MHF4U – Power Functions & Polynomials Notes (Advanced Functions)
Review
- Function - every x-value produces exactly one y-value
- x-value gives two different y values ≠ function
- Use vertical line test, a vertical line cannot touch
more than one point on the graph
- Some equations may look algebraic but
still fail the vertical line test when graphed
- All polynomials are functions, but not all
functions are polynomials
Example
red x = (y - 3)2 + 3 [not a function]
blue x = 15
- Domain - all possible x-values (independent variable) gives output of real y-values
- Range - all possible y-values (dependent variable) derived from the x-values
Example
a) y = 2x + 4 where R is real numbers
Domain {X∊R} or (-∞ to + ∞)
Range {Y∊R} or (-∞ to + ∞)
- No restriction for domain/range
b) f(x)= (x - 3)2
Domain {X∊R} → (-∞ to + ∞)
Range {Y∊R | y ≥ 0} → [0,∞)
- No restriction for domain, restriction for range
-Asymptote - a line that a curve gets closer and closer to but never touches
- Know there’s an asymptote if the denominator of the function is a higher
degree than the numerator
Example
1
f(x) = 𝑥−3
- Vertical asymptote - vertical line (imagine a wall)
- Here, x can never = 3 otherwise be dividing by 0
(undefined)
- Horizontal asymptote - the horizontal line (imagine a floor)
- For this case it reaches close to y = 0 but it never
truly touches it
- The bigger the x-value, the larger the denominator,
the closer to 0, but it will never be 0
, MHF4U – Power Functions & Polynomials Notes (Advanced Functions)
Interval Notation
- Sets of real numbers may be described in a variety of ways
1) As an inequality -3 < x ≤ 5
2) Interval (or bracket) notation (-3, 5]
3) Graphically on a numberline
- Infinite = ∞ (infinity) or -∞ (negative infinity) → always use a round bracket (cannot
reach these values)
- Square bracket → end value is included; Round bracket → end value not included
Polynomial Functions
- Power function - simplest type of polynomial function
- f(x) = axn a → coefficients (a0, a1… an; real numbers)
n → degree of function, (non-negative integer, whole number)
x → variable
- Only one term, no other term added
- Example: y = -2x4
- General form: f(x) = anxn + an-1xn-1 + an-2xn-2 + … + a2x2 + a1x1 + a0
- Example: y = 2x3 + 5x2 + 3
- Degree of a polynomial - the highest exponent on a variable in an expression
- This determines the order how the function is written
- Not determined by the leading coefficient
- Written in descending order of power (in terms of degrees)
- Example: f(x) = x6 + 2x2 + x + 4 has a degree of 6
- Leading coefficient (anxn); constant (a0)
- Domain is set of real numbers → {X∊R} or (-∞ - to ∞)
- Real numbers - all numbers that can be placed on a number line
- Range may be all real numbers, but may have an upper/lower bound (not both)
- Can have a restriction
- No horizontal or vertical asymptotes
- Polynomial functions with degree 0 are just horizontal lines (i.e. x = 5)
- Shapes of graphs depends on degree of function (generally 5 shapes)
- Even degrees → U-shaped, ends go same direction
- Odd degrees → S-shaped, ends go opposite directions
Linear; n = 1 Quadratic; n = 2 Cubic; n = 3 Quartic; n = 4 Quintic; n = 5
- Straight line - U-shaped - S-shaped curve - Wider U-shaped - S-shaped curve,
- Always parabola - Always parabola like cubic but
increasing/ - Vertex increasing/ - ‘Flatter’ near steeper near origin
decreasing, no - Symmetrical decreasing vertex - Can increase/
curves about y-axis through turn - Symmetrical decrease through
points about y-axis turn points
Review
- Function - every x-value produces exactly one y-value
- x-value gives two different y values ≠ function
- Use vertical line test, a vertical line cannot touch
more than one point on the graph
- Some equations may look algebraic but
still fail the vertical line test when graphed
- All polynomials are functions, but not all
functions are polynomials
Example
red x = (y - 3)2 + 3 [not a function]
blue x = 15
- Domain - all possible x-values (independent variable) gives output of real y-values
- Range - all possible y-values (dependent variable) derived from the x-values
Example
a) y = 2x + 4 where R is real numbers
Domain {X∊R} or (-∞ to + ∞)
Range {Y∊R} or (-∞ to + ∞)
- No restriction for domain/range
b) f(x)= (x - 3)2
Domain {X∊R} → (-∞ to + ∞)
Range {Y∊R | y ≥ 0} → [0,∞)
- No restriction for domain, restriction for range
-Asymptote - a line that a curve gets closer and closer to but never touches
- Know there’s an asymptote if the denominator of the function is a higher
degree than the numerator
Example
1
f(x) = 𝑥−3
- Vertical asymptote - vertical line (imagine a wall)
- Here, x can never = 3 otherwise be dividing by 0
(undefined)
- Horizontal asymptote - the horizontal line (imagine a floor)
- For this case it reaches close to y = 0 but it never
truly touches it
- The bigger the x-value, the larger the denominator,
the closer to 0, but it will never be 0
, MHF4U – Power Functions & Polynomials Notes (Advanced Functions)
Interval Notation
- Sets of real numbers may be described in a variety of ways
1) As an inequality -3 < x ≤ 5
2) Interval (or bracket) notation (-3, 5]
3) Graphically on a numberline
- Infinite = ∞ (infinity) or -∞ (negative infinity) → always use a round bracket (cannot
reach these values)
- Square bracket → end value is included; Round bracket → end value not included
Polynomial Functions
- Power function - simplest type of polynomial function
- f(x) = axn a → coefficients (a0, a1… an; real numbers)
n → degree of function, (non-negative integer, whole number)
x → variable
- Only one term, no other term added
- Example: y = -2x4
- General form: f(x) = anxn + an-1xn-1 + an-2xn-2 + … + a2x2 + a1x1 + a0
- Example: y = 2x3 + 5x2 + 3
- Degree of a polynomial - the highest exponent on a variable in an expression
- This determines the order how the function is written
- Not determined by the leading coefficient
- Written in descending order of power (in terms of degrees)
- Example: f(x) = x6 + 2x2 + x + 4 has a degree of 6
- Leading coefficient (anxn); constant (a0)
- Domain is set of real numbers → {X∊R} or (-∞ - to ∞)
- Real numbers - all numbers that can be placed on a number line
- Range may be all real numbers, but may have an upper/lower bound (not both)
- Can have a restriction
- No horizontal or vertical asymptotes
- Polynomial functions with degree 0 are just horizontal lines (i.e. x = 5)
- Shapes of graphs depends on degree of function (generally 5 shapes)
- Even degrees → U-shaped, ends go same direction
- Odd degrees → S-shaped, ends go opposite directions
Linear; n = 1 Quadratic; n = 2 Cubic; n = 3 Quartic; n = 4 Quintic; n = 5
- Straight line - U-shaped - S-shaped curve - Wider U-shaped - S-shaped curve,
- Always parabola - Always parabola like cubic but
increasing/ - Vertex increasing/ - ‘Flatter’ near steeper near origin
decreasing, no - Symmetrical decreasing vertex - Can increase/
curves about y-axis through turn - Symmetrical decrease through
points about y-axis turn points
