Artificial Neuron network

Neural Network dan Logika Kabur

 Neural networks and fuzzy logic are two
complimentary technologies
 Neural networks can learn from data and
feedback
– It is difficult to develop an insight about
the meaning associated with each neuron
and each weight
– Viewed as “black box” approach (know
what the box does but not how it is done
conceptually!)

 Two ways to adjust the weights using
backpropagation
– Online/pattern Mode: adjusts the weights
based on the error signal of one input-output
pair in the trainning data.
• Example: trainning set containning 500
input-output pairs, this mode BP adjusts the
weights 500 times for each time the
algorithm sweeps through the trainning set.
If the algorithm sweeps converges after 1000
sweeps, each weight adjusted a total of
50,000 times

– Batch mode (off-line): adjusts weights
based on the error signal of the entire
training set.
• Weights are adjusted once only after all
the trainning data have been processed by
the neural network.
• From previous example, each weight in the
neural network is adjusted 1000 times.

 Fuzzy rule-based models are easy to
comprehend (uses linguistic terms and the
structure of if-then rules)
 Unlike neural networks, fuzzy logic does not
come with a learning algorithm
– Learning and identification of fuzzy models
need to adopt techniques from other areas
 Since neural networks can learn, it is natural
to marry the two technologies.

Neuro-fuzzy system can be classified into
three categories:
1. A fuzzy rule-based model constructed using
a supervised NN learning technique
reinforcement-based learning
NN to construct its fuzzy partition of the
input space

 A class of adaptive networks that are
functionally equivalent to fuzzy inference
systems.
 ANFIS architectures representing both the
Sugeno and Tsukamoto fuzzy models

Assume - two inputs X and Y and one output Z
Rule 1: If x is A1 and y is B1,
then f1 = p1x + q1y +r1
Rule 2: If x is A2 and y is B2,
then f2 = p2x + q2y +r2

Every node i in this layer is an adaptive node with a node function
O1,i = mAi (x), for I = 1,2, or O1,i = mBi-2 (y), for I = 3,4
Where x (or y) is the input to node i and Ai (or Bi) is a linguistic
label
** O1,i is the membership grade of a fuzzy set and it specifies the
degree to which the given input x or y satisfies the quantifies

Typically, the membership function for a fuzzy
set can be any parameterized membership
function, such as triangle, trapezoidal,
Guassian, or generalized Bell function.
Parameters in this layer are referred to as
Antecedence Parameters

Every node i in this layer is a fixed node labeled P,
whose output is the product of all the incoming
signals:
O2,i = Wi = min{mAi (x) , mBi (y)}, i = 1,2
Each node output represents the firing strength of
a rule.

Every node in this layer is a fixed node labeled N. The ith node
calculates the ratio of the ith rule’s firing strength to the sum of
all rules’firing stregths:
O3,i = Wi = Wi /(W1+W2) , i =1,2
(normalized firing strengths]

Every node i in this layer is an adaptive node with
a node function
__ __
O 4,i = wi fi = wi (pix + qiy +ri) …Consequent
parameters

The single node in this layer is a fixed node labeled S,
which computes the overall output as the summation
of all incoming signals:
__
O 5,1 = Si wi fi

ANFIS architecture for the Sugeno fuzzy model,
weight normalization is performed at the
very last layer

Equivalent ANFIS architecture using the
Tsukamoto fuzzy model

Artificial Neuron network

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