# Bidirectional Associative Memory (BAM) Implementation from Scratch

• Last Updated : 06 Oct, 2021

Prerequisite: ANN | Bidirectional Associative Memory (BAM) Learning Algorithm
To implement BAM model, here are some essential consideration and approach-

1. Consider the value of M, as BAM will be constructed with M pairs of patterns. Here the value of M is 4.
2. Set A: Input Patterns
3. Set B: Corresponding Target Patterns
4. Assign the neurons in input and output layer. Here, neurons in input layer are 6 and output layer are 3
5. Compute the Weight Matrix using the BAM Algorithm
6. Test the BAM model for the input patterns which will return the corresponding target patterns as output. As well as for each of the target patterns, the BAM model will return the corresponding input patterns.

Python Implementation of BAM:

## Python3

 `# Import Python Libraries``import` `numpy as np` `# Take two sets of patterns:``# Set A: Input Pattern``x1 ``=` `np.array([``1``, ``1``, ``1``, ``1``, ``1``, ``1``]).reshape(``6``, ``1``)``x2 ``=` `np.array([``-``1``, ``-``1``, ``-``1``, ``-``1``, ``-``1``, ``-``1``]).reshape(``6``, ``1``)``x3 ``=` `np.array([``1``, ``1``, ``-``1``, ``-``1``, ``1``, ``1``]).reshape(``6``, ``1``)``x4 ``=` `np.array([``-``1``, ``-``1``, ``1``, ``1``, ``-``1``, ``-``1``]).reshape(``6``, ``1``)` `# Set B: Target Pattern``y1 ``=` `np.array([``1``, ``1``, ``1``]).reshape(``3``, ``1``)``y2 ``=` `np.array([``-``1``, ``-``1``, ``-``1``]).reshape(``3``, ``1``)``y3 ``=` `np.array([``1``, ``-``1``, ``1``]).reshape(``3``, ``1``)``y4 ``=` `np.array([``-``1``, ``1``, ``-``1``]).reshape(``3``, ``1``)` `'''``print("Set A: Input Pattern, Set B: Target Pattern")``print("\nThe input for pattern 1 is")``print(x1)``print("\nThe target for pattern 1 is")``print(y1)``print("\nThe input for pattern 2 is")``print(x2)``print("\nThe target for pattern 2 is")``print(y2)``print("\nThe input for pattern 3 is")``print(x3)``print("\nThe target for pattern 3 is")``print(y3)``print("\nThe input for pattern 4 is")``print(x4)``print("\nThe target for pattern 4 is")``print(y4)` `print("\n------------------------------")``'''``# Calculate weight Matrix: W``inputSet ``=` `np.concatenate((x1, x2, x3, x4), axis ``=` `1``)``targetSet ``=` `np.concatenate((y1.T, y2.T, y3.T, y4.T), axis ``=` `0``)``print``(``"\nWeight matrix:"``)``weight ``=` `np.dot(inputSet, targetSet)``print``(weight)` `print``(``"\n------------------------------"``)` `# Testing Phase``# Test for Input Patterns: Set A``print``(``"\nTesting for input patterns: Set A"``)``def` `testInputs(x, weight):``  ``# Multiply the input pattern with the weight matrix``  ``# (weight.T X x)``  ``y ``=` `np.dot(weight.T, x)``  ``y[y < ``0``] ``=` `-``1``  ``y[y >``=` `0``] ``=` `1``  ``return` `np.array(y)` `print``(``"\nOutput of input pattern 1"``)``print``(testInputs(x1, weight))``print``(``"\nOutput of input pattern 2"``)``print``(testInputs(x2, weight))``print``(``"\nOutput of input pattern 3"``)``print``(testInputs(x3, weight))``print``(``"\nOutput of input pattern 4"``)``print``(testInputs(x4, weight))` `# Test for Target Patterns: Set B``print``(``"\nTesting for target patterns: Set B"``)``def` `testTargets(y, weight):``  ``# Multiply the target pattern with the weight matrix``  ``# (weight X y)``  ``x ``=` `np.dot(weight, y)``  ``x[x <``=` `0``] ``=` `-``1``  ``x[x > ``0``] ``=` `1``  ``return` `np.array(x)` `print``(``"\nOutput of target pattern 1"``)``print``(testTargets(y1, weight))``print``(``"\nOutput of target pattern 2"``)``print``(testTargets(y2, weight))``print``(``"\nOutput of target pattern 3"``)``print``(testTargets(y3, weight))``print``(``"\nOutput of target pattern 4"``)``print``(testTargets(y4, weight))`
Output:
```Weight matrix:
[[4 0 4]
[4 0 4]
[0 4 0]
[0 4 0]
[4 0 4]
[4 0 4]]

------------------------------

Testing for input patterns: Set A

Output of input pattern 1
[[1]
[1]
[1]]

Output of input pattern 2
[[-1]
[-1]
[-1]]

Output of input pattern 3
[[ 1]
[-1]
[ 1]]

Output of input pattern 4
[[-1]
[ 1]
[-1]]

Testing for target patterns: Set B

Output of target pattern 1
[[1]
[1]
[1]
[1]
[1]
[1]]

Output of target pattern 2
[[-1]
[-1]
[-1]
[-1]
[-1]
[-1]]

Output of target pattern 3
[[ 1]
[ 1]
[-1]
[-1]
[ 1]
[ 1]]

Output of target pattern 4
[[-1]
[-1]
[ 1]
[ 1]
[-1]
[-1]]```

Here, for each of the input patterns, the BAM model gives the correct target patterns and for the target patterns, the model also gives the corresponding input patterns.
Hence, it signifies that the BAM model is correctly implemented.

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