow providing weghts as an argument which will affect every line's width. This argument is optional, as there's no sense of providing weights for the last layer. All this to be able to visualize my solution to this exercise on neural networks. I've given binary weights (either 0 or 1), so that lines with zero weight not be drawn at all (to make an image more clear).

``````from matplotlib import pyplot
from math import cos, sin, atan
import numpy as np

class Neuron():
def __init__(self, x, y):
self.x = x
self.y = y

def draw(self):
circle = pyplot.Circle((self.x, self.y), radius=neuron_radius, fill=False)
pyplot.gca().add_patch(circle)

class Layer():
def __init__(self, network, number_of_neurons, weights):
self.previous_layer = self.__get_previous_layer(network)
self.y = self.__calculate_layer_y_position()
self.neurons = self.__intialise_neurons(number_of_neurons)
self.weights = weights

def __intialise_neurons(self, number_of_neurons):
neurons = []
x = self.__calculate_left_margin_so_layer_is_centered(number_of_neurons)
for iteration in range(number_of_neurons):
neuron = Neuron(x, self.y)
neurons.append(neuron)
x += horizontal_distance_between_neurons
return neurons

def __calculate_left_margin_so_layer_is_centered(self, number_of_neurons):
return horizontal_distance_between_neurons * (number_of_neurons_in_widest_layer - number_of_neurons) / 2

def __calculate_layer_y_position(self):
if self.previous_layer:
return self.previous_layer.y + vertical_distance_between_layers
else:
return 0

def __get_previous_layer(self, network):
if len(network.layers) > 0:
return network.layers[-1]
else:
return None

def __line_between_two_neurons(self, neuron1, neuron2, linewidth):
angle = atan((neuron2.x - neuron1.x) / float(neuron2.y - neuron1.y))
x_adjustment = neuron_radius * sin(angle)
y_adjustment = neuron_radius * cos(angle)
line_x_data = (neuron1.x - x_adjustment, neuron2.x + x_adjustment)
line_y_data = (neuron1.y - y_adjustment, neuron2.y + y_adjustment)
line = pyplot.Line2D(line_x_data, line_y_data, linewidth=linewidth)
pyplot.gca().add_line(line)

def draw(self):
for this_layer_neuron_index in range(len(self.neurons)):
neuron = self.neurons[this_layer_neuron_index]
neuron.draw()
if self.previous_layer:
for previous_layer_neuron_index in range(len(self.previous_layer.neurons)):
previous_layer_neuron = self.previous_layer.neurons[previous_layer_neuron_index]
weight = self.previous_layer.weights[this_layer_neuron_index, previous_layer_neuron_index]
self.__line_between_two_neurons(neuron, previous_layer_neuron, weight)

class NeuralNetwork():
def __init__(self):
self.layers = []

def add_layer(self, number_of_neurons, weights=None):
layer = Layer(self, number_of_neurons, weights)
self.layers.append(layer)

def draw(self):
for layer in self.layers:
layer.draw()
pyplot.axis('scaled')
pyplot.show()

if __name__ == "__main__":
vertical_distance_between_layers = 6
horizontal_distance_between_neurons = 2
neuron_radius = 0.5
number_of_neurons_in_widest_layer = 4
network = NeuralNetwork()
# weights to convert from 10 outputs to 4 (decimal digits to their binary representation)
weights1 = np.array([\
[0,0,0,0,0,0,0,0,1,1],\
[0,0,0,0,1,1,1,1,0,0],\
[0,0,1,1,0,0,1,1,0,0],\
[0,1,0,1,0,1,0,1,0,1]])
network.add_layer(10, weights1)
network.add_layer(4)
network.draw()
``````

Here is a library based on matplotlib, named viznet (pip install viznet). To begin, you can read this notebook. Here is an example Viznet defines a set of brush rules.

``````node1 >> (0, 1.2)  # put a node centered at axis (0, 1.2)
node2 >> (2, 0)    # put a node centered at axis (2, 0)
edge >> (node1, node2)  # connect two nodes
``````

Here, node1 and node2 are two node brushes, like `node1 = NodeBrush('nn.input', ax=d.ax, size='normal')`

The first parameter defines the theme of node. For a neural network node (theme start with 'nn.'), its style refers from Neural Network Zoo Page For edges, we can define its brush like `edge = EdgeBrush('->', ax=d.ax, lw=2)` The first parameters is the theme,'-' for straight line, '.' for dashed line, '=' for double line, '>','<' are left arrow and right arrow. The proportion of '-', '.' and '=' in a theme code decides their length in a line. For example, '->' and '->-' represents lines with arrow at end and arrow at center respectively. The following are several examples With only nodes and edges are not enough, the rule for connection plays a fundamentally role. Except basic connection rule, you can create pins on nodes. I will stop here and leave it for documents. These flexible features make it capable for drawing also tensor networks and quantum circuits.

This project just embraced its v0.1 release, I will keep improving it. You can access its Github repo for latest version, and wellcome for pulling requests or posting issues!

Draw the network with nodes as circles connected with lines. The line widths must be proportional to the weights. Very small weights can be displayed even without a line.