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Integ. Science
Assignments
Take Notes &Define Key Terms on 2 – 26
Read/Use Appendix B
p. A8
Metric Homework part 1
Metric Homework part 2
Location Due Date
Textbook/ Notebook
Textbook/ Notebook
Worksheet Tuesday
Today
Worksheet Wednesday
Worksheet
Tuesday
Precision and Accuracy
Precision indicates degree of reproducibility of a measured number. Accuracy indicates how close your measurements are to the true value.
Precision and Accuracy
When making measurements in science you want them to be both precise and accurate.
SI Base and Derived Units Physical Quantity Base Unit Symbol
length meter m
area square meter m2
mass kilogram kg
volume liter l
density gram/liter g/l
temperature degrees Celsius °C
thermodynamic temperature kelvin K
time second s
electric current ampere A
amount of substance mole mol
luminous intensity candela Cd
Metric SystemDesigned during the French Revolution of the 1790's, the metric system brought order out of the conflicting and confusing traditional systems of weights and measures then being used in Europe. Prior to the introduction of the metric system, it was common for units of length, land area, and weight to vary, not just from one country to another but from one region to another within the same country.
Metric System• The metric system replaces all the traditional units, except the units
of time and of angle measure, with units satisfying three conditions:
• (1) One fundamental unit is defined for each quantity. These units are now defined precisely in the International System of Units.
• (2) Multiples and fractions of these fundamental units are created by adding prefixes to the names of the defined units.
• (3) The fundamental units are defined rationally and are related to each other in a rational fashion.
• The metric units were defined in an elegant way unlike any traditional units of measure. The Earth itself was selected as the measuring stick. The meter was defined to be one ten-millionth of the distance from the Equator to the North Pole
Metric System
Prefixesgiga – G 1,000,000,000 = 1*10 9
mega – M 1,000,000 = 1*10 6
kilo – k 1,000 = 1*10 3
hecto – h 100 = 1*10 2
deka – da 10 = 1*10 1
Base Unit – (meter, gram, liter, second) = 1*10 0
deci – d 0.1 = 1*10 -1
centi – c 0.01 = 1*10 -2
milli – m 0.001 = 1*10 -3
micro - µ 0.000 001 = 1*10 -6
nano – n 0.000 000 001 = 1*10 -9
Metric SystemUnderstanding prefixes
Prefixes are short names and letter symbols for numbers (powers of ten). A prefix is attached to the front of a unit, without a space. Prefixes are easier to write and say than powers of ten, ordinary notation, or traditional number names. Compare:
25 MW(pronounced and spelled out: 25 megawatts) 25 X106 (the 106 is a power of ten)25 000 000 W (ordinary notation)25 million watts (traditional number name)
Metric SystemAs you go up the "ladder" of these prefixes, the unit is multiplied in steps of 1000, or 103.
km = 1000 X m [kilometer]Mm = 1000 X km [megameter]Gm = 1000 X Mm [gigameter]
Going down the prefix scale, a unit is divided in steps of 1000. In other words, it is multiplied in steps of 0.001 (= 1/1000).
mm = 0.001 X m [millimeter]µm = 0.001 X mm [micrometer]nm = 0.001 X µm [nanometer]
Metric SystemChanging prefixes by moving the decimal point
Choose a prefix that will simplify an expression by eliminating unnecessary placeholding zeros (non-significant digits). To switch to the next larger prefix, move the decimal point three places to the left.– 4 000 m = 4 km – 1 500 mg = 1.5 g – 500 mL = 0.5 L – 76 000 kg = 76 Mg – 2 300 µs = 2.3 ms
To switch to the next smaller prefix, move the decimal point three places to the right.– 0.005 m = 5 mm – 0.009 kg = 9 g – 0.003 2 mm = 3.2 µm
When moving the decimal point to the right, you may have to add one or two place holding zeros at the end of the number to show where the (unexpressed) decimal point goes.– 0.03 g = 30 mg – 0.2 L = 200 mL
1) 120 mm = _______________cm
2) 48.6 g = _______________ cg
3) 84,000 cm = _______________ Mm
4) 19.7 mm = _______________m
5) 23.89 km = _______________cm
6) .098 mg = _______________kg
7) 29.9 Ms = _______________µs
Practice Problems
Practice Problems1. 421 m = _______________cm
2. 486 cg = _______________ Mg
3. 17,000 km = _______________ Mm
4. 17 mm = _______________dam
5. 23 km = _______________cm
6. 225,081 mg = _______________kg
7. 53 Ms = _______________µs
Imperial Metric
1 inch [in] 2.54 cm
1 foot [ft] 12 in 0.3048 m
1 yard [yd] 3 ft 0.9144 m
1 mile 1760 yd 1.6093 km
1 nautical mile 2025.4 yd 1.852 km
Linear Measure
Linear Measure Practice• Inches to Centimeters and cm to in
34.3 in = ??? cm 94 cm = ??? in
• Feet to Meters and m to ft
8 ft = ??? m 323 m = ??? ft
• Yards to Meters and m to yd
100 yd = ??? m 7.24 m = ??? yd
• Miles to Kilometers and km to mi.
51.8 mi = ??? km 5 km = ??? mi
Imperial Metric
1 in3 Cubic Inches 16.387 cm3
1 ft3 Cubic Feet 1,728 in3 0.0283 m3
1 fl oz Fluid Ounces 23.625 ml
1 pt Pint 20 fl oz 0.4725 l
1 gal 8 pt 3.780 l
Volume Measure
Volume Practice
• Cubic inches to cubic centimeters15 in3 = ??? cm3 31.7 cm3 = ??? in3
• Cubic feet to cubic meters 3 ft3 = ??? m3 894 m3 = ??? ft3
• Ounces to milliliters 89 oz = ??? ml 89 ml = ??? oz
• Gallons to liters 4 gal = ??? L 63 L = ??? gal
Imperial Metric
1 ounce [oz] 437.5 grain 28.35 g
1 pound [lb] 16 oz 0.4536 kg
1 stone 14 lb 6.3503 kg
1 hundredweight [cwt] 112 lb 50.802 kg
1 long ton (UK) 20 cwt 1.016 t
1 short ton (US) 2,000 lb 0.907 t
Mass Measure
Mass
• Measure of the amount of matter that makes up an object.
• Units used to designate mass are kilograms (kg)
• You can measure an objects mass using a balance (triple beam, electronic, spring).
Volume
• Volume is a measurement of the three-dimensional space occupied by an object.
• Units include cm3 and mL.
• Solids, liquids, and gases all have volume, but you measure each differently.– Solid – calculate geometrically or displacement– Liquid – measure using a graduated cylinder
Density
• The amount of matter in a given space.– Does this sound familiar?
• Concentration or Compactness
• The unit for density is or .
Mass, Volume, and Density• Mass volume and density are directly related.
Practice Exercise:1. Measure the mass and volume of an object in the
room.2. Calculate the Density of the Object.3. What are the units associated with this
calculation?
Practice Problems1. Calculate the volume of an object that is 34
cm by 25 cm by 8 cm.
2. Given: V = 50 mL D = .75 g/mLCalculate:Mass
3. Given: M = 55 g D = 2.3 g/cm3
Calculate: Volume
4. Given: M = .13 kg V = 20 mLCalculate:Density
Significant Figures
• It is important to record the precision of your measurements so that other people can understand and interpret your results.
• A common convention used in science to indicate precision is known as significant figures.
• Significant figures are those digits in a measurement that are known with certainty plus the first digit that is uncertain.
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.
Rules for Sig Fig
Rule 1
Zeros between other nonzero digits are significant.
Examples
a. 50.3 m has three significant figuresb. 3.0025 s has five significant figures
Rules for Sig Fig
Rule 2
Zeros in front of nonzero digits are not significant.
Examples
a. 0.892 has three significant figuresb. 0.0008 s has one significant figure
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
a. 57.00 g has four significant figuresb. 2.000 000 kg has seven significant figure
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
a. 100 m has ONE significant figureb. 20 m has ONE significant figure