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Essentials of College Physics --Serway/Vuille

Essentials of College Physics --Serway/Vuille. Chapter 1 Introduction. Theories and Experiments. The goal of physics is to develop theories based on experiments A theory is a “guess,” expressed mathematically, about how a system works

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Essentials of College Physics --Serway/Vuille

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  1. Essentials of College Physics --Serway/Vuille Chapter 1 Introduction

  2. Theories and Experiments • The goal of physics is to develop theories based on experiments • A theory is a “guess,” expressed mathematically, about how a system works • The theory makes predictions about how a system should work • Experiments check the theories’ predictions • Every theory is a work in progress

  3. Fundamental Quantities and Their Dimension • Length [L] • Mass [M] • Time [T] • other physical quantities can be constructed from these three

  4. Units • To communicate the result of a measurement for a quantity, a unit must be defined • Defining units allows everyone to relate to the same fundamental amount

  5. Systems of Measurement • Standardized systems • agreed upon by some authority, usually a governmental body • SI -- Systéme International • agreed to in 1960 by an international committee • main system used in this text • also called mks for the first letters in the units of the fundamental quantities

  6. Systems of Measurements, cont • cgs – Gaussian system • named for the first letters of the units it uses for fundamental quantities • US Customary • everyday units • often uses weight, in pounds, instead of mass as a fundamental quantity

  7. Length • Units • SI – meter, m • cgs – centimeter, cm • US Customary – foot, ft • Defined in terms of a meter – the distance traveled by light in a vacuum during a given time

  8. Mass • Units • SI – kilogram, kg • cgs – gram, g • USC – slug, slug • Defined in terms of kilogram, based on a specific cylinder kept at the International Bureau of Weights and Measures

  9. Standard Kilogram

  10. Time • Units • seconds, s in all three systems • Defined in terms of the oscillation of radiation from a cesium atom

  11. US “Official” Atomic Clock

  12. Approximate Values • Various tables in the text show approximate values for length, mass, and time • Note the wide range of values • Lengths – Table 1.1 • Masses – Table 1.2 • Time intervals – Table 1.3

  13. Table 1.1, p.2

  14. Table 1.2, p.2

  15. Table 1.3, p.2

  16. Prefixes • Prefixes correspond to powers of 10 • Each prefix has a specific name • Each prefix has a specific abbreviation • See table 1.4

  17. Table 1.4, p.3

  18. Structure of Matter • Matter is made up of molecules • the smallest division that is identifiable as a substance • Molecules are made up of atoms • correspond to elements

  19. More structure of matter • Atoms are made up of • nucleus, very dense, contains • protons, positively charged, “heavy” • neutrons, no charge, about same mass as protons • protons and neutrons are made up of quarks • orbited by • electrons, negatively charged, low mass (compared to proton) • fundamental particle, no structure

  20. Structure of Matter

  21. Dimensional Analysis • Technique to check the correctness of an equation • Dimensions (length, mass, time, combinations) can be treated as algebraic quantities • add, subtract, multiply, divide • Both sides of equation must have the same dimensions

  22. Dimensional Analysis, cont. • Cannot give numerical factors: this is its limitation • Dimensions of some common quantities are listed in Table 1.5

  23. Table 1.5, p.4

  24. Uncertainty in Measurements • There is uncertainty in every measurement, this uncertainty carries over through the calculations • need a technique to account for this uncertainty • We will use rules for significant figures to approximate the uncertainty in results of calculations

  25. Significant Figures • A significant figure is one that is reliably known • All non-zero digits are significant • Zeros are significant when • between other non-zero digits • after the decimal point and another significant figure • can be clarified by using scientific notation

  26. Operations with Significant Figures • Accuracy – number of significant figures • When multiplying or dividing two or more quantities, the number of significant figures in the final result is the same as the number of significant figures in the least accurate of the factors being combined

  27. Operations with Significant Figures, cont. • When adding or subtracting, round the result to the smallest number of decimal places of any term in the sum • If the last digit to be dropped is less than 5, drop the digit • If the last digit dropped is greater than or equal to 5, raise the last retained digit by 1

  28. Conversions • When units are not consistent, you may need to convert to appropriate ones • Units can be treated like algebraic quantities that can “cancel” each other • See the inside of the front cover for an extensive list of conversion factors • Example:

  29. Examples of various units measuring a quantity

  30. UN 1.2, p.8

  31. Order of Magnitude • Approximation based on a number of assumptions • may need to modify assumptions if more precise results are needed • Order of magnitude is the power of 10 that applies

  32. Coordinate Systems • Used to describe the position of a point in space • Coordinate system consists of • a fixed reference point called the origin • specific axes with scales and labels • instructions on how to label a point relative to the origin and the axes

  33. Types of Coordinate Systems • Cartesian • Plane polar

  34. Cartesian coordinate system • Also called rectangular coordinate system • x- and y- axes • Points are labeled (x,y)

  35. Plane polar coordinate system • Origin and reference line are noted • Point is distance r from the origin in the direction of angle , ccw from reference line • Points are labeled (r,)

  36. Trigonometry Review

  37. Figure P1.33, p.16

  38. More Trigonometry • Pythagorean Theorem • To find an angle, you need the inverse trig function • for example, • Be sure your calculator is set appropriately for degrees or radians

  39. Figure P1.35, p.17

  40. Figure 1.7, p.13

  41. Problem Solving Strategy

  42. Problem Solving Strategy • Read the problem • Identify the nature of the problem • Draw a diagram • Some types of problems require very specific types of diagrams

  43. Problem Solving cont. • Label the physical quantities • Can label on the diagram • Use letters that remind you of the quantity • Many quantities have specific letters • Choose a coordinate system and label it • Identify principles and list data • Identify the principle involved • List the data (given information) • Indicate the unknown (what you are looking for)

  44. Problem Solving, cont. • Choose equation(s) • Based on the principle, choose an equation or set of equations to apply to the problem • Substitute into the equation(s) • Solve for the unknown quantity • Substitute the data into the equation • Obtain a result • Include units

  45. Problem Solving, final • Check the answer • Do the units match? • Are the units correct for the quantity being found? • Does the answer seem reasonable? • Check order of magnitude • Are signs appropriate and meaningful?

  46. Problem Solving Summary • Equations are the tools of physics • Understand what the equations mean and how to use them • Carry through the algebra as far as possible • Substitute numbers at the end • Be organized

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