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Chapter 33 Basic Logic Gates. Objectives After completing this chapter, you will be able to: –Identify and explain the function of the basic logic gates.

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Presentation on theme: "Chapter 33 Basic Logic Gates. Objectives After completing this chapter, you will be able to: –Identify and explain the function of the basic logic gates."— Presentation transcript:

1 Chapter 33 Basic Logic Gates

2 Objectives After completing this chapter, you will be able to: –Identify and explain the function of the basic logic gates –Draw the symbols for the basic logic gates –Develop truth tables for the basic logic gates

3 AND Gate Two or more inputs and a single output Produces a 1 output only when all inputs are 1s Total number of possible combinations: N = 2 n where: n = total number of input variables Performs basic operation of multiplication

4 AND Gate (cont’d.) Figure 33-1. Logic symbol for an AND gate.

5 AND Gate (cont’d.) Figure 33-2. Truth table for a two-input AND gate.

6 OR Gate Produces a 1 output if any of its inputs are 1s Performs basic operation of addition Can have any number of inputs greater than one

7 OR Gate (cont’d.) Figure 33-3. Truth table for a two-input OR gate.

8 OR Gate (cont’d.) Figure 33-4. Logic symbol for an OR gate.

9 NOT Gate Referred to as an inverter Converts the input state to an opposite output state Only two input combinations possible

10 NOT Gate (cont’d.) Figure 33-5. Truth table for an inverter.

11 NOT Gate (cont’d.) Figure 33-6. Logic symbol for an inverter.

12 NAND Gate Combination of an inverter and an AND gate (NOT-AND) Most commonly used logic function Produces a 1 output when any of the inputs are 0s Available with two, three, four, eight, and thirteen inputs

13 NAND Gate (cont’d.) Figure 33-8. Truth table for a two-input NAND gate.

14 NOR Gate Combination of an inverter and an OR gate (NOT-OR) Produces a 1 output only when both inputs are 0s Available with two, three, four, and eight inputs

15 NOR Gate (cont’d.) Figure 33-10. Logic symbol for a NOR gate.

16 NOR Gate (cont’d.) Figure 33-11. Truth table for a two-input NOR gate.

17 Exclusive OR and NOR Gates Exclusive OR gate (XOR) –Has only two inputs –Produces a 1 output only if both inputs are different Exclusive NOR gate (XNOR) –Complement of the XOR gate –Produces a 1 output only when both inputs are the same

18 Exclusive OR and NOR Gates (cont’d.) Figure 33-12. Logic symbol for an exclusive OR gate.

19 Exclusive OR and NOR Gates (cont’d.) Figure 33-13. Truth table for an exclusive OR gate.

20 Exclusive OR and NOR Gates (cont’d.) Figure 33-14. Logic symbol for an exclusive NOR gate.

21 Exclusive OR and NOR Gates (cont’d.) Figure 33-15. Truth table for an exclusive NOR gate.

22 Buffer Isolates conventional gates from other circuitry Provides high-driving current for heavy circuit loads Provides noninverting input and output

23 Buffer (cont’d.) Figure 33-16. Logic symbol for a buffer.

24 Summary An AND gate produces a 1 output when all of its inputs are 1s An OR gate produces a 1 output if any of its inputs are 1s A NOT gate converts the input state to an opposite output state A NAND gate produces a 1 output when any of the inputs are 0s

25 Summary (cont’d.) A NOR gate produces a 1 output only when both inputs are 0s An exclusive OR (XOR) gate produces a 1 output only if both inputs are different An exclusive NOR (XNOR) gate produces a 1 output only when both inputs are the same

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