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Math Review Lecture 2

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Title: Math Review Lecture 2


1
Math ReviewLecture 2
  • Evans School of Public Affairs
  • University of Washington

2
Lecture 2 Algebra Basics
  • Algebra Basics
  • Terminology
  • A term is a numerical constant or the product (or
    quotient) of a numerical constant and one or more
    variables. Examples of terms are 2x and 3xy
  • An algebraic expression is a combination of one
    or more terms. Terms in an expression are
    separated by either or signs.

Slide 2/38
3
Lecture 2 Algebra Basics
  • In the term 3xy, the numerical constant 3 is
    called a coefficient. In a simple term such as z,
    1 is the coefficient. A number without any
    variables is called a constant term. An
    expression with one term, such as 3xy, is called
    a monomial one with two terms, such as 4a 2d,
    is a binomial one with three terms, such as xy
    z a, is a trinomial. The general name for
    expressions with more than one term is
    polynomial.

Slide 3/38
4
Lecture 2 Algebra Basics
  • Operations with Polynomials
  • All of the laws of arithmetic operations, such as
    the associative, distributive, and commutative
    laws, are also applicable to polynomials.
  • All of the laws of arithmetic operations, such as
    the associative, distributive, and commutative
    laws, are also applicable to polynomials.
  • Commutative law a b b a
  • Associative law (x y) z x (y z)
  • Distributive law 2 (a 5) 2a 2(5) 2a 10

Slide 4/38
5
Lecture 2 Algebra Basics
  • Translating English Into Algebra In some word
    problems, especially those involving variables,
    the best approach is to translate directly from
    an English sentence into an algebraic sentence,
    i.e., into an equation. The table below lists
    some common English words and phrases, and the
    corresponding algebraic symbols.

Slide 5/38
6
Lecture 2 Algebra Basics
Example Steve is now five times as old as Craig
was 5 years ago. If the sum of Craigs and
Steves ages is 35, in how many years will Steve
be twice as old as Craig?
Slide 6/38
7
Lecture 2 Orders of Operation
  • Order of Operations
  • PEMDAS Please Excuse My Dear Aunt Sally.
    Parentheses, exponents, multiplication, division,
    addition, subtraction.
  • Start with the innermost set of parentheses and
    work outwards.
  • Absolute value indicators are treated as
    parentheses.
  • Multiplication division are interchangeable
  • Addition subtraction are interchangeable

Slide 7/38
8
Lecture 2 Equations
  • Equations
  • Equations An equation is an algebraic sentence
    that says that two expressions are equal to each
    other. The two expressions consist of numbers,
    variables, and arithmetic operations to be
    performed on these numbers and variables.  

9
Lecture 2 Equations
  • A linear or first-degree equation is an equation
    in which all the variables are raised to the
    first power. (There are no squares or cubes.)
  • n 6 10
  • A quadratic or second-degree equation contains a
    squared term and no greater power. The equation
    can be written as
  • ax2 bx c 0
  • where a is not equal to zero.

10
Lecture 2 Variation
  • Variation
  • Direct Variation One variable increases when the
    other increases, and decreases when the other
    decreases. For instance, the amount of paint
    needed to paint a wall varies directly with the
    area of the wall. When two quantities x and y
    vary directly, their relationship can be
    expressed by the equation y kx, where k is a
    constant.

11
Lecture 2 Variation
  • Inverse Variation In inverse variation, one
    variable decreases when the other increases, and
    increases when the other decreases. When two
    quantities x and y vary inversely, their
    relationship can be expressed by xy k, or y
    k/x. One inverse relationship is rate time
    distance. To cover a constant distance in less
    time (decreasing time), you must go faster
    (increasing rate).

12
Lecture 2 Functions
  • Functions
  • Definition of a function A function is a rule
    that assigns each element in the domain to one
    and only one element in the range.
  • The domain is the set of all possible numbers
    that can be used as an input. This is also called
    the explanatory or independent variable.
  • The range is the set of all possible values that
    are the output. This is also known as the
    response variable or dependent variable.

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13
Lecture 2 Functions
  • Functional Notation y f(x) mx b
  • The domain is x and the range is f(x)
  • For public policy applications, we must consider
    the practical as well as mathematical meaning.
    For example, it might not make sense to have a
    negative quantity of books or a negative price.

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14
Lecture 2 Correlation vs. Causation
  • Correlation Variables vary together, either
    directly or inversely.
  • Examples
  • A persons height and weight
  • Extent of fire damage and number of firefighters
  • Causation an event B always occurs when A occurs
    (deterministic) the occurrence of A increases
    the probability of B (probabilistic)
  • Examples
  • Rain and a wet roof
  • Air pollution and respiratory illness

Slide 14/38
15
Lecture 2 Solving Equations
  • Solving Equations
  • The goal is to isolate the variable youre
    solving for on one side.
  • What you do to one side, e.g. subtracting x, you
    must always do to the other side.
  • Add terms together, but only if they have the
    same exponent. This process is known as
    collecting like terms.
  • Follow the order of operations.

16
Lecture 2 Solving Equations
  • Adding and Subtracting Monomials To combine
    terms with the same variable and exponent, keep
    the variable part unchanged while adding or
    subtracting the coefficients.
  • Examples
  • 2a 3a
  • 10x 2x
  • Adding and Subtracting Polynomials Again,
    combine like terms, where the exponent is equal.
  • Example
  • (3x2 5x 7) x2

17
Lecture 2 Solving Equations
  • Remove parenthesis by distributing the
    coefficient, as in 3(2y 4) 6y 12
  • Divide both sides by the coefficient to get the
    variable by itself.
  • Eliminate fractions by multiplying both sides by
    the lowest common denominator. Or, if two
    fractions are equal to each other, cross
    multiply. This is a shortcut in which you simply
    go from to  

18
Lecture 2 Solving Equations
  • Example of an equation with fractional
    coefficients
  • Solve by multiplying both sides by the LCD, which
    is 30. Then distribute and rearrange.
  •  

19
Lecture 2 Solving Equations
  • Substitute known quantities in an expression
  • Example If x2, replace x with 2 wherever x
    appears
  • 3x2 4x 3(2)2 4(2) 3 4 4 2 12
    8 4
  • Example Suppose a persons salary (S) is
    influenced both by her years of education (E) and
    her
  • parents income(I)
  •  
  •  
  • Jason has a high school diploma his parents
    average
  • salary was 80,000. Rachel has an MPA her
    parents
  • earned 55,000. Who has the greater earning
    potential?

20
Lecture 2 Solving Equations
  • Multiplying Monomials Multiply the coefficients
    and variables separately.
  • Example (2a)(3a) 6a2
  • Multiplying Binomials Use FOIL (first, outside,
    inside, last) to distribute each term.
  • Example 1 (x3)(x4) x2 4x 3x 12
  • x2 7x 12
  • Example 2 Calculate (2a5)(4a10)

21
Lecture 2 Solving Equations
  • Multiplying Other Polynomials FOIL works only
    when you multiply two binomials. If you want to
    multiply polynomials with more than two terms,
    make sure you multiply each term in the first
    polynomial by each term in the second.
  • Example (x2 3x 4)(x 5)
  • x2(x 5) 3x(x 5) 4(x 5)
  • x3 5x2 3x2 15x 4x 20
  • x3 8x2 19x 20
  • The number of terms, before simplifying, equals
    the product of the number of terms in the
    polynomials.

22
Lecture 2 Solving Equations
  • Factoring Common Divisors A factor common to all
    terms of a polynomial can be factored out.
  • Example All three terms in the polynomial
  • 3x3 12x2 6x contain a factor of 3x. Pulling
    out the common factor yields 3x(x2 4x
    2)

23
Lecture 2 Solving Equations
  • A rational equation contains a fraction in which
    the numerator and denominator are both
    polynomials.
  • Although they look complicated, they work just
    like simpler equations. Start by
    cross-multiplying, then simplify and solve.
  • Example provided that x doesnt equal 2 or 4

24
Lecture 2 Inequalities
  • Inequalities
  • Inequality symbols
  • greater than
  • greater than or equal to
  • less than or equal to
  • Examples 5 2 and 12

25
Lecture 2 Solving Inequalities
  • Solving Inequalities
  • Use the same methods used in solving equations
    with one exception
  • Multiplying or dividing by a negative number
    reverses the direction of the inequality.
  • Example 1 If the inequality 3x multiplied by 1, the resulting inequality is 3x
    2.
  • Example 2 Solve for x in

26
Lecture 2 The Coordinate Plane
  • The Cartesian Coordinate Plane
  • Ordered pairs of real numbers can be represented
    as points on a plane, in the same way as real
    numbers on a number line.
  • The coordinate plane has two axesa horizontal
    x-axis and a vertical y-axisintersecting at the
    origin.
  • Any point can be identified by an ordered pair
    containing the x-coordinate and the y-coordinate,
    (x, y), where x is the number of horizontal units
    the point is from the origin.

27
Lecture 2 The Coordinate Plane
  • The coordinates of the origin are (0,0). Starting
    at the origin to the right is positive, to the
    left is negative up is positive and down is
    negative. Examples (2,3), (-4,5).

28
Lecture 2 The Coordinate Plane
  • Quadrants and Plotting Points The Cartesian
    plane has 4 quadrants by the y-axis and x-axis.
    You can always tell which quadrant a point is in
    by its sign. Points with zeroes in them lie on
    the lines.
  • Quadrant I (x, y)
  • Quadrant II (-x, y)
  • Quadrant III (-x, -y)
  • Quadrant IV (x, -y)
  • Example (-72, 5) is in Quadrant II.
  • Which quadrants contain these points?
  • (-1,-1/16), -(?,-?), (-9,2)

29
Lecture 2 Graphing Lines
  • Graphing Lines
  • Any equation in two variables can be graphed if
    it has a solution. The graph of the line
    represents all the possible solutions.
  • The equation y mx b can be graphed as a
    straight line. The form is known as
    slope-intercept form, where m is the slope and b
    is the y-intercept (the value of y where the line
    crosses the y axis and where x0).
  • The equation y-y0 m(x-x0) is in point-slope
    form, and (x0, y0) is a point on the line.

30
Lecture 2 Graphing Lines
  • A line has positive slope if x and y increase
    together, and negative slope if one goes up when
    the other declines.
  • The slope m measures the change in the vertical
    direction for a given horizontal distance.

31
Lecture 2 Graphing Equations
  • Ways to Graph
  • Slope-intercept plot the y-intercept at (0,b).
    Use the slope to count the rise and run to
    another point. Connect the points with a straight
    line. Label the line.
  • Point-slope plot the point (x0, y0) given in the
    equation. Use the slope to plot another point.
    Connect the points and label the equation of the
    line.
  • Plug and Chug plug in sensible values for x in
    order to calculate corresponding values of y.
    Its often helpful to start with x0. Plot two or
    three calculated points and connect them.

32
Lecture 2 Graph Examples
  • Graph y2x1
  • Graph

33
Lecture 2 Graphing in Economics
  • Graphs in mathematics usually have the response
    variable on the vertical axis.
  • Graphs in economics have the response variable
    (quantity) on the horizontal axis.
  • A supply equation QS 4 2P
  • A demand equation QD 6 - 2P

Slide 33/38
34
Lecture 2 Simultaneous Equations
  • Simultaneous Equations
  • Simultaneous equations, also called a system of
    equations, is a set of two or more equations
    containing two or more variables.
  • A system of equations can be solved only if there
    are at least as many equations as there are
    variables, and one equation isnt a multiple of
    the other. Some systems have no solutions, and
    others have infinitely many solutions.

35
Lecture 2 Simultaneous Equations
  • The goal of solving simultaneous equations is to
    find a pair or n-tuple (generic phrase for a
    vector of n values) that satisfies all of the
    equations.
  • An example of a system of equations is
  • which is solved by x10 and y4, or (10,4).

36
Lecture 2 Simultaneous Equations
  • Substitution If you are given two different
    equations with two variables, you can isolate the
    variable in one equation, then plug that
    expression into the other equation.
  • Example Find the values of m and n in
  • m 4n 12
  • 3m 2n 16
  • Substitute the first equation into the second
    equation, wherever m appears. Solve for n and
    then plug that value in to find the value of m.

37
Lecture 2 Simultaneous Equations
  • Combination Another way to solve a system of
    equations is to combine the equations in such a
    way that one of the variables cancels out.
  • Example 4x3y8 and xy3.
  • Alter one equation so that the coefficients of
    one variable are the inverse of the coefficients
    of the same variable in the second equation, and
    then add the equations together, leaving one
    variable.
  • -4(xy)-4(3) gives -4x-4y-12
  • 4x3y8 -4x-4y-12 -y-4
  • So y4 and x-1.

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38
Lecture 2 One Equation with Many Unknowns
  • If a single equation involves more than one
    variable, you cannot usually find a specific
    value for a variable you can only solve for one
    variable in terms of the others. To do this, try
    to get the desired variable alone on one side and
    all the other variables on the other side.
  • Example Solve for N in the formula V
    (PN)/(RNT)
  • Clear denominators by cross multiplying
  • Remove parenthesis by distributing
  • Move terms containing N to one side and all other
    terms on the other side
  • Factor out the common factor N
  • Divide by the coefficient of N to get N alone
  • Note reduce the number of negative signs by
    multiplying the numerator and denominator by 1.
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