1. Intro to Digital Electronics

2. Classifications of Electronic Circuits Switching Circuits – by turning electricity on and off. – Figure 1 – Known as the digital method. Regulating Circuits – controls intensity of current. – Figure 2 – Known as the analog method Figure 1 – Current is On or Off Figure 2 – Increase/Decrease Current

3. What’s Digital and Analog DigitalAnalog Computers Microprocessors Watches Displays Audio Amplifiers Radios Televisions – stations have recently gone digital

4. Why Digital? Digital electronics are simple, practical, and reliable. Combines simple switches and gates to create electrical functions. Digital means switching. – HI or 1 (one) or On – LO or 0 (zero) or Off

5. Truth Table of a Digital Circuit The operation of the circuit to the right is represented by the table. Describes switch and output status. Truth tables represent the operation of a circuit. Truth Table SwitchBulb OPENOFF (LO or 0) CLOSEDON (HI or 1)

6. Timing Diagrams of a Digital Circuit Timing diagrams may also represent a digital circuit operation, in this case resistor voltage.

7. Logic Gates

8. Logic? Logic circuits are circuits that make decisions based on the inputs they receive. – Remember what the digital signals can be? – 1 or 0; HI or LO; On or Off

9. Logic Indicators Logic Indicator is a device that indicates the logic state (either HI or LO) of a certain point in a circuit. – Usually a LED

10. Boolean Algebra Conventional Algebra has 4 basic operations – Addition, subtraction, multiplication, division Boolean Algebra has 6 basic operations – AND, OR, NAND, NOR, NOT, YES Example: Using the AND Gate – Read as “A anded B equals Q” – Also read as A  B = Q Try using the OR Gate: Q B A Q B A

11. The AND Logic Gate ABQ 111 100 010 000 When is the output of this gate HI? Boolean Equation A  B = Q

12. The OR Logic Gate ABQ 111 101 011 000 When is the output of this gate HI? Boolean Equation A + B = Q

13. The NOT (Inverter) Logic Circuit AQ 10 01 The NOT logic circuit is also called the “inverter”. Boolean Equation A = Q “A is equal to not Q” Widely used in many circuits; NAND and NOR gates are created by adding inverters to AND and OR gates.

14. The YES Logic Circuit AQ 11 00 The input is the same as the output. Also used as: Amplifiers – makes a weak signal strong. Buffers – Isolates delicate circuits Boolean Equation A = Q “A equals Q”

15. Transistors 39043906

16. The NOR Logic Gate ABQ 110 100 010 001 The result of this Gate is always the opposite of an OR Gate. Boolean Equation A + B = Q

17. The OR Gate vs. the NOR Gate The OR GateThe NOR Gate ABQ 111 101 011 000 ABQ 110 100 010 001

18. The NAND Logic Gate ABQ 110 101 011 001 The result of this Gate is always the opposite of an AND Gate. Boolean Equation A  B = Q

19. The AND Gate vs. the NAND Gate The AND GateThe NAND Gate ABQ 111 100 010 000 ABQ 110 101 011 000