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ECE/CS 352 Digital Systems Fundamentals

ECE/CS 352 Digital Systems Fundamentals. Spring 2001 Chapter 2 – Part 5. Tom Kaminski & Charles R. Kime. Three-Variable Maps. Reduced literal product terms for SOP standard forms correspond to rectangles on K-maps containing cell counts that are powers of 2.

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ECE/CS 352 Digital Systems Fundamentals

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  1. ECE/CS 352 Digital Systems Fundamentals Spring 2001 Chapter 2 – Part 5 Tom Kaminski& Charles R. Kime ECE/CS 352 Digital System Fundamentals

  2. Three-Variable Maps • Reduced literal product terms for SOP standard forms correspond to rectangles on K-maps containing cell counts that are powers of 2. • Rectangles of 2 cells represent 2 adjacent minterms; of 4 cells represent 4 minterms that form a “pairwise adjacent” ring. • Rectangles can be in many different positions on the K-map since adjacencies are not confined to cells truly next to teach other. ECE/CS 352 Digital System Fundamentals

  3. X Y Z Three-Variable Maps • Topological warps of 3-variable K-maps that show all adjacencies: • Venn Diagram Cylinder 0 4 6 5 7 3 1 2 ECE/CS 352 Digital System Fundamentals

  4. Y Y X X Z Z Z Three-Variable Maps • Example Shapes of Rectangles: 1 2 3 0 5 7 6 4 ECE/CS 352 Digital System Fundamentals

  5. Three Variable Maps F(x,y,z) = x y+ z ECE/CS 352 Digital System Fundamentals

  6. Three-Variable Map Simplification • F(X,Y,Z) = (0,1,2,4,6,7) ECE/CS 352 Digital System Fundamentals

  7. Four Variable Maps ECE/CS 352 Digital System Fundamentals

  8. Four Variable Terms • Four variable maps can have terms of: • Single one = 4 variables, (i.e. Minterm) • Two ones = 3 variables, • Four ones = 2 variables • Eight ones = 1 variable, • Sixteen ones = zero variables (i.e. Constant "1") ECE/CS 352 Digital System Fundamentals

  9. Four-Variable Maps • Example Shapes of Rectangles: Y Y 1 2 3 0 X W 6 5 7 4 X 12 15 14 13 W 11 10 8 9 X Z Z Z ECE/CS 352 Digital System Fundamentals

  10. Four-Variable Map Simplification • F(W,X,Y,Z) = (0, 2,4,5,6,7,8,10,13,19) ECE/CS 352 Digital System Fundamentals

  11. Four-Variable Map Simplification • F(W,X,Y,Z) = (3,4,5,7,13,14,15,17) ECE/CS 352 Digital System Fundamentals

  12. Systematic Simplification • A Prime Implicant is a product term obtained by combining the maximum possible number of adjacent squares in the map. • A is a prime implicant is called an Essential Prime Implicant if it is the only prime implicant that covers (includes) one or more minterms. • Prime Implicants and Essential Prime Implicants can be determined by inspection of the K-Map. • A set of prime implicants that "covers all minterms" means that, for each minterm of the function, there is at least one prime implicant in the selected set of prime implicants that includes the minterm. ECE/CS 352 Digital System Fundamentals

  13. Example of Prime Implicants ECE/CS 352 Digital System Fundamentals

  14. Prime Implicant Practice • F(A,B,C,D) = (0,2,3,8,9,10,11,12,13,14,15) ECE/CS 352 Digital System Fundamentals

  15. (No Don’t Cares) Systematic Approach 1. Select all Essential PI's 2. Find and delete all Less Than PIs 3. Repeat 1) and 2) until all minterms are covered. If Cycles Occur: 4. Arbitrarily select a PI and generate a cover. 5. Delete the selected PI and generate a new cover 6. Select the cover with fewer literals 7. If a new cycle appears, repeat steps 4), 5), and 6) and compare all solutions for the best. ECE/CS 352 Digital System Fundamentals

  16. Other PI Selection ECE/CS 352 Digital System Fundamentals

  17. Example 2 from Supplement 1 ECE/CS 352 Digital System Fundamentals

  18. Example 2 (Continued) ECE/CS 352 Digital System Fundamentals

  19. Another Example • G(A,B,C,D) =  (0,2,3,4,7,12,13,14,15) ECE/CS 352 Digital System Fundamentals

  20. Five Variable or More K-Maps ECE/CS 352 Digital System Fundamentals

  21. Don't Cares in K-Maps • Sometimes a function table contains entries for which it is known the input values will never occur. In these cases, the output value need not be defined. By placing a “don't care” in the function table, it may be possible to arrive at a lower cost logic circuit. • “Don't cares” are usually denoted with an "x" in the K-Map or function table. • Example of “Don't Cares” - A logic function defined on 4-bit variables encoded as BCD digits where the four-bit input variables never exceed 9, base 2. Symbols 1010, 1011, 1100, 1101, 1110, and 1111 will never occur. Thus, we DON'T CARE what the function value is for these combinations. • “Don't cares“are used in minimization procedures in such a way that they may ultimately take on either a 0 or 1 value in the result. ECE/CS 352 Digital System Fundamentals

  22. Example: BCD “5 or More” ECE/CS 352 Digital System Fundamentals

  23. Product of Sums Example • F(A,B,C,D) =  (3,9,11,12,13,14,15) + d(1,4,6) • Use and take complement of result: ECE/CS 352 Digital System Fundamentals

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