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Sample Problem

Sample Problem. A typical bacterium has a mass of about 2.0 fg. Express this measurement in terms of grams and kilograms. Step 1. Write what we know . . . then what we are looking for. Unknown: mass = ? g mass = ? kg. Given: mass = 2.0 fg. Sample Problem. Step 2.

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Sample Problem

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  1. Sample Problem A typical bacterium has a mass of about 2.0 fg. Express this measurement in terms of grams and kilograms. Step 1 Write what we know . . . then what we are looking for. Unknown: mass = ? g mass = ? kg Given: mass = 2.0 fg

  2. Sample Problem Step 2 These fractions equal 1, since the numerator and the denominator are equal by conversion

  3. Sample Problem Step 3 Only the first one will cancel the units of femtograms to give units of grams. Essentially, we are multiplying 2.0 fg by 1 In order to make the units equal

  4. Sample Problem, continued Take the previous answer, and use a similar process to cancel the units of grams to give units of kilograms.

  5. Accuracy and Precision • Accuracyis a description of how close a measurement is to the correct or accepted value of the quantity measured. • Precisionis the degree of exactness of a measurement. • A numeric measure of confidence in a measurement or result is known asuncertainty.A lower uncertainty indicates greater confidence.

  6. Accuracy and Precision

  7. Measurement and Parallax

  8. Significant Figures • It is important to record theprecision of your measurementsso that other people can understand and interpret your results. • A common convention used in science to indicate precision is known assignificant figures. • Significant figuresare those digits in a measurement that are known with certainty plus the first digit that is uncertain.

  9. Significant Figures Even though this ruler is marked in only centimeters and half-centimeters, if you estimate, you can use it to report measurements to a precision of a millimeter.

  10. Rules for Sig Fig Rule 1 Zeros between other nonzero digits are significant. Examples • 50.3 m has three significant figures • 3.0025 s has five significant figures

  11. Rules for Sig Fig Rule 2 Zeros in front of nonzero digits are not significant. Examples • 0.892 has three significant figures • 0.0008 s has one significant figure

  12. Rules for Sig Fig Rule 3 Zeros that are at the end of a number and also to the right of a decimal point are significant. Examples • 57.00 g has four significant figures • 2.000 000 kg has seven significant figure

  13. Rules for Sig Fig Rule 4 Zeros that are at the end of a number but left of the decimal point are not significant. Examples • 100 m has ONE significant figure • 20 m has ONE significant figure

  14. Rules for Sig. Fig. Extra Rule Zeros that are at the end of a number but left of the decimal point that are measured to be significant are indeed significant. Examples • A scale measures 1200. kg has four significant figures and is written in scientific notation: • 1.200 x 10 kg so Rule 3 applies 3

  15. Rules for Sig Fig

  16. Rules for Calculating with Significant Figures

  17. Rules for Rounding in Calculations

  18. Rules for Rounding in Calculations

  19. Objectives • Interpretdata in tables and graphs, and recognize equations that summarize data. • Distinguishbetween conventions for abbreviating units and quantities. • Usedimensional analysis to check the validity of equations. • Performorder-of-magnitude calculations.

  20. Mathematics and Physics • Tables, graphs,andequationscan make data easier to understand. • For example, consider an experiment to test Galileo’s hypothesis that all objects fall at the same rate in the absence of air resistance. • In this experiment, a table-tennis ball and a golf ball are dropped in a vacuum. • The results are recorded as a set of numbers corresponding to the times of the fall and the distance each ball falls. • A convenient way to organize the data is to form a table, as shown on the next slide.

  21. Data from Dropped-Ball Experiment A clear trend can be seen in the data. The more time that passes after each ball is dropped, the farther the ball falls.

  22. Graph from Dropped-Ball Experiment One method for analyzing the data is to construct a graph of the distance the balls have fallen versus the elapsed time since they were released. The shape of the graph provides information about the relationship between time and distance.

  23. Interpreting Graphs

  24. Physics Equations • Physicists useequationsto describe measured or predicted relationships between physical quantities. • Variablesand other specific quantities are abbreviated with letters that areboldfacedoritalicized. • Unitsare abbreviated with regular letters, sometimes called roman letters. • Two tools for evaluating physics equations aredimensional analysisandorder-of-magnitude estimates.

  25. Equation from Dropped-Ball Experiment • We can use the following equation to describe the relationship between the variables in the dropped-ball experiment: (change in position in meters) = 4.9  (time in seconds)2 • With symbols, the word equation above can be written as follows: Dy = 4.9(Dt)2 • The Greek letterD(delta) means“change in.”The abbreviationDyindicates thevertical changeina ball’s position from its starting point, andDtindicates thetime elapsed. • This equation allows you toreproduce the graphandmake predictionsabout the change in position for any time.

  26. Evaluating Physics Equations

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