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2.3 Using Scientific Measurements

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Presentation on theme: "2.3 Using Scientific Measurements"— Presentation transcript:

1 2.3 Using Scientific Measurements

2 Accuracy vs. Precision Accuracy- closeness of measurement to correct or accepted value Precision- closeness of a set of measurements

3 Accuracy vs. Precision ACCURATE = CORRECT PRECISE = CONSISTENT
Accuracy - how close a measurement is to the accepted value Precision - how close a series of measurements are to each other ACCURATE = CORRECT PRECISE = CONSISTENT

4 Accuracy vs. Precision

5 Percent Error your value accepted value
Indicates accuracy of a measurement your value accepted value

6 Percent Error % error = 2.9 %
A student determines the density of a substance to be 1.40 g/mL. Find the % error if the accepted value of the density is 1.36 g/mL. % error = 2.9 %

7 Percent Error A technician experimentally determined the boiling point of octane to be 124.1ºC. The actual boiling point of octane is 125.7ºC. Calculate the error and percent error. Error= 1.6ºC Percent error= %

8 Significant Figures Indicates precision of a measurement.
Recording Sig Figs Sig figs in a measurement include the known digits plus a final estimated digit 2.31 cm

9 Significant Figures All certain digits plus one estimated digit

10 The underlined zeros do not count.
Significant Figures Counting Sig Figs All non-zero numbers are sig figs Zeros depend on location in number: LEADING zeros never count EMBEDDED zeros always count ,005 TRAILING zeros only count if there is a decimal point , ,500. The underlined zeros do not count.

11 Practice 101.02 EMBEDDED 5 20.0 TRAILING w/ 3 0.005302 LEADING 4
TRAILING w/o 2 TRAILING w/ 4

12 Rounding Need to use rounding to write a calculation correctly
Calculator gives you lots of insignificant figures and you must round to the right place When rounding, look at the digit after the one you can keep Greater than or equal to 5, round up Less than 5, keep the same

13 Examples Make the following have 3 sig figs: 761.50  762
 762  14.3  10.4  10800  8020  204

14 Using Sig Figs in Calculations
Adding/Subtracting: end with the least number of decimal places

15 Using Sig Figs in Calculations
Adding/Subtracting: end with the least number of decimal places

16 Using Sig Figs in Calculations
Multiplying/Dividing: end with the least number of sig figs

17 Using Sig Figs in Calculations
Multiplying/Dividing: end with the least number of sig figs

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