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Chapter 1 What is Physics?

Chapter 1 What is Physics?. 1.1 Mathematics and Physics. Physics. A branch of knowledge that involves the study of the physical world (from atoms to the universe). The study of the relationship between matter and energy. Math in Physics.

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Chapter 1 What is Physics?

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  1. Chapter 1What is Physics?

  2. 1.1 Mathematics and Physics

  3. Physics • A branch of knowledge that involves the study of the physical world (from atoms to the universe). • The study of the relationship between matter and energy.

  4. Math in Physics • Equations are used to model observations and make predictions. • Scientists compare their experimental data with the results predicted by their models/equations.

  5. SI Units • In order to effectively communicate results, scientists need a standard system of measurements. • International System of Units (SI) • An adaptation of the metric system • A convenient set of standardized measurements related by powers of ten • Scientific institutions have defined and regulate measures • See Handout/Textbook p.5-6

  6. The meter is defined as: • 1/10,000,000 of the distance form the north pole to the equator. • Distance between 2 lines engraved on a platinum-iridium bar in Paris. • Distance traveled by light in a vacuum in 1/299,792,458 seconds.

  7. The second is defined as: • 1/86,400 of the average solar day. • Frequency of the radiation emitted my a cesium atom.

  8. The kilogram is defined as: • Mass of a small platinum-iridium metal cylinder kept at a controlled temperature and humidity.

  9. Dimensional Analysis • A method of treating units as algebraic quantities, that can be cancelled. • Use to see what your final unit should be. • EX:

  10. Converting Units • Multiply by a form of one to change the “appearance” but not the value. • Convert to base unit first • Put the power with the base unit • EX: Convert 5.9 km to m • EX: Convert 47.8 pm to mm • EX: Convert 5.56 ng to kg

  11. Scientific Notation • A way to write really big/small numbers. • Writes numbers as powers of 10. • EX: 1,700 = 1.7 x 103 • EX: 0.0000079 = 7.9 x 10-6 • Make sure you know how to use scientific notation on your calculator.

  12. Significant Digits • The valid digits in a measurement (last digit for any given measurement is the uncertain digit). • Numbers believed to be correct • Rules: • 1) Nonzero digits are always significant. • EX: 8.954 = 4 sd • 2) All final digits after the decimal are significant. • EX: 5.3331000 = 8 sd • 3) Zeros between 2 other sig digs are always significant. • EX: 809.07 = 5 sd • 4) Zeros used solely as place holders are not significant. • EX: 0.00000000005 = 1 sd

  13. Significant digits • Scientific notation can help clear up any ambiguity when it comes to determining how many significant digits a value has. • EX: 184, 000could have 3,4,5, or 6 sd. • 1.8400 x 105 has 5 sd

  14. State the number of significant digits in each: • 3021 • 7.8 x 105 • 7.08 x 105 • 7.80 x 107 • 0.0000007021 • 59.0000

  15. Determining the correct number of sd after performing a mathematical operation: • Add/Sub – least precise number • EX: 5.12 cm + 6.129 cm • Mult/Div – least number of sd • EX: 12.78 m x 1.23 m

  16. A = 1.24 m B = 0.23 cm • Which has more sig digits? • Which is more precise?

  17. A Scientific Method:

  18. Scientific Method • Experiments/Results must be reproducible. • Other scientists must be able to recreate the experiment with similar results

  19. Scientific Law • A rule of nature that sums up related observations to describe a pattern in nature. • Laws only describe what happens – not why they happen. • EX: Law of Reflection – angle of incidence equals the angle of reflection.

  20. Scientific Theory • An explanation based on many observations supported by experimental results. • Best available explanation for why things happen the way they do. • EX: Einstein’s Theory of Relativity

  21. 1.2 Measurement

  22. Measurement • A comparison between an unknown quantity and an accepted standard. • EX: You measure your desk with a meter stick. • Many measurements contain a certain amount of uncertainty (±) • A new measurement within the margin of uncertainty confirms the old measurement .

  23. Comparing results and uncertainties • Three students measure the length of a model car: • Student 1 average: 18.8 ± 0.3 cm • Student 2 average: 19.0 ± 0.2 cm • Student 3 average: 18.3 ± 0.1 cm • Which are in agreement? • Which are not in agreement?

  24. Precision • The degree of exactness of a measurement. • When dealing with multiple measurements, the smaller the variation between them, the more precise they are. (small ±) • Which student was most precise? • Which was least precise?

  25. Precision • To get a precise measurement, use a tool with the smallest divisions possible. • This will allow your measurement to be taken out to more digits.

  26. precision • Always measure to the nearest mark and then estimate the last digit. • A measurement can never be more precise than the tool used to measure it. • The precision of a measurement is said to be ½ the smallest division of the tool. • Meter stick: 1 mm divisions • Max range of error based on tool: ± 0.5 mm

  27. Accuracy • How well the results of an experiment agree with the accepted (“real”) value. • If the model car was actually 19.0 cm, which student was most accurate? • Which was least accurate?

  28. Accuracy • To make sure a measuring tool is accurate (even if it is precise), it must be calibrated. • Make sure it meads 0 when it should. • Make sure it gives the correct reading when measuring an accepted standard.

  29. Precision vs accuracy

  30. parallax • The apparent shift in the position of an object when it is viewed from different angles. • Pay attention to the angle at which you are reading a measurement. Read it from straight above.

  31. 1.3 graphing Data

  32. Independent Variable – the variable that is changed or manipulated. The experimenter controls it directly. • Dependent Variable – depends on the independent variable. It will change according to how the independent variable changes.

  33. When plotting data: • 1) Identify the independent and dependent variables. • Plot the independent variable on the horizontal (x) axis. • Plot the dependent variable on the vertical (y) axis. • 2) Determine the range of the data and divide your axis accordingly. • 3) Plot the data points and draw in the best fit line/smooth curve. • 4) Label and title the graph.

  34. Linear relationships • A straight line graph. • Variables are directly proportional. • Equation: y=mx + b • Pay attention to t he units of the slope. • It often represents a physical quantity.

  35. Quadratic relationship • Graph is a parabola. • One variable depends on the square of the other. • Equation: y = ax2 + bx + c

  36. Inverse relationship • Graph is a hyperbola. • One variable depends on the inverse of the other. • Equation: y = a/x or xy = a, where “a” is a constant.

  37. You can use graphs to make predictions. • Make sure your predictions are within reason. • EX: Graphing length of a spring for different masses. • What limitations to prediction are there?

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