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AOI Logic Implementation © 2014 Project Lead The Way, Inc.Digital Electronics.

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Presentation on theme: "AOI Logic Implementation © 2014 Project Lead The Way, Inc.Digital Electronics."— Presentation transcript:

1 AOI Logic Implementation © 2014 Project Lead The Way, Inc.Digital Electronics

2 AOI Logic Implementation This presentation will demonstrate how to… Design an AOI logic circuit from a Sum-Of-Products (SOP) logic expression. Design an AOI logic circuit from a Product-Of-Sums (POS) logic expression. EQUALS AOI Logic CircuitLogic Expression 2

3 Designing (AOI) Sum of Product (SOP) Logic Circuits Design Steps Implement each Minterm in the logic expression with an AND gate with the same number of inputs as there are variables in the Minterm. (i.e., AB = 2 input gate, ABC = 3 input gate, ABCD = 4 input gate, etc.) OR together the outputs of the AND gates to produce the logic expression. If necessary, gates can be cascaded to create gates with more inputs. 3

4 Example #1: Sum of Product (SOP) Logic Circuits Design an AOI Logic Circuit for the SOP logic expression shown below. 4

5 SOLUTION 5

6 In this class, we only have access to 2-input OR gates, 2-input AND gates, Limiting your design to these gates, redesign the AOI Logic Circuit for the SOP expression in the previous example. 6 Example #2: Sum of Product (SOP) Logic Circuits

7 SOLUTION 7

8 8 redesign the AOI Logic Circuit for the SOP expression in the previous example.

9 Product of sums The difference is that the outputs of multiple OR gates are combined with a single AND gate which outputs the final result. The expression below adheres to the format of a POS expression 9

10 POS CIRCUIT ANALYSIS 10

11 Design Steps Implement each Maxterm in the logic expression with an OR gate with the same number of inputs as there are variables in the Maxterm. (i.e., A+B = 2 input gate, A+B+C = 3 input gate, A+B+C+D = 4 input gate, etc.) AND together the outputs of the OR gates to produce the logic expression. If necessary, gates can be cascaded to create gates with more inputs. 11 Designing (AOI) Product of Sum (POS) Logic Circuits

12 Example Design an AOI Logic Circuit for the POS logic expression shown below. 12 Example #3: Product of Sum (POS) Logic Circuits

13 Design an AOI Logic Circuit for the POS logic expression shown below. Solution 13 Example #3: Product of Sum (POS) Logic Circuits F2F2

14 Limiting your design to only 2-input OR gates, 2-input AND gates, and 3-input AND gates redesign the AOI Logic Circuit for the POS logic expression in the previous example. 14 Example #4: Product of Sum (POS) Logic Circuits

15 Limiting your design to only 2-input OR gates, 2-input AND gates, and 3-input AND gates redesign the AOI Logic Circuit for the POS logic expression in the previous example. Solution 15 Example #4: Product of Sum (POS) Logic Circuits F2F2

16 Design an AOI Logic Circuit for the SOP logic expression shown below. Solution 16 Example #1: Sum of Product (SOP) Logic Circuits F1F1

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