Lambton College Lecture 2: CBD-3335 Data Mining and Analysis PDF

Summary

Lambton College's lecture notes cover artificial neural networks, their components, history, and applications. The document explores the comparison of brains and computers, the perceptron, multilayer networks, and various associated concepts. It also details the structure of neurons and the training process.

Full Transcript

Lambton College
School of Computer Studies

Lecture 2

CBD-3335 Data Mining and Analysis
Artificial Neural Networks

◼The Brain
◼Brain vs. Computers

◼The Perceptron

◼Multilayer networks

◼Some Applications
 Artificial Neural Networks
◼ Other terms/names
◼ connectionist
◼ parallel distributed processing
◼ neural computation
◼ adaptive networks..
◼ History
◼ 1943-McCulloch & Pitts are generally recognised as
the designers of the first neural network
◼ 1949-First learning rule
◼ 1969-Minsky & Papert - perceptron limitation - Death
of ANN
◼ 1980’s - Re-emergence of ANN - multi-layer networks
3
 Brain and Machine
The Brain
– Pattern Recognition
– Association
– Complexity
– Noise Tolerance

The Machine
– Calculation
– Precision
– Logic

4
 The contrast in
architecture
The Von Neumann architecture
uses a single processing unit;
– Tens of millions of operations per
second
– Absolute arithmetic precision

The brain uses many slow
unreliable processors acting in
parallel

5
Features of the Brain

Ten billion (1010) neurons
On average, several thousand connections
Hundreds of operations per second
Die off frequently (never replaced)
Compensates for problems by massive
parallelism

6
 The biological inspiration

The brain has been extensively studied by
scientists.
Vast complexity prevents all but rudimentary
understanding.
Even the behaviour of an individual neuron
is extremely complex

7
The biological inspiration

Single “percepts” distributed among many
neurons
Localized parts of the brain are responsible for
certain well-defined functions (e.g. vision,
motion).

8
The Structure of Neurons

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 The Structure of Neurons
A neuron has a cell body, a branching input
structure (the dendrIte) and a branching
output structure (the axOn)

Axons connect to dendrites via synapses.
Electro-chemical signals are propagated
from the dendritic input, through the cell
body, and down the axon to other neurons

10
 The Structure of Neurons

A neuron only fires if its input signal
exceeds a certain amount (the threshold)
in a short time period.
Synapses vary in strength
– Good connections allowing a large signal
– Slight connections allow only a weak signal.

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12
The Artificial Neuron
(Perceptron)
ao+1
wj0
a1 wj1
wj2
a2
Sj f(Sj) Xj

wjn
an
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 A Simple Model of a
Neuron (Perceptron)
y1 w1j
y2 w2j

y3
w3j
 O
yi wij
Each neuron has a threshold value
Each neuron has weighted inputs from other
neurons
The input signals form a weighted sum
If the activation level exceeds the threshold, the
neuron “fires”

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 An Artificial Neuron
y1 w1j
y2 w2j

y3
w3j
 f(x) O
yi wij

Each hidden or output neuron has weighted input
connections from each of the units in the preceding layer.
The unit performs a weighted sum of its inputs, and
subtracts its threshold value, to give its activation level.
Activation level is passed through a sigmoid activation
function to determine output.
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Supervised Learning
◼ Training and test data sets
◼ Training set; input & target

16
Perceptron Training

1 if  wi xi >t
Output={ i=0
0 otherwise
◼ Linear threshold is used.
◼ W - weight value
◼ t - threshold value

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18
 Simple network

1 if  wixi >t
AND with a Biased input {
output= i=0
0 otherwise
-1
W1 = 1.5

X W2 = 1 t = 0.0

W3 = 1
Y
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 Learning algorithm
While epoch produces an error
Present network with next inputs from
epoch
Error = T – O
If Error 0 then
Wj = Wj + LR * Ij * Error
End If
End While

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 Learning algorithm
Epoch : Presentation of the entire training set to the neural
network.
In the case of the AND function an epoch consists
of four sets of inputs being presented to the
network (i.e. [0,0], [0,1], [1,0], [1,1])
Error: The error value is the amount by which the value
output by the network differs from the target
value. For example, if we required the network to
output 0 and it output a 1, then Error = -1

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 Learning algorithm
Target Value, T : When we are training a network we not
only present it with the input but also with a value
that we require the network to produce. For
example, if we present the network with [1,1] for
the AND function the target value will be 1
Output , O : The output value from the neuron
Ij : Inputs being presented to the neuron
Wj : Weight from input neuron (Ij) to the output neuron
LR : The learning rate. This dictates how quickly the
network converges. It is set by a matter of
experimentation. It is typically 0.1
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Training Perceptrons
For AND
-1 A B Output
W1 = ?
00 0
01 0
x t = 0.0
W2 = ? 10 0
11 1
W3 = ?
y

What are the weight values?
Initialize with random weight values

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 Training Perceptrons
For AND
-1 A B Output
W1 = 0.3
00 0
01 0
x t = 0.0
W2 = 0.5 10 0
11 1
W3 =-0.4
y

I1 I2 I3 Summation Output
-1 0 0 (-1*0.3) + (0*0.5) + (0*-0.4) = -0.3 0
-1 0 1 (-1*0.3) + (0*0.5) + (1*-0.4) = -0.7 0
-1 1 0 (-1*0.3) + (1*0.5) + (0*-0.4) = 0.2 1
-1 1 1 (-1*0.3) + (1*0.5) + (1*-0.4) = -0.2 0

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Learning in Neural Networks

◼ Learn values of weights from I/O pairs
◼ Start with random weights
◼ Load training example’s input
◼ Observe computed input
◼ Modify weights to reduce difference
◼ Iterate over all training examples
◼ Terminate when weights stop changing OR
when error is very small

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 Decision boundaries
In simple cases, divide feature space by
drawing a hyperplane across it.
Known as a decision boundary.
Discriminant function: returns different values
on opposite sides. (straight line)
Problems which can be thus classified are
linearly separable.

26
Linear Separability

X1
A
A
A
B Decision
A Boundary
A B
B
B
A B

A B B
X2
B
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 Rugby players & Ballet
dancers

2 Rugby ?

Height (m)
Ballet?
1

50 120
Weight (Kg)
28
 Hyperplane partitions

A single Perceptron (i.e. output unit) with
connections from each input can perform,
and learn, a linear separation.
Perceptrons have a step function activation.

29
Hyperplane partitions

An extra layer models a convex hull
– “An area with no dents in it”
– Perceptron models, but can’t learn
– Sigmoid function learning of convex hulls
– Two layers add convex hulls together
– Sufficient to classify anything “sane”.
In theory, further layers add nothing
In practice, extra layers may be better

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 Types of Layers
The input layer.
– Introduces input values into the network.
– No activation function or other processing.
The hidden layer(s).
– Perform classification of features
– Two hidden layers are sufficient to solve any problem
– Features imply more layers may be better
The output layer.
– Functionally just like the hidden layers
– Outputs are passed on to the world outside the neural
network.
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Multilayer Perceptron (MLP)
Output Values

Output Layer
Adjustable
Weights

Input Layer

Input Signals (External Stimuli)

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 Different Non-Linearly
Separable Problems
Types of Exclusive-OR Classes with Most General
Structure
Decision Regions Problem Meshed regions Region Shapes

Single-Layer Half Plane A B
Bounded By B
A
Hyperplane B A

Two-Layer Convex Open A B
Or B
A
Closed Regions B A

Three-Layer Arbitrary
(Complexity A B
B
Limited by No. A
of Nodes) B A

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 Activation functions

Transforms neuron’s input into output.
Features of activation functions:
A squashing effect is required
Prevents accelerating growth of activation
levels through the network.
Simple and easy to calculate

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Activation functions

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 Standard activation
functions
The hard-limiting threshold function
– Corresponds to the biological paradigm
either fires or not
Sigmoid functions ('S'-shaped curves)
1
– The logistic function f(x) =
1 + e -ax
– The hyperbolic tangent (symmetrical)
– Both functions have a simple differential
– Only the shape is important
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 Training Algorithms

Adjust neural network weights to map inputs
to outputs.
Use a set of sample patterns where the
desired output (given the inputs presented) is
known.
The purpose is to learn to generalize
– Recognize features which are common to
good and bad exemplars

37
 Training Algorithms

Cascade neurons together
Output from one layer is the input to the next
Each layer has its own sets of weights

HKUST
38
 Training Algorithms

Predictions are fed forward through the
network to classify

HKUST
39
 Training Algorithms

Predictions are fed forward through the
network to classify

HKUST
40
 Training Algorithms
Predictions are fed forward through the
network to classify

HKUST
41
 Training Algorithms
Predictions are fed forward through the
network to classify

HKUST
42
 Training Algorithms
Predictions are fed forward through the
network to classify

HKUST
43
 Training Algorithms
Predictions are fed forward through the
network to classify

HKUST
44
 Regularization
L1, L2 regularization (weight decay)
Dropout
Randomly turn off some neurons
Allows individual neurons to independently be
responsible for performance

Dropout: A simple way to prevent neural networks from overfitting [Srivastava JMLR 2014]
Adapted from Jia-bin Huang
 Back-Propagation

A training procedure which allows multi-layer
feedforward Neural Networks to be trained;
Can theoretically perform “any” input-output
mapping;
Can learn to solve linearly inseparable
problems.

46
Back-Propagation

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GRADIENT DESCENT
GRADIENT DESCENT
GRADIENT DESCENT

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 Gradient descent

We’ll update the weights
Move in direction opposite to gradient:
L
Time
Learning rate

Figure from Andrej Karpathy
 Gradient descent in multi-layer nets
How to update the weights at all layers?
Answer: backpropagation of error from
higher layers to lower layers

Figure from Andrej Karpathy
 Mini-batch gradient descent

Rather than compute the gradient from the loss for
all training examples, could only use some of the
data for each gradient update
We cycle through all the training examples multiple
times; each time we’ve cycled through all of them
once is called an ‘epoch’
Allows faster training (e.g. on GPUs),
parallelization

Figure from Andrej Karpathy
 Backpropagation: Error
For output units (e.g. identity
output, least squares loss):
For hidden units:

Backprop formula:
 Applications

The properties of neural networks define
where they are useful.
– Can learn complex mappings from inputs to
outputs, based solely on samples
– Difficult to analyse: firm predictions about neural
network behaviour difficult;
Unsuitable for safety-critical applications.
– Require limited understanding from trainer, who
can be guided by heuristics.

55
Neural network for OCR

◼ feedforward network A
B

◼ trained using Back- C

propagation
D
E

Hidden
Layer Output
Layer

Input
Layer
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OCR for 8x10 characters

10 10 10

8 8 8
◼ NN are able to generalise
◼ learning involves generating a partitioning of the input space
◼ for single layer network input space must be linearly
separable
◼ what is the dimension of this input space?
◼ how many points in the input space?
◼ this network is binary(uses binary values)
◼ networks may also be continuous
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 Engine management

The behaviour of a car engine is influenced
by a large number of parameters
– temperature at various points
– fuel/air mixture
– lubricant viscosity.
Major companies have used neural networks
to dynamically tune an engine depending on
current settings.

58
 ALVINN
Drives 70 mph on a public highway

30 outputs
for steering
30x32 weights
4 hidden
into one out of
units
four hidden
30x32 pixels unit
as inputs
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 Signature recognition

Each person's signature is different.
There are structural similarities which are
difficult to quantify.
One company has manufactured a machine
which recognizes signatures to within a high
level of accuracy.
– Considers speed in addition to gross shape.
– Makes forgery even more difficult.

60
 Sonar target recognition

Distinguish mines from rocks on sea-bed
The neural network is provided with a large
number of parameters which are extracted
from the sonar signal.
The training set consists of sets of signals
from rocks and mines.

61
 Stock market prediction

“Technical trading” refers to trading based
solely on known statistical parameters; e.g.
previous price
Neural networks have been used to attempt
to predict changes in prices.
Difficult to assess success since companies
using these techniques are reluctant to
disclose information.

62
 Mortgage assessment

Assess risk of lending to an individual.
Difficult to decide on marginal cases.
Neural networks have been trained to make
decisions, based upon the opinions of expert
underwriters.
Neural network produced a 12% reduction in
delinquencies compared with human experts.

63
Neural Network
Problems

Many Parameters to be set
Overfitting
long training times...

64
Parameter setting

Number of layers
Number of neurons
too many neurons, require more training time
Learning rate
from experience, value should be small ~0.1
Momentum term..

65
Over-fitting

With sufficient nodes can classify any
training set exactly
May have poor generalisation ability.
Cross-validation with some patterns
– Typically 30% of training patterns
– Validation set error is checked each epoch
– Stop training if validation error goes up

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 Training time

How many epochs of training?
– Stop if the error fails to improve (has reached a
minimum)
– Stop if the rate of improvement drops below a
certain level
– Stop if the error reaches an acceptable level
– Stop when a certain number of epochs have
passed

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 References

https://www.slideserve.com/phelan-cortez/artificial-neural-
networks
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