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Presentation transcript:

Slide 1 of 48 Measurements and Their Uncertainty

© Copyright Pearson Prentice Hall Slide 2 of Measurements and Their Uncertainty On January 4, 2004, the Mars Exploration Rover Spirit landed on Mars. Each day of its mission, Spirit recorded measurements for analysis. In the chemistry laboratory, you must strive for accuracy and precision in your measurements.

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 3 of Using and Expressing Measurements A measurement is a quantity that has both a number and a unit. Measurements are fundamental to the experimental sciences. For that reason, it is important to be able to make measurements and to decide whether a measurement is correct.

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 4 of Using and Expressing Measurements In scientific notation, a given number is written as the product of two numbers: a coefficient and 10 raised to a power. The number of stars in a galaxy is an example of an estimate that should be expressed in scientific notation.

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 5 of Accuracy, Precision, and Error Accuracy and Precision Accuracy is a measure of how close a measurement comes to the actual or true value of whatever is measured. Precision is a measure of how close a series of measurements are to one another.

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 6 of Accuracy, Precision, and Error To evaluate the accuracy of a measurement, the measured value must be compared to the correct value. To evaluate the precision of a measurement, you must compare the values of two or more repeated measurements.

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 7 of Accuracy, Precision, and Error

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 8 of Accuracy, Precision, and Error Determining Error The accepted value is the correct value based on reliable references. The experimental value is the value measured in the lab. The difference between the experimental value and the accepted value is called the error.

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 9 of Accuracy, Precision, and Error The percent error is the absolute value of the error divided by the accepted value, multiplied by 100%.

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 10 of 48 Accuracy, Precision, and Error 3.1

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 11 of Accuracy, Precision, and Error Just because a measuring device works, you cannot assume it is accurate. The scale below has not been properly zeroed, so the reading obtained for the person’s weight is inaccurate.

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 12 of 48 Significant Figures in Measurements Suppose you estimate a weight that is between 2.4 lb and 2.5 lb to be 2.46 lb. The first two digits (2 and 4) are known. The last digit (6) is an estimate and involves some uncertainty. All three digits convey useful information, however, and are called significant figures. The significant figures in a measurement include all of the digits that are known, plus a last digit that is estimated. 3.1

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 13 of 48 Significant Figures in Measurements Measurements must always be reported to the correct number of significant figures because calculated answers often depend on the number of significant figures in the values used in the calculation. 3.1

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 14 of 48 Significant Figures in Measurements 3.1

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 15 of 48 Insert Illustration of a sheet of paper listing the six rules for determining whether a digit in a measured value is significant. Redo the illustration as process art. Each rule should be a separate image. Significant Figures in Measurements 3.1

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 16 of 48 Significant Figures in Measurements 3.1

© Copyright Pearson Prentice Hall Slide 17 of 48

© Copyright Pearson Prentice Hall Slide 18 of 48

Slide 19 of 48 © Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Significant Figures in Calculations In general, a calculated answer cannot be more precise than the least precise measurement from which it was calculated. The calculated value must be rounded to make it consistent with the measurements from which it was calculated. 3.1

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 20 of Significant Figures in Calculations Rounding To round a number, you must first decide how many significant figures your answer should have. The answer depends on the given measurements and on the mathematical process used to arrive at the answer.

© Copyright Pearson Prentice Hall SAMPLE PROBLEM Slide 21 of

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 22 of Significant Figures in Calculations Addition and Subtraction The answer to an addition or subtraction calculation should be rounded to the same number of decimal places (not digits) as the measurement with the least number of decimal places.

© Copyright Pearson Prentice Hall SAMPLE PROBLEM Slide 23 of

© Copyright Pearson Prentice Hall Measurements and Their Uncertainty > Slide 24 of Significant Figures in Calculations Multiplication and Division In calculations involving multiplication and division, you need to round the answer to the same number of significant figures as the measurement with the least number of significant figures. The position of the decimal point has nothing to do with the rounding process when multiplying and dividing measurements.

© Copyright Pearson Prentice Hall SAMPLE PROBLEM Slide 25 of