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Math Unit. Measurement When making any measurement, always estimate one place past what is actually known.

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Presentation on theme: "Math Unit. Measurement When making any measurement, always estimate one place past what is actually known."— Presentation transcript:

1 Math Unit

2 Measurement When making any measurement, always estimate one place past what is actually known.

3 Example For example, if a meter stick has calibrations (markings) to the 0.1 cm, the measurement must be estimated to the 0.01 cm. If you think it’s perfectly on a line, estimate the last digit to be zero –For example, if you think it’s on the 2.1 cm line, estimate it to 2.10 cm.

4 Electronic Devices When making a measurement with a digital readout, simply write down the measurement. The last digit is the estimated digit.

5 Significant Digits Significant digits are all digits in a number which are known with certainty plus one uncertain digit.

6 5 Rules for Counting Significant Digits in a Measurment 1. All nonzero numbers are significant. –132.54 g has 5 significant digits.

7 2. All zeros between nonzero numbers are significant. 130.0054 m has 7 significant digits

8 3.Zeros to the right of a nonzero digit but to the left of an understood decimal point are not significant unless shown by placing a decimal point at the end of the number. 190 000 mL has 2 significant digits 190 000. mL has 6 significant digits

9 4.All zeros to the right of a decimal point but to the left of a nonzero digit are NOT significant. 0.000 572 mg has 3 significant digits

10 5.All zeros to the right of a decimal point and to the right of a nonzero digit are significant. 460.000 dm has 6 significant digits

11 Shortcut If the number contains a decimal point, draw an arrow starting at the left through all zeros and up to the 1st nonzero digit. The digits remaining are significant.

12 Exact Numbers Exact numbers have an infinite (∞) number of significant digits. 3 types of numbers with (∞) number of sig digs: 1. Definitions (12 eggs = 1dozen) 2. Counting numbers (there are 24 desks in this room 3. Numbers in a formula (2  r)

13 Try these 0.002 5 1.002 5 0.002 500 0 14 100.0

14 If the quantity does not contain a decimal point, draw an arrow starting at the right through all zeroes up to the 1st nonzero digit. The digits remaining are significant.

15 Try these 225 10 004 14 100 103

16 Remember – Atlantic Pacific Decimal Point Present, start at the Pacific. Decimal Point Absent, start at the Atlantic.

17 How many significant digits do these have? 1.050 20.06 13 0.303 0 373.109 420 000 970 0.002 0.007 80 145.55

18 Rounding Rules Round up if the digit immediately to the right of the digit you are rounding to is Greater than 5 Round 0.236 to 2 significant digits 5 followed by another nonzero number Round 0.002351 to 2 significant digits Round 0.00235000000001 to 2 significant digits

19 Kepp the digit the same if the digit immediately to the right of the digit you are rounding to is Less than 5 round 1.23 to 2 significant digits

20 What if the digit to the right of the number you are rounding to is 5 and there’s nothing after it? That means you are perfectly in the middle. Half of the time you must round up and half of the time you must round down. There are 2 rules for this

21 Look to the digit to the right of the number you are rounding to. If it is even – keep the same. –Round 0.8645 to 3 significant digits If it is odd – round up. –Round 0.8675 to 3 significant digits.

22 Round These to 3 significant digits 279.3 32.395 18.29 42.353 0.008 752 18.77 7.535 32.25 5 001

23 Applying significant digits to arithmetic operations

24 Addition and Subtraction Look at the numbers being added or subtracted and identify which one has the lowest number of decimal places. Calculate the answer. Round the answer to the lowest number of decimal places.

25 Examples 14.565 + 7.32 = 21.885 7.32 has only 2 decimal places, so the answer should be rounded to 21.88 143.52 – 100.6 = 42.92 100.6 has only 1 decimal place, so the answer should be rounded to 42.9

26 Multiplication and Division Look at the numbers being multiplied or divided and identify which one has the lowest number of significant digits. Calculate the answer. Round the answer to the lowest number of significant digits.

27 Examples 172.6 x 24.1 = 4159.66 24.1 has only 3 significant digits, so the answer should be rounded to 4160 172.6 ÷ 24.1 = 7.161 82 24.1 only has 3 significant digits, so the answer should be rounded to 7.16

28 Practice Add 5.34 cm, 9.3 cm, and 12 cm. Subtract 4.31 cm from 7.542 cm. Subtract 1.512 g from 16.748 g. Add 2.572 5 m, 14.55 m and 0.035 m. Multiply 176.335 and 0.003 2. Divide 475.90 by 35. Multiply 0.000 565, 1.579 52, and 45.006 86. Multiply 1 456.00 by 0.035 0 and divide that by 17.070.

29 Percent Error This is a way of expressing how far off an experimental measurement is from the accepted/true value. Final Exam Question

30 Formula X 100

31 Scientific Notation It is used for extremely large or small numbers. The general form of the equation is: m x 10 n With the absolute value of m ≥ 1 and < 10

32 Practice 12 300 -1 456 0.005 17 -0.000 6 6.650 x 10 2 3.498 x 10 5 -2.208 x 10 -3 1.1650 x 10 -4

33 Arithmetic Rules for Scientific Notation Follow the same rules for math operations with scientific notation as you would with standard notation.

34 Addition and Subtraction (3.37 x 10 4 ) + (2.29 x 10 5 ) (9.8 x 10 7 ) + (3.2 x 10 5 ) (8.6 x 10 4 ) – (7.6 x 10 3 ) (2.238 6 x 10 9 ) – (3.335 7 x 10 7 )

35 Multiplication and Division (1.2 x 10 3 ) x (3.3 x 10 5 ) (7.73 x 10 2 ) x (3.4 x 10 -3 ) (9.9 x 10 6 )  (3.3 x 10 3 ) (1.55 x 10 -7 )  (5.0 x 10 -4 )

36 Temperature Conversion Temperature is defined as the average kinetic energy of the particles in a sample of matter. The units for this are o C and Kelvin (K). Note that there is no degree symbol for Kelvin.

37 Kelvin Scale The Kelvin scale is based on absolute zero. This is the theoretical temperature when motion stops.

38 Heat is a measurement of the total kinetic energy of the particles in a sample of matter. The units for this are the calorie (cal) and the Joule (J).

39 Formulas T(K) = t( o C) + 273.15 t( o C) = T(K) - 273.15

40 Dimensional Analysis Dimensional analysis is the algebraic process of changing from one system of units to another.

41 You must develop the habit of including units with all measurements in calculations. Units are handled in calculations as any algebraic symbol:  Numbers added or subtracted must have the same units.

42  Units are multiplied as algebraic symbols. For example: 10 cm x 10 cm = 10 cm 2

43  Units are cancelled in division if they are identical.  For example, 27 g ÷ 2.7 g/cm 3 = 10 cm 3. Otherwise, they are left unchanged. For example, 27 g/10. cm 3 = 2.7 g/cm 3.

44 Conversion Factor These are fractions obtained from an equivalence between two units. For example, consider the equality 1 in. = 2.54 cm. This equality yields two conversion factors which both equal one: and

45 Convert 5.08 cm to inches 5.08 cm x = 2.00 in

46 Convert 6.53 in to cm 6.53 in x = 16.6 cm

47 Here are some common English/metric conversions. You will not need to memorize these. 1 mm = 0.039 37 in1 in = 2.54 cm 1 cm = 0.393 7 in1 yd = 0.914 40 m 1 m = 39.37 in1 mile = 1.609 Km 1 Km = 0.621 4 mi. 1 pound = 453.6 g 1 quart = 946 ml1 ounce = 28.35 g 1 quart = 0.946 L

48 Converting within metric units In section 2-5 of your textbook, you learned the relationship between metric prefixes and their base units. You need to have these relationships memorized to do these problems. When you write your conversions factor, always use the number 1 with the unit with the prefix and meaning of the prefix with the base unit.

49 Examples

50 Try to set up these conversion factors


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