Laboratory1: Exercise 1

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3 September 2007 MAR 110 Lab1: Exercise 1 - Conversions 1 1-1. THE METRIC SYSTEM Laboratory1: Exercise 1 Metric - English Conversion [based on the Chauffe & Jefferies (2007)] The French developed the metric system during the 1790s. Unlike the "English" system, in which the difference between smaller and larger units is irregular and has no scientific foundation, the metric system is based on multiples of 10. Smaller and larger units can be obtained simply by moving the decimal point that is multiplying or dividing by 10. For example, in the "English" system there are 12 inches to a foot (ft), but 3 ft to a yard, and 1760 yards in a mile. By contrast, in the metric system there are 10 m to a decameter (dm), 10 dm to a hectometer (hm), and 10 hm to a kilometer (km). The convenience and regularity of the metric system make it the standard system used in scientific research. The basic units of the metric system are the meter for length, gram for mass (weight), liter for volume, and degree Celsius ( O C) for temperature. These terms have been defined in terms of practical considerations. For example, one meter is equal to one ten millionth of the distance between the North Pole and the equator. The gram is the mass of one cubic centimeter (or one millionth of a cubic meter) of water at a temperature of 4 C. The liter is the volume of a cubic decimeter (or one thousandth of a cubic meter). A degree Celsius is one-hundredth of the change in temperature between the freezing and boiling points of water. The French also experimented with decimal time, developing two types of clocks, one with 10 hours in a day and the other with one 100 hours in a day, but neither was widely accepted and both were eventually abandoned. Thus the metric and English systems use the same divisions of time and angles. Because all parts of the metric system use the same prefixes to indicate size, it is useful to learn them and their meanings (see Table 1). Some of these terms will be familiar to you because they are used to describe the size of computer memory. They are kilobyte (1000 bytes), megabyte (1 million bytes) and gigabyte (1 billion bytes), or are parts of words with which you may be familiar, as in kilowatts (1000 watts), and in the names of insects, as in millipede (1000 legs)

3 September 2007 MAR 110 Lab1: Exercise 1 - Conversions 2 and centipede (100 legs). Table 1 Metric Prefixes and their Numerical Meanings Prefix Size giga (G) 1,000,000,000 (1 billion) mega (M) 1,000,000 (1 million) kilo (k) 1,000 (1 thousand) hecto (h) 100 (1 hundred) deka (da) 10 (ten) deci (d) 0.1 (1 tenth) centi (c) 0.01 (1 hundredth) milli (m) 0.001 (1 thousandth) micro (µ) 0.000001 (1 millionth) nano (n) 0.000000001 (1 billionth) Until the U.S. adopts the metric system, as has most of the world and all branches of science, it will be necessary to learn how to convert units between the metric and English systems. Conversion factors are provided in a chart at the end of this laboratory. When converting between the English and metric systems, it is important to keep track of the units. The examples below show the procedure for using the conversion charts on pages 6 and 7 to convert units for a few different cases. Example 1. Convert 15.7 miles into kilometers (Note the abbreviations used below). a. From the conversion charts on pages 5 and 6, we find that 1 mi = 1.609 km. b. This equality can be converted into a fraction that is equal to 1 by either (1) dividing the term on both sides of the equal sign by 1 mile; or (2) dividing both sides by 1.609 km. Thus the above equality (or equation) can be written as, 1 = 1.609 km / l mi = 1 mi / l.609 km c. Any number that is multiplied by 1 is the same number. That is 15.7 mi x 1 = 15.7 mi. d. Select the fraction (in b.) above that is equal to 1 and when multiplied by 15.7 mi, will yield the distance in kilometers. The correct fraction is 1 = 1.609 km / l mi. e. BECAUSE when we substitute it for 1 below the conversion we sought is made

3 September 2007 MAR 110 Lab1: Exercise 1 - Conversions 3 15.7 mi x 1 = 15.7 mi. 15.7 mi x 1.609 km/l mi = 25.26 km Example 2. Convert 8.54 miles into centimeters. From Example 1, we know that to convert miles to kilometers we multiply the number of miles by the factor 1.609 km / mi. The conversion from kilometers to centimeters is similar as follows. a. From the conversion chart, we find that 1 km = 1000 m AND ALSO 1 m = 100 cm. b. The equality (or equation) 1 km = 1000 m can be converted into a fraction that is equal to 1 by either (1) dividing the term on both sides of the equal sign by 1 km; or (2) dividing both sides by 1000 m, or 1 = 1 km / 1000 m = 1000 m / 1 km c. The equality (or equation) 1 m = 100 cm can be converted likewise into the following fractions, 1 = 1 m / 100 cm = 100 cm / l m. d. Since any number (8.54 mi in this case) can be multiplied by 1, as many times as we want, and it still remains the same number, we can write 8.54 mi x 1 x 1 x 1 = 8.54 mi. f. To make the conversion from 8.54 mi to the equivalent distance is centimeters (cm) select the 3 fractions (all equal to 1) that, when multiplied by 8.54 mi, will convert it (1) from units of miles to kilometers, (2) from units of kilometers to meters; and finally (3) from units of meters to centimeters. g. That is substitute the fractions 1.609 km / l mi, 1000 mi / km and 100 cm / l m for the 1s below 8.54 mi x 1 x 1 x 1 = 8.54 mi. So that the conversion is made 8.54 mi x 1.609 km /1 mi x 1000 m / l km x 100 cm/1m = 1,374,086 cm. NOTE: In each set of the sequence the proper units cancel each other out until the units that are sought remain.

3 September 2007 MAR 110 Lab1: Exercise 1 - Conversions 4 Example 3. Convert 16 kilometers into inches. a. From the conversion chart we know 1 km = 0.6214 mi 1 mi = 5280 ft and 1 ft = 12 in. b. Thus, and 1 = 0.6214 mi/km = 1 km/0.6214 mi, 1 = 5280 ft/mi = 1 mi/5280 ft 1 = 12 in/ft = 1 ft/12 in. c. Since, as above, 16 km x 1 x 1 x 1 = 16 km. d. Then the substitution of the appropriate sequence of fractions in to the above equation will lead to the sequential cancellation of units leaving the equivalent distance in inches as follows: 16 km x 1 x 1 x 1 = 16 km 16 km x 0.614 m1/km x 5280 ft/mi x 12 in/ft = 622,448.64 in. Example 4. Convert 1.245 cubic feet (ft 3 ) into liters (L). a. From the convert chart we know 1 ft 3 = 1728 in 3 1 in 3 = 16.39 cm 3 1 cm 3 = 1 ml and 1 L = 1000 ml b. Thus, 1 = 1728 in 3 /ft 3 = 1 ft 3 /l728 ft 3, 1 = 16.39 cm 3 /in 3 = 1 in 3 /16.39 cm 3, 1 = 1 cm 3 /ml = 1 ml/cm 3 and 1 = 1 L/l000 ml = 1000 m/l L.

3 September 2007 MAR 110 Lab1: Exercise 1 - Conversions 5 c. Since any number multiplied by 1, no matter how many times, is still the same number, then we can write for this case 1.245 ft 3 x 1 x 1 x 1 x 1 = 1.245 ft 3. d. Then the substitution of the appropriate sequence of fractions in to the above equation will lead to the sequential cancellation of units leaving the equivalent distance in inches as follows: 1.245 f t 3 x 1 x 1 x 1 x 1 = 1.245 ft 3. 1.245 ft 3 x 1728 in 3 /ft 3 x 16.39 cm 3 /in 3 x 1 ml/cm 3 x 1 L/l000 ml = 35.26 L.

3 September 2007 MAR 110 Lab1: Exercise 1 - Conversions 6

3 September 2007 MAR 110 Lab1: Exercise 1 - Conversions 7

3 September 2007 MAR 110 Lab1: Exercise 1 - Conversions 8 EXERCISE 1. CONVERSION OF UNITS Convert each of the following quantities into those with the units that are requested. SHOW YOUR WORK! a. Earth's circumference, 24,900 mi km m b. Equatorial diameter, 12,756 km mi mi. c. Ocean depth of 36,198 ft m km. d. Highest point on Earth, 8847 m km ft

3 September 2007 MAR 110 Lab1: Exercise 1 - Conversions 9 e.wind speed of 30 mi/h m/hr km/hr f. Density of 60 lbs/ft 3 kg/m 3 g/cm 3 g. Speed of Earth's equatorial rotation, 460 m/sec mi/hr km/hr h.discharge of the Mississippi River, 61,000 ft 3 /sec m 3 /sec L/sec

3 September 2007 MAR 110 Lab1: Exercise 1 - Conversions 10 i. An area of 2500mi 2 km 2 m 2 j. Mean density of the Earth 5.522 g/cm 3 lbs/ft 3 kg/m 3 k. A 10 L container Gal in 3 l. A 55 gallon drum of oil ft 3 liters

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