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Chapter 1 : EQUALITY, LOGARİTHM and FUNCTION
Lineer Inequalities
Solve that inequality |
2 < | 3x – 4 | Þ 2 < style=""> Þ 6 < style=""> Þ 2 < style="position: relative; top: 12pt;">
Solution Set : { x | x < È x > 2 }
Quadratic Inequalities
x2 – x – 6 > 0 Solve that inequality |
x2 – x – 6 > 0 Þ (x – 3) (x + 2) > 0
Solution Set : { x | x < -2 È x > 3 }
Solve for x if sin2x – 3cos2x + 2 = 0 is given where xÎ [ 0,2p] |
sin2x – 3cos2x + 2 = 0 Þ 1-cos2x – 3cos2x + 2 = 0 Þ 4cos2x = 3 Þ cos x =
Solution set : { x = x = }
COORDINATE PLANE
Two points define a uniqe line on two dimensional plane.
a) Two points where A(x1,y1) , B(x2,y2)
b) Slope and one point y – y1 = m (x – x1)
c) Slope and y-intercept y = m x + b
Defines a uniqe line.
Suppose you are given points A(-2,3) and B(3,5) , write the equation of the line. |
m = slope = = ; y = m x + b Þ 3 = . 2 + b , b =
y = . x + or we write 5 y – 2 x – 19 = 0 as standart form.
Paralel lines , Perpendicular lines
Parallel lines have equal slopes.
Perpendicular lines have slopes that are negative reciprocals.
Exercises:
I- Given l1 // to the x-axis, write the equation of l1 if it passes from (-3,2).
y = m x + n y = n is the equation of a horizontal line.
y = 0.-3 + 2 so we find y = 2 line
II- Suppose you are given 2x + 3y = 6 write the equation of the perpendicular line that passes from the origin.
a. Find the slope of the original line
b. Find negative reciprocal.
c. Write equation of
a) 2x + 3y = 6 Þ 3y = -2x + 6 Þ y = x + 2 moriginal =
b) =
c) y = x
III- Write the equation of a linet hat has y intercept 2, and passes from (-2,4)
y = m x + n Þ 4 = -2m + 2 , m = -1 Þ y = - x + 2
Intersection of Lines
Find the intersection of 2x + 3y = 6 and x – 2y = -2 |
2x + 3y = 6
x – 2y = -2 y = x = Point, (,)
CIRCLE EQUATION
(x-a)2 + (y-b)2 = r2 Circle, with center (a,b) radius r
Circle & Line intersection
1 point of int. 2 pts. of int. No intersect.
Given x2 + y2 + 6x – 2y + 6 = 0 is the eq. of the circle. Find center, find radi. |
(x-a)2 + (y-b)2 = r2 is circle eq.
(x2 + 6x + 9 ) + (y2– 2y +1) + 6 – 9 – 1 = 0 Þ (x + 3)2 + (y - 1)2 = 22
Center : C(-3,1) radius : 2
Definition: A function is a relation such that there exists only 1 “y” for each “x” |
Sketch y = x ¹ -2 |
x > -2 x < -2
y = = 1 y = = -1
Sketch y = | x | |
y = x veya y = -x y =
Sketch y = 2| x | + 3 |
Sketch y = | x - 2| |
Sketch y = | x + 1| - 3 |
Describe the graph of the given equation x2 + y2 + x = 0 |
( x2 + x + ) + y2 - = 0 Þ ( x - )2 + (y – 0)2 =
x = - ; y = 0 Þ Center: C(- , 0 ) radius :
Find an equation of the perpendicular bisector of the line segment joining points. (2,1) and (1,2) |
Mid points
Slope of original line : m = = -1
Slope of perpendicular line : = + 1
Point :
Equation of line : y - = 1 ( x - ) Þ y = x - + Þ y = x
Length of segment : d = =
Sketch the graph of y = | x + 1 | + | x – 1 | |
Case I x + 1 0 x – 1 0
x -1 x 1
x 1 Þ y = x + 1 + x – 1 Þ y = 2x
Case II x + 1 0 x – 1 0
x -1 x 1
x 1 Þ y = x + 1 + x – 1 Þ y = 2
More About Functions
Domain
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Ex: Find the domain of f(x) = |
7x + 4 ³ 0 Þ 7x ³ -4 Þ x ³
Ex: Find the domain of f(x) = |
x ¹2 Ù ³ 0
D : { x | 1 £ x <>
Ex: Find the domain of f(x) = |
Ex: Find the domain of f(x) = |
D : x – 1 ³ 0 Þ x ³ 1 D : x > 1
COMPOSITION OF FUNCTIONS
h(x) = , g(x) = are given
goh = hog = hoh =
Ex: Consider g(x) = Try to write it is a composition of two functions |
1. f(x) = ; h(x) = | x | Þ g(x) = f o h =
2. f(x) = ; h(x) = 1 + | x | Þ g(x) = f o h =
3. f(x) = ; h(x) = x2 Þ g(x) = f o h = =
DOMAIN OF COMPOSITION OF FUNCTIONS
If f(x) and g(x) are two function then (fog)(x) = f (g(x))
Ex: f(x) = g(x) = - x2 compute domain of fog and gof |
f(x) = g(x) = - x2 Þ fog = D :
Þ gof = - []2 = - x D : x ³ 0
It is because of the domain of
Ex: Find the domain and range of y = 2 + |
D : x ³ 1
R : [ 2 , ¥ )
y = y = y = 2 +
EXPONANTIAL FUNCTION
Definition : The functions of the form f(x) = ax a ÎR+ - {1} are called exponential functions.
Ex: f(x) = 3x Ex: f(x) =
Domain : R Domain : R
Range : (0 , ¥) Range : (0 , ¥)
Some properties
i-) ax = ak Û x = k
ii-) (ax)t Û ax.t
iii-) ax . ak Û ax+k
* f(x) = ax is an exponential function a ÎR+ - {1}
* f(x) = ex is an exponential function which is called “naturel exponential function.”
Function – Inverse Function
In order f to have an inverse function f should be one-to-one and onto
Now let’s consider the function :
f(x) = ax f -1(x) = logax
Domain : R Domain : (0,¥ )
Range : (0,¥ ) Range : R
Some Properties of Logarithmic Functions |
Logn (A.B) Û Logn A + Logn B |
Logn () Û Logn A - Logn B |
Log Ap Û Loga A |
Loga A Û |
Loga A Û “Taban Değiştirme” |
Loga b . Logb a = 1 |
Log b = - Loga b |
Loga b . Logb c . Logc d . . . . . . Logy z = Loga z |
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Ex: Using the logarithmic properties rewrite the expressions below in terms of lna, lnb , lnc a) ln a2 b) ln c) ln d) ln |
a) ln a2 = ln a2 + ln = 2 . ln a + ln b + ln c
b) ln = ln b – ln (a3.c) = ln b – 3.ln a – 3.lnc
c) ln = ln - ln (a.b) = ln c – ln a – ln b
d) ln = ln = [ ln a + 3.lnb -2.lnc ] = lna + ln b – ln c
Ex: Rewrite the expressions below as a single logarithm a) 4 log 2 – log 3 + log 16 b) log x – 3.log 2x + 3.log 2 c) 2.ln (x+1) + ln x – 2.ln |
a) 4 log 2 – log 3 + log 16 = log 16 – log 3 + log 16 = log + log 16 = log
b) log x – 3.log 2x + 3.log 2 = log - log 8x3 + log 8 = log x-3/2
c) 2.ln (x+1) + ln x – 2.ln = ln (x+1)2 + ln x1/3- ln x = ln
Domain of logarithm Function
If f(x) = loga X a ÎR+ - {1} Domain : (0 , ¥) Range : R
If f(x) = logg(x) h(x) Domain of f(x) = { x| h(x) > 0 } Ç { x| g(x) > 0 , g(x) ¹ 1 }
Ex: Find the domain of the following function f(x) = log3 |
There are two conditions.
1.) > 0 2.) a = 3 > 0 , a ¹ 1
> 0 x + 1 = 0 ; x – 1 = 0
x = -1 ; x = 1
Domain of f(x) : (-¥,-1) È (1, ¥ )
Some Notes About Functions
Definition : A function is a set of ordered pairs (x,y) in which no two distinct pairs have the same first number .
This is not a function.
Definition : The set of all “x” is called domain of a function, set of all “y” is called Range of a function.
Ex: Consider f(x) = , sketch the graph, find the domain and range |
y
Domain : R+È {0} = [ 0,¥) Range : R+È {0} = [ 0,¥)
x
Ex: Consider f(x) = , sketch the graph, find the domain and range |
Solution : x2 – 9 ³ 0 Þ (x-3) (x+3) ³ 0 x = 3 , x = -3
Domain : R+È {0} =(-¥,-3]È[3, ¥)
Range : R+È {0} = [ 0,¥)
Ex: Find the domain and range, and draw the graph of; f(x) = |
Soln: Domain : R Range : { -3, 1, 4 }
.
For example : f(-5) = -3 ; f(-1000000000000) = -3
; f(1000) = 4
Ex: Find the domain and range of f(x) = | x | then draw it’s graph |
Soln. f(x) = | x | Domain : R
Range : R+È {0} = [ 0,¥) “All nonnegative real numbers”
Ex: f(x) = , find domain , range and draw it’s graph |
Soln.
f(x) = Domain : R - { 2 } Range : R – { 1 }
f -1(x) = Domain : R – { 1 } Range : R – { 2 }
Range of f(x) = Domain of f -1(x) = R – { 1 }
Ex: f(x) = Find the domain, range and draw graph |
Solution:
Domain : R Range : R – { 6 }
y = x + 3
Ex: Given f(x) = x2 + 3x – 4 Find a) f(x+h) b) f(x) + f(h) |
Soln:
a) f(x+h) = (x+h)2 + 3(x+h) – 4
b) f(x) + f(h) = x2 + 3x – 4 + h2 + 3h – 4
Ex: Given f(x) = , g(x) = find the domain of; a) (f+g)(x) b) (f-g)(x) c) (f.g)(x) d) ()(x) |
a) (f+g)(x) = f(x) + g(x) = + x + 1 ³ 0 , x ³ -1 ; -x + 4 ³ 0 , x £ 4 Domain of f(x) : [-1,¥) ; Domain of g(x) : (-¥,4] then, Doman of (f+g)(x) : [-1,¥) Ç (-¥,4] = [-1 , 4 ] b) (f-g)(x) = f(x) -g(x) = - x + 1 ³ 0 , x ³ -1 ; -x + 4 ³ 0 , x £ 4 Domain of (f-g)(x) : [-1 , 4 ]
c) (f.g)(x) = f(x) . g(x) = . ; Domain of (f . g)(x) : [-1 , 4 ] d) ()(x) = = ; Domain of ()(x) : [-1 , 4 )
Definition: Given two function f and g then the composite function defined by
(fog)(x) = f (g(x) )
And domain of (fog)(x) is the set of all numbers x in the domain of such that g(x) is in the domain of f.
Ex: f(x) = 2x + 7 g(x) = x2 – 8 a) (fog)(x) b) (fof)(x) |
a) (fog)(x) = f( g(x) ) = 2 (x2 – 8 ) + 7 = 2x2 – 9
b) (fof)(x) = f( f(x) ) = 2 ( 2x + 7 ) + 7 = 4x + 21
Ex: Find the domain of (fog)(x) if f(x) = , g(x) 2x - 3 |
Soln: Domain of f(x) : [0,¥) ; Domain of g(x) :R domain of (fog)(x) : [,¥)
Chapter 2 : LIMITS and CONTINUITY
Before giving the definition of a limit, let’s give an example.
Ex: Consider a function f(x) = Domain of f(x) = R \ { 1 } ,
For x ¹ 1 we can write f(x) = = = x + 1 so for x ¹ 1 , f(x) = x + 1
Let’s draw the graph of f(x) ;
f(x) is not defined at x = 1, but when “x” approaches to x = 1 , the value of f(x) approaches to 2. In the limit the value of f(x) at x = 1 is not important. The important thing is where the value of f(x) approaches as x approaches x = 1.
At x = 1 f(x) is not defined by f(x) = 2
Informal Definition of limit:
Let f(x) be defined on an open interval about x = x0 except possible does not contain x = x0 ,
İf f(x) gets arbitrarly close to L for all x sufficiently close to x0 we say approaches the limit L as x approaches to x0 and we write Formal definition of limit;
f(x) = L means, >0 such that 0 < | x - x0 | < Þ | f(x) – L | <
Ex: Consider the following functions; f(x) = g(x) = x + 1 h(x) = |
f(x) = 2 g(x) = 2 h(x) = 2
LIMIT RULES
If L, M, a and K are real numbers and,
f(x) = L and g(x) = M
1) ( f(x) + g(x) ) = f(x) + g(x) = L + M |
2) ( f(x) - g(x) ) = f(x) - g(x) = L - M |
3) ( f(x) . g(x) ) = f(x) . g(x) = L . M |
4) () = f(x) : g(x) = L : M |
5) ( k. f(x) ) = k f(x) = k . L |
Theorem: (Limits of Polynomials)
If f(x) = an xn + an-1 xn-1 + an-2 xn-2 + . + . + . . . . . . . . .+ ao
f(x) = f(C) = an Cn + an-1 Cn-1 + an-2 Cn-2 + . + . + . . . . . . . . .+ ao
Theorem: If f(x) and g(x) are polynomials then;
If g( C ) ¹ 0
Ex: Find the limits of the following functions. a) (x3 + 4x2 – 3 ) b) c) |
a) (x3 + 4x2 – 3 ) = 13 + 4 . 12 – 3 = 2
b) = =
c) = =
Ex: Find the limits of the following functions. a) b) c) |
a) = then = = 3
b) = then = = =
c) = then = =
=
Sandwich Theorem
Let f(x) £ g(x) £ h(x) for all x in open interval containing x = c , except possibly at x = c
f(x) = L , h(x) = L then g(x) = L
Ex: Given that 1 - £ U(x) £ 1 + for all x ( x ¹ 0 ) Find U(x) |
Solution: 1 - £ U(x) £ 1 + ( x ¹ 0 ) Take the limit of both sides
(1 - ) £ U(x) £ (1 + )
1 £ U(x) £ 1
By the SANDWICH ttheorem: U(x) = 1
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