1. Chapter 1 Components, Quantities, and Units

2. Objectives Recognize components and measuring instruments, Recognize components and measuring instruments, List electrical and magnetic quantities and their units, List electrical and magnetic quantities and their units, Use Scientific notation to express quantities, Use Scientific notation to express quantities, Use metric prefixes to express large and small numbers, Use metric prefixes to express large and small numbers, Convert from one metric unit to another metric unit. Convert from one metric unit to another metric unit.

3. Electrical Components and Measuring Instruments This chapter will give an overview of the instruments and components you will use throughout this book.

4. Resistors Resistors limit electric current in a circuit. Insert figure 1-1

5. Capacitors Capacitors store electrical charge. Insert figure1-5

6. Inductors Inductors, or coils, are used to store energy in an electromagnetic field.

7. Transformers Transformers are used for ac coupling, or to increase/decrease ac voltages.

8. Electronic Instruments Insert figure 1-10

9. DC Power supply A DC power supply provides current and voltage to power electronic circuits.

10. Function Generator A function generator provides electronic signals for our circuits.

11. Voltmeters A voltmeter is used to measure voltage in a circuit. Ammeter An ammeter is used to measure current in a circuit. Ohmmeter An ohmmeter is used to measure resistance.

12. Digital Multimeter A digital multimeter (DMM) measures voltage, current or resistance, depending upon the function selected.

13. Oscilloscope The oscilloscope us used for observing and measuring voltage signals in a circuit.

14. Electrical Units Letters are used in electronics to represent quantities and units. Letters are used in electronics to represent quantities and units. The units and symbols are defined by the SI system. The units and symbols are defined by the SI system.

15. Magnetic Units Letters are also used to represent magnetic quantities and units in the SI system. Letters are also used to represent magnetic quantities and units in the SI system.

16. Scientific Notation Scientific notation is a method of expressing numbers. Scientific notation is a method of expressing numbers. A quantity is expressed as a number between 1 and 10, and a power of ten. A quantity is expressed as a number between 1 and 10, and a power of ten. Example: 5000 would be expressed as 5 x 10 3 in Scientific notation.

17. Powers of Ten The power of ten is expressed as an exponent of the base 10. The power of ten is expressed as an exponent of the base 10. Exponent indicates the number of places that the decimal point is moved to the right (positive exponent) or left (negative exponent). Exponent indicates the number of places that the decimal point is moved to the right (positive exponent) or left (negative exponent).

18. Engineering Notation Engineering notation is similar to Scientific notation, except that engineering notation can have from 1 to 3 digits to the left of the decimal place, and the powers of 10 are multiples of 3.

19. Scientific notation vs Engineering notation Consider the number: 23,000 In Scientific notation it would be expressed as:2.3 x 10 4 In Engineering notation it would be expressed as:23 x 10 3

20. Metric Prefixes Metric prefixes are symbols that represent the powers of ten used in Engineering notation.

21. Prefix:Symbol:Magnitude:Meaning (multiply by): Yotta-Y10 24 1 000 000 000 000 000 000 000 000 Zetta-Z10 21 1 000 000 000 000 000 000 000 Exa-E10 18 1 000 000 000 000 000 000 Peta-P10 15 1 000 000 000 000 000 Tera-T10 12 1 000 000 000 000 Giga-G10 9 1 000 000 000 Mega-M10 6 1 000 000 myria-my10 4 10 000 (this is now obsolete) kilo-k10 3 1000 hecto-h10 2 100 deka-da10 ----

22. deci-d10 -1 0.1 centi-c10 -2 0.01 milli-m10 -3 0.001 micro-u (mu)10 -6 0.000 001 nano-n10 -9 0.000 000 001 pico-p10 -12 0.000 000 000 001 femto-f10 -15 0.000 000 000 000 001 atto-a10 -18 0.000 000 000 000 000 001 zepto-z10 -21 0.000 000 000 000 000 000 001 yocto-y10 -24 0.000 000 000 000 000 000 000 001 Prefix:Symbol:Magnitude:Meaning (multiply by): The mass of the earth is 5983 Yg (yottagrams), and it gains another 40 Gg (gigagrams) every year from captured meteorites and cosmic dust. The average distance to the moon is 384.4 Mm (megameters). The average distance to the sun is 149.5 Gm (gigameters). The wavelength of yellow light is 590 nm (nanometers). The diameter of a hydrogen atom is about 70 pm (picometers). The mass of a proton is about 1.67 yg (yoctograms), and that of an electron about 0.000 91 yg (yoctograms).

23. Example of Metric Prefix Consider the quantity 0.025 amperes, it could be expressed as 25 x 10 -3 A in Engineering notation, or using the metric prefix as 25 mA.

24. Summary Resistors limit electric current. Resistors limit electric current. Capacitors store electrical charge. Capacitors store electrical charge. Inductors store energy in an electromagnetic field. Inductors store energy in an electromagnetic field. Transformers magnetically couple ac voltages, and may step these voltages up/down. Transformers magnetically couple ac voltages, and may step these voltages up/down.

25. Summary Power supplies provide current and voltage. Power supplies provide current and voltage. Voltmeters measure voltage. Voltmeters measure voltage. Ammeters measure current. Ammeters measure current. Ohmmeters measure resistance. Ohmmeters measure resistance. Digital Multimeters (DMM) measure voltage, current and resistance. Digital Multimeters (DMM) measure voltage, current and resistance.

26. Summary Function generators provide electronic signals for our circuits. Function generators provide electronic signals for our circuits. An oscilloscope is used for observing and measuring voltages in a circuit. An oscilloscope is used for observing and measuring voltages in a circuit.

27. Summary Scientific notation expresses a number as one digit to the left of the decimal point times a power of ten. Scientific notation expresses a number as one digit to the left of the decimal point times a power of ten. Engineering notation expresses a number as one, two or three digits to the left of the decimal point times a power of ten that is a multiple of 3. Engineering notation expresses a number as one, two or three digits to the left of the decimal point times a power of ten that is a multiple of 3. Metric symbols represent powers of 10 that are multiples of 3. Metric symbols represent powers of 10 that are multiples of 3.