NAME______
Review of Some Mathematical Concepts for Space Science
College of Staten Island - CUNY
Objective: Space Science (including Astronomy and Astrophysics) is a measurement science. In order to draw conclusions about measurements we usually organize them in tables or graphs or formulas. These give rise to the discovery of basic natural principles or laws with enormous predictive power (which gives science an edge over other human endeavors in interpreting existence).
In the laboratory part of the course you will carry out from time to time various measurements and will be asked to draw conclusions. In the course you will be asked to solve problems for homework of an analytic nature. To help you do these activities you will need to understand the following concepts and/or techniques of analytical thinking.
Your work will be judged on quality which usually mean time commitment. Your mathematical skills are only improved with practice. . this exercise is a review of mathematical concepts you will use, master these and you will not find this course difficult. Whatever is not finished in the laboratory session should be finished at home and this entire exercise handed in next laboratory period.
I. Metric measurement.
Study the Metric Ruler as you do this exercise.
The measure of length is now universally based on the meter.
Examine a meter stick and note that 1 meter = 100 centimeters and further
note that 1 cm. = 10 millimeter.
Measurements are expressed in decimal fashion,
for example: 1.57 meters, 12.55 cm. 345.5 mm 3 kilometers
TASK 1. How many millimeters in one meter. ______
TASK 2. 25.5 cm = ? mm ______
TASK 3. 1.579 meters = ? cm = ? mm ______
The metric system was developed around 1775 by French scientists. It is convenient to use because its units are related by powers of ten. A standardized system now exists worldwide. It is referred to as the International System (SI) of weights and measures.
Traditionally in the study of physics, hence astrophysics, two systems of measure have been used. They are referred to as the MKS and the CGS systems.
MKS system meter - kilogram - second energy is joule temperature is Kelvin
CGS system centimeter - gram - second energy is erg temperature is Kelvin
Many textbooks emphasize the MKS system but ours uses mostly the CGS system
The CGS Metric System: some basic fundamental units of measure are displayed.
Length: base unit = centimeter (cm)
Mass: base unit = gram (g)
Time: base unit = second (s)
Energy: base unit=erg
Temperature: base unit=Kelvin (K)
Derived units from the fundamental
Speed (v)= cm/sec
Acceleration (a) = cm/sec2
Volume(V): = liter (derived unit = 1000 ml or =1000 cm^3(cubic centimeter sometimes called a “cc”)
Force: =dynes from F=ma 1 dyne= 1 g x 1cm/sec2
LOOK OVER APPENDIX C UNITS AND CONVERSION TO SEE OTHER UNITS WE USE IN OUR COURSE…
TASK 3b NAME SEVERAL ENERGY UNITS NOT MENTIONED ABOVE?
LOOK OVER APPENDIX B Physical and astronomical constants to see how some of the units are used
TASK 3c write down here three constants, all with different units…
Note sometimes I used ^ for exponent!
Units of measure are divided into two categories called the Fundamental unit and the Derived Unit.
Fundamental Unit: These are units of measure obtained directly from measurement observations using SI units and cannot be obtained indirectly from any simpler or more basic units of measure. Mass, length, and time are examples of fundamental units.
Derived Unit: These are units of measure which may be able to be observed through direct measurement (i.e. volume can be observed directly by visibly observing the reading off of the side of a graduate cylinder.), but also can be obtained by derivation using simpler fundamental units of measure. As an example consider that volume can be obtained from length by the formula V = L x W x H.
Example: Length of course is a length measurement (L), but so are width (W) and height (H) length measurements simply oriented in different directions. And it follows then that volume, which is a multiplication product of the three, is derived from length.
Metric Prefixes - Units of Measure base units may be inappropriate for a given measurement or calculations so we use multipliers of the base units with prefix names, as follows
Prefix Symbol Fractional Equivalent Example (using the meter)
Kilo K 1000 x base unit kilometer (Km)
hecto h 100 x base unit hectometer (hm)
deka da 10 x base unit dekameter (dam)
______1 x base unit meter (m)
deci d 1/10 x base unit decimeter (dm)
centi c 1/100 x base unit centimeter (cm)
milli m 1/1000 x base unit millimeter (mm)
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Additional Units:
Prefix (Symbol) Fractional Equivalent Example (using the meter)
giga (G) 1 x 10^9 x base unit gigameter (Gm)
mega (M) 1 x 10^6 x base unit megameter (Mm)
micro (m) 1/1 x 10^-6 x base unit micrometer (mm ) greek letter is called mu
nano (n) 1/1 x 10^-9 x base unit nanometer (nm) ..we use this a lot!
pico (p) 1/1 x 10^-12 x base unit picometer (pm)
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Common Metric - English Equivalents:
1 m = 39.37 in 1 cm = 0.394 in 1 in = 2.54 cm
1 kg = 2.21 lb 1 lb = 454 g 1 L = 1.057 qt
1 oz = 28.4 g 1 in^3 = 16.5 cm^3 1 gal = 3.78 L
Metric Conversion -
Conversions between metric units:you started this exercise by doing just that!
The metric system is very easily manipulated as can be seen by the following two examples. Converting between two units of the same category of measurement can be done simply by moving the position of the decimal place at the same time the prefix is changed. As the unit of measure is increased the decimal is moved to the left making the numerical value smaller proportionally. As the unit of measure is decreased the decimal is moved to the right making the numerical value larger proportionally. Look at the following two examples of this concept.
Example 1: Consider the measurement 2.5 m and the variations of the same length measurement expressed in other metric units of length.
km hm damm dm cm mm
0.0025 0.025 0.25 2.5 25.0 250. 2,500.
Can you see all these ….study this!
Example 2: Consider the measurement 4,200 m and the variations of the same length measurement expressed in other metric units of length.
km hm damm dm cm mm
4.2 42. 420. 4,200. 42,000. 420,000. 4,200,000.
TASK 4 Convert each of the example values to nm
1______2 ______
Working with multiple dimensional conversions.
Student who study doing conversions between units within a measurement system such as Metric to Metric or between measuring systems such as the Metric to English and English to Metric conversions usually can handle conversion factors that are one dimensional. However, a problem often arises when conversion factors are needed for two and three dimensional problems. The following information compares handling units in one, two, and three dimensions where conversions are involved.
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1. One Dimensional conversion.
Given a length of 100 inches, convert this to centimeters.
The one dimensionsl (linear) conversion factor is 1 in = 2.54 cm.
The calculation involves 100 in x 2.54 cm / in = 254 cm.
------You did some of this at the start!
2. Two Dimensional conversion.
Given a surface area of 500 square inches (500 in^2), convert this to square centimeters.
The two dimensional (Area) conversion factor is (1 in)^2 = (2.54 cm)^2 or 1 in^2 = 6.4516 cm^2
The calculation involves 500 in^2 x 6.4516 cm^2 / in^2 = 3,225.8 cm^2
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3. Three Dimensional conversion.
Given a volume of 1200 cubic inches (1200 in^3), convert this to cubic centimeters.
The three dimesnional (Volume) conversion factor is (1 in)^3 = (2.54 cm)^3 or 1 in^3 = 16.387064 cm^3
The calculation involves 1200 in^3 x 16.387064 cm^2 / in^3 = 19,664.4768 cm^3
Dimensional Analysis, also called Factor Labeling.
Dimensional analysis focuses on the units of measurement, which is an area of mathematics that many students overlook. Dimensional analysis focuses on the use of measurements in calculations. Below are some examples of using units in calculations. By doing this when working out a formula one can avoid calculations errors since the final dimension must be what one is looking for..
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1. Calculating the surface area of a shelf board.
Given a 24 inch by 48 inch shelf board calculate the amount of surface area available to store objects on.
Equation to be used: Area = length x width
Substitution: Area = 48 inches x 24 inches
Answer: Area = 1,152 square inches or 1,152 in^2
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2. Converting the surface area determined in the above problem into square feet.
The shelf board above has a surface area of 1,152 in^2
There are two ways to go about this. One is to convert the original dimensions to feet and then substitute into the equation and solve. The other way is to solve for the answer by doing a conversion calculation.
The 1st way: The length is 48 in x 1 ft / 12 in = 4 ft
The width is 24 in x 1 ft / 12 in = 2 ft
Calculation of Area: A = L x w = 4 ft x 2 ft = 8 square feet or 8 ft^2
The 2nd way: The area is 1,152 in^2
The conversion factor between the inch and the foot is 12 in = 1 ft
The conversion factor between the square inch and the square foot involves squaring both sides of the above conversion factor. This gives us:
Conversion factor in^2 --> to ft^2 is (12 in)^2 = (1 ft)^2
Using this conversion factor: 1,152 in^2 x (1 ft^2 / 144 in^2)
Answer: 8 ft^2
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3. The same approach is used in volume problems.
Calculate the volume of a box having the following dimensions.
48 inches long, 24 inches wide, 36 inches deep (or high)
Equation to be used: Volume = length x width x depth (or height)
Substitution: Volume = 48 in x 24 in x 36 in
Answer: Volume = 41,472 in^3
4. Determining the volume in cubic feet would involve the following process.
Again we could approach this in two different ways.
The 1st way: The length is 48 in x 1 ft / 12 in = 4 ft
The width is 24 in x 1 ft / 12 in = 2 ft
The depth is 36 in x 1 ft / 12 in = 3 ft (also height)
Calculation of Volume: V = L x W x H = 4 ft x 2 ft x 3 ft = 24 cubic feet or 24 ft^3
The 2nd way: The area is 41,472 in^3
The conversion factor between the inch and the foot is 12 in = 1 ft
The conversion factor between the cubic inch and the cubic foot involves cubing both sides of the above conversion factor. This gives us:
Conversion factor in^3 --> to ft^3 is (12 in)^3 = (1 ft)^3
Using this conversion factor: 41,472 in^2 x (1 ft^2 / 1,728 in^2)
Answer: 24 ft^3
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5. Determining the Density of a substance.
The mass of a rectangular solid piece of metal is 100 g
Its dimensions are: Length is 5 cm, Width is 4 cm, and thickness (height) is 2 cm.
Equation used: Density = Mass / Volume
Volume is: V = L x W x H = 5 cm x 4 cm x 2 cm = 40 cm^3
Substitution: D = M / V = 100 g / 40 cm^3 = 2.5 g/cm^3
Note: Density is a derived unit with a complex unit of measure.
Angles and Protractor.
An angle is a measure of the space between the intersection of two lines. It has come down to us from ancient times that a circle can be divided into 360 parts each of which subtends an angle of 1 degree at the center. Recall the class discussion the 360 was the number of days for the Sun to go completely around the Zodiac or the length of a Year as measured in ancient times.. now we know it is ~ 365.25 days
The protractor is used to measure the angle. It usually is half a circle and, hence, contains 180 degrees marked in various convenient fashions. You must center the intersection point of the lines you are measuring or constructing at the center point (instructor will demonstrate) of the protractor and also match one of the lines to the base line of the protractor.
IF A LINE IS NOT LONG ENOUGH TO REACH THE ANGLE SCALE ON THE PROTRACTOR IT IS CUSTOMARY TO CAREFULLY ENLARGE THE LINE WITH THE STRAIGHT EDGE OF THE PROTRACTOR.
TASK 5. With one arm outstretched and pointing to the horizon and the other to the point over your head, (Do not be bashful of course you look silly)
approximately what angle are you constructing on the sky = ______.
TASK 6. The Zodiac Constellations lie along the path of the sun which may be thought of as a great circle all around us. If there are twelve constellations all evenly spaced, then what angle describes their "size" on the sky =______.
TASK 7. Define another unit of angle known as the “Radian” what is the relationship to degrees!
Use the space below.
TASK 8 Draw a these angles carefully with your protractor 38, 112, 195 on a sheet of paper or on the back of this exercise.
Right angle triangle Trigonometry: these functions are extremely useful in all fields of science
Tangent
The three Trigonometry functions of Sine, Cosine, and Tangent are very important. All three functions are defined as ratios of lengths of sides in a right triangle (a triangle with one angle being 90 degrees such that two of the sides of the triangle meet as lines perpendicular to each other). In such a situation the some of the other two of the three angles present in the right triangle add up to 90 degrees and are called complementary angles.