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Circuit Simplification: DeMorgan’s Theorems

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1 Circuit Simplification: DeMorgan’s Theorems
Digital Electronics  2,1 Introduction to AOI Logic Circuit Simplification: DeMorgan’s Theorems Digital Electronics © 2014 Project Lead The Way, Inc. Project Lead The Way, Inc. Copyright 2009

2 DeMorgan’s Theorems DeMorgan’s Theorems Digital Electronics  2,1 Introduction to AOI Logic DeMorgan’s Theorems are two additional simplification techniques that can be used to simplify Boolean expressions. Again, the simpler the Boolean expression, the simpler the resulting logic. Introductory Slide / Overview of Presentation Project Lead The Way, Inc. Copyright 2009

3 DeMorgan’s Theorems Augustus DeMorgan Digital Electronics  2,1 Introduction to AOI Logic My name is Augustus DeMorgan. I’m an Englishman born in India in I was instrumental in the advancement of mathematics and am best known for the logic theorems that bear my name. A little history… Project Lead The Way, Inc. Copyright 2009

4 DeMorgan’s Theorem #1 Proof 1 1
DeMorgan’s Theorems Digital Electronics  2,1 Introduction to AOI Logic Proof Overview & proof of DeMorgan’s Theorem #1 1 1 The truth-tables are equal; therefore, the Boolean equations must be equal. Project Lead The Way, Inc. Copyright 2009

5 DeMorgan’s Theorem #2 Proof 1 1
DeMorgan’s Theorems Digital Electronics  2,1 Introduction to AOI Logic Proof Overview & proof of DeMorgan’s Theorem #2 1 1 The truth-tables are equal; therefore, the Boolean equations must be equal. Project Lead The Way, Inc. Copyright 2009

6 Summary Boolean & DeMorgan’s Theorems Commutative Law Associative Law
Digital Electronics  2,1 Introduction to AOI Logic Boolean & DeMorgan’s Theorems Commutative Law Associative Law Distributive Law Updates of the Boolean Theorems with the addition of DeMorgan’s Consensus Theorem DeMorgan’s Project Lead The Way, Inc. Copyright 2009

7 DeMorgan Shortcut BREAK THE LINE, CHANGE THE SIGN
DeMorgan’s Theorems Digital Electronics  2,1 Introduction to AOI Logic BREAK THE LINE, CHANGE THE SIGN Break the LINE over the two variables, and change the SIGN directly under the line. For Theorem #14A, break the line, and change the AND function to an OR function. Be sure to keep the lines over the variables. “Split and Switch” For Theorem #14B, break the line, and change the OR function to an AND function. Be sure to keep the lines over the variables. Project Lead The Way, Inc. Copyright 2009

8 DeMorgan’s: Example #1 Example
DeMorgan’s Theorems DeMorgan’s: Example #1 Digital Electronics  2,1 Introduction to AOI Logic Example Simplify the following Boolean expression and note the Boolean or DeMorgan’s theorem used at each step. Put the answer in SOP form. Pause the presentation and allow students to complete the example. The solution is on the next slide. Project Lead The Way, Inc. Copyright 2009

9 DeMorgan’s: Example #1 Example
DeMorgan’s Theorems Digital Electronics  2,1 Introduction to AOI Logic Example Simplify the following Boolean expression and note the Boolean or DeMorgan’s theorem used at each step. Put the answer in SOP form. Solution This slide includes a solution for example #1. If you print handouts, do not print this page. ; Theorem #14A ; Theorem #9 & #14B ; Theorem #9 ; Rewritten without AND symbols and parentheses Project Lead The Way, Inc. Copyright 2009

10 DeMorgan’s Theorems DeMorgan’s: Example #2 Digital Electronics  2,1 Introduction to AOI Logic So, where would such an odd Boolean expression come from? Take a look at the VERY poorly designed logic circuit shown below. If you were to analyze this circuit to determine the output function F2, you would obtain the results shown. Example Simplify the output function F2. Be sure to note the Boolean or DeMorgan’s theorem used at each step. Put the answer in SOP form. Pause the presentation and allow students to complete the example. The solution is on the next slide. Project Lead The Way, Inc. Copyright 2009

11 DeMorgan’s: Example #2 Solution ; Theorem #14A ; Theorem #9
DeMorgan’s Theorems Digital Electronics  2,1 Introduction to AOI Logic Solution ; Theorem #14A ; Theorem #9 ; Theorem #14B ; Rewritten without AND symbols This slide includes a solution for example #2. If you print handouts, do not print this page. Project Lead The Way, Inc. Copyright 2009

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