カテゴリー 全て - tangent - identities - domain - range

によって MAMADOU BARRY 9年前.

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TRIGONOMETRIC FUNCTIONS

The tangent function exhibits specific properties based on its quadrant positioning where it is positive in the first and third quadrants, and negative in the second and fourth quadrants.

TRIGONOMETRIC FUNCTIONS

TRIGONOMETRIC FUNCTIONS

COSECANTE

FORMULAS OF COSECANT
EVEN ODD IDENTITY
INVERSE OF COSECANT
GRAPH OF COSECANT
PROPERTIES OF COSECANT
EVEN ODD PROPERTIES
SIGNS OF COSECANT

THE DOMAINE OF THE COSECANT FUNCTION IS THE SET OF ALL REAL NUMBERS EXCEPT  INTEGERS MULTIPLES OF π(180 degrees)

• Domain: IR/{X≠Kπ},K is an  integer

THE RANGE OF THE COSECANT FUNCTION CONSISTS OF ALL REAL NUMBERS LESS THAN OR EQUAL TO -1 OR GREATER THAN OR EQUAL TO 1. THAT IS

• Range: IR/{Y≤-1 OR Y≥1}

TANGENTE

FORMULAS OF TANGENT

tan(2α) =(2tan2α)/(1-tan^2(α))



tan(α/2) =± √(1-cosα)/(1+cosα)

tan(α+β) = (tanα+tanβ)/(1-tanαtanβ)

tan(α-β) = (tanα-tanβ)/(1+tanαtanβ)

The tangent function is an odd function;

tan(-ϴ) = tan ϴ

by using the pythagorian theorem we can demonstrate that:

tan^2(ϴ) +1 = sec^2(ϴ)

Reciprocal Identity

tan ϴ = sinϴ/cosϴ and cotϴ = cosϴ/sinϴ

hence tanϴ = 1/cotϴ

tanϴ = sinϴ/cosϴ

INVERSE OF TANGENT

The domain of the inverse function of tangent is negative infinity to infinity and the range from zero inclusive 90 degree exclusive

GRAPH OF TANGENT
PROPERTIES OF TANGENT
EVEN ODD PROPERTY

the tangent function is an odd function;

tan(-ϴ) = -tan ϴ

SIGNS

The tangent function is:

 -positive in the first and third quadrant

 -negative in the second and fourth quadrant

The domain of tangent function is the set of all real numbers except odd integers multiple of kΠ

COTANGENTE

FORMULAS OF COTANGENTE
PRODUCT TO SUM
HALPH ANGLE

cot(2α) = (1-tan^2(α))/(2tan2α)

cot(α/2) =± 1/√(1-cosα)/(1+cosα)

SUM AND DIFFERENCE

cot(α+β) = (1-tanαtanβ)/(tanα+tanβ)


cot(α-β) = (1+tanαtanβ)/(tanα-tanβ)

EVEN ODD

COTANGENT IS AN ODD FUNCTION LIKE TANGENT;

cot(-ϴ) = -cot(ϴ)

PYTHAGORIAN

using the pythagorian identity

cos^2ϴ +sin^2ϴ = 1 , and by dividing both sides by sin^ϴ, we can obtain:

cot^2ϴ +1 = csc^2ϴ 

RECIPROCAL

cotϴ = 1/tanϴ

QUOTIENT
INVERSE OF COTANGENTE
DOMAIN AND RANGE
GRAPH OF COTANGENTE
PROPERTIES OF COTANGENTE
EVEN ODD PROPERTY
SIGNS OF COTANGENTE

SINE

FORMULAS OF SINE
SUM TO PRODUCT
PRODUCT TO SUM
HALF ANGLE
DOUBLE ANGLE
SUM AND DIFFERENCE
DERIVATE IDENTITY
PYTHAGORIAN IDENTITY

sin^2ϴ + cos^2ϴ = 1

INVERSE OF SINE
GRAPH OF SINE

The periodicity is given by T=2π/w. We know that the graph of y = sin(wx) is obtained from the graph of y = sin(x) by performing a horizontal compression or stretch by a factor of 1/w. This horizontal compression replaces the interval[0,2π], which contains one period of the graph of y = sin(x), by the interval [0,2π/w], which contains one period of the graph of y = sin(wx).

In general, the value of the function

y = A sin(x), where A≠0, will always satisfy the inequality

-|A| ≤ A sin(x) ≤ |A|. The number |A| is called the amplitude of y = A sin(x)

PROPERTIES OF SINE
EVEN ODD PROPERTIE

The sine function is an odd function there for ,

sin(-ϴ) = -sinϴ

SIGNS OF SINE

The sine function is :

-positive in the first and second quadrant;

-negative in the third and fourth quadrant

The domain of the sine function is the set of all real numbers.

The range is the set of all real numbers between -1 and 1 inclusive

SECANT

FORMULAS FOR SECANT

sec( α/2) = 1/( √(1-cos α)/2)


sec(2ϴ) =1/(cos^2 ϴ - sin^2 ϴ)

sec(2ϴ) = 1/(1- 2sin^2 ϴ)

sec(2ϴ) = 1/( 2cos^2 ϴ - 1)

INVERSE OF SECANT

FOR THE SECANT AND ITS INVERSE FUNCTION, THE FOLLOWING PROPERTIES HOL:

SEC^-1(SEC X) = X ; [0,pi/2)

SEC(SEC^-1 X) = X ; X LESS THAN or equal to -1 or X greater than or equal to 1

DOMAIN AND RANGE

THE SECANT FUNCTION IS NOT A ONE-TO-ONE FUNCTION WHEN WE CONSIDER ITS ENTIRE DOMAIN, HOWEVER, WE CAN RESTRICT THAT DOMAIN TO GET AN INVERSE FUNCTION. If we restrict the domain of

 y = sec(x) to the interval [0,π/2), the restricted function y = sec(x)  ,

0 ≤ x < π/2 is one-to-one and hence have an inverse function which will be obtained by interchanging x and y in the function

y =f(x) = sec(x) . The implicit form of the inverse is x = sec(y) , 0 ≤ y < π/2 and we obtain

y = sec^-1(x) where

0 ≤ y < π/2

Use sum and difference to establish identities

cos(π/2 -ϴ) = sinϴ

1/cos(π/2 -ϴ) = 1/sinϴ

sec(π/2 -ϴ) = cscϴ

use double angle formula to establish identity

cos^2 ϴ =(1+cos 2ϴ)/2

sec^2 ϴ = 2/(1+cos 2ϴ)

PYTHAGORIAN IDENTITY

sin^2 ϴ + cos^2 ϴ = 1

divide both side by cos^2 ϴ ,we will have

tan^2 ϴ + 1 = sec^2 ϴ

RECIPROCAL IDENTITY

sec ϴ cos ϴ = 1 hence sec ϴ = 1 / cos ϴ

GRAPH OF SECANT
AMPLITUDE AND PERIODICITY

In general, the value of the function

y = A sec(x), where A≠0, will always satisfy the inequality

-|A| ≤ Acos(x) ≤ |A|. The number |A| is called the amplitude of y = A sec(x)

The periodicity is given by T=2π/w. We know that the graph of y = cos(wx) is obtained from the graph of y = cos(x) by performing a horizontal compression or stretch by a factor of 1/w. This horizontal compression replaces the interval[0,2π], which contains one period of the graph of

y = cos(x), by the interval [0,2π/w], which contains one period of the graph of

y = cos(wx).

Since we want to graph secant in the xy-plane,we shall use the traditional symbol x for the independent variable(or argument) and y for the dependent variable(or value at x).so we write

y=f(x)=sec(x). The independent variable x represents an angle measured in radians.

since the cosine function has period 2π,we only need to graph y=f(x)=sec(x) on the interval [0,2π],the remainder will consist of repetitions of this portion.

PROPERTIE OF SECANT
EVEN ODD PROPERTIES

THE SECANTE FUNCTION IS AN EVEN FUNCTION WHICH MEANS:

SEC(-ϴ)=SEC(ϴ)

THE SECANTE FUNCTION LIKE THE COSINE FUNCTION IS A PERIODIC FUNCTION WITH PERIOD

SEC(ϴ+2π)=SEC(ϴ)

SIGNS OF SECANT

BETWEEN THE INTERVAL [0,90] DEGREE,

SECANTE OF ANY ANGLE IN THAT INTERVAL IS POSITIVE,

SEC(X)>0

BETWEEN THE INTERVAL [90,180] DEGREE,

SECANTE OF ANY ANGLE IN THAT INTERVAL IS NEGATIVE,

SEC(X)<0

BETWEEN THE INTERVAL [180,270] DEGREE,
SECANTE OF ANY ANGLE IN THAT INTERVAL IS NEGATIVE,

SEC(X)<0

BETWEEN THE INTERVAL [270,0] DEGREE,

SECANTE OF ANY ANGLE IN THAT INTERVAL IS POSITIVE,

SEC(X)>0

DOMAIN AND RANGE

THE DOMAINE OF THE SECANT FUNCTION IS THE SET OF ALL REAL NUMBERS EXCEPT ODD INTEGERS MULTIPLES OF π/2(90 degrees)

• Domain: IR/{X≠Kπ/2},K is an odd integer

THE RANGE OF THE SECANT FUNCTION CONSISTS OF ALL REAL NUMBERS LESS THAN OR EQUAL TO -1 OR GREATER THAN OR EQUAL TO 1. THAT IS

• Range: IR/{Y≤-1 OR Y≥1}

COSINE

FORMULAS FOR COSINE
SUM TO PRODUCT

Sum to Product formulas

cos α + cos β = 2[cos(α+β)/2 cos(α-β)/2]

cos α - cos β =-2[sin (α+β)/2 sin(α-β)/2]

PRODUCT TO SUM

product to sum formulas

cos α cos β  = (1/2)[cos(α-β)+cos(α+β)]

sin α cos β = (1/2)[sin(α+β)+sin(α-β)] 

HALF ANGLE

Half angle formulas for cosine

cos α/2 = √(1-cos α)/2

DOUBLE ANGLE

Double angle formulas

cos(2ϴ) = cos^2 ϴ - sin^2 ϴ

cos(2ϴ) = 1- 2sin^2 ϴ

cos(2ϴ) = 2cos^2 ϴ - 1

DIFFERENCE

cos(α-β) = cos α cos β + sin α sin β

SUM

 cos(α+β) = cos α cos β - sin α sin β

IDENTITIES

Two functions f and g are said to be identically equal if

               f(x) = g(x)

for every value of x for which both functions are defined. Such an equation is referred to as an identity.

DERIVATE IDENTITIES

Use sum and difference to establish identities

 cos(π/2 -ϴ) = sinϴ

use double angle formula to establish identity

cos^2 ϴ =(1+cos 2ϴ)/2

EVEN ODD IDENTITY

cos(-ϴ) = cos ϴ

PYTHAGORIAN IDENTITY

sin^2 ϴ + cos^2 ϴ = 1

RECIPROCICAL IDENTITY

sec ϴ cos ϴ = 1 hence cos ϴ = 1 / sec ϴ

QUOTIENT IDENTITY

tan ϴ = sin ϴ/cos ϴ hence

cos ϴ = sin ϴ/tan ϴ 

And cot ϴ = cos ϴ / sin ϴ hence

      cos ϴ = cot ϴ/ sin ϴ

INVERSE COSINE
PROPERTIES

For the cosine function and its inverse, the followings properties hold:

f^-1(f(x)) = cos^-1(cos(x)) = x ,0 ≤ x ≤ π

f(f^-1(x)) = cos(cos^-1(x))=x, -1 ≤ x ≤ 1

RANGE

The range of the inverse cosine function is the restricted domain [0,π]

DOMAINE

THE COSINE FUNCTION IS NOT A ONE-TO-ONE FUNCTION WHEN WE CONSIDER ITS ENTIRE DOMAIN, HOWEVER, WE CAN RESTRICT THAT DOMAIN TO GET AN INVERSE FUNCTION. If we restrict the domain of y = cos(x) to the interval [0,π], the restricted function y = cos(x)  

0 ≤ x ≤ π is one-to-one and hence have an inverse function which will be obtained by interchanging x and y in the function

y =f(x) = cos(x) . The implicit form of the inverse is x = cos(y) , 0 ≤ y ≤ π and we obtain

 y = cos^-1(x) where -1 ≤ x ≤ 1 and

 0 ≤ y ≤ π

GRAPH OF COSINE
PERIODICITY

The periodicity is given by T=2π/w. We know that the graph of y = cos(wx) is obtained from the graph of y = cos(x) by performing a horizontal compression or stretch by a factor of 1/w. This horizontal compression replaces the interval[0,2π], which contains one period of the graph of y = cos(x), by the interval [0,2π/w], which contains one period of the graph of y = cos(wx).

AMPLITUDE

In general, the value of the function

 y = A cos(x), where A≠0, will always satisfy the inequality

-|A| ≤ Acos(x) ≤ |A|. The number |A| is called the amplitude of y = A cos(x)

GRAPH

Since we want to graph cosine in the xy-plane,we shall use the traditional symbol x for the independent variable(or argument) and y for the dependent variable(or value at x).so we write

y=f(x)=cos(x). The independent variable x represents an angle measured in radians.

since the cosine function has period 2π,we only need to graph y=f(x)=cos(x) on the interval [0,2π],the remainder will consist of repetitions of this portion.

graph see book chapter 6 section 6.4 figure 48 , table 7 page 395

PROPERTIES OF COSINE
EVEN ODD PROPERTY

A function f is even if f(-ϴ)=f(ϴ) for all ϴ in the domain of f, function f is odd if f(-ϴ)=-f(ϴ)

for all ϴ in the domain of f.

cos(-ϴ)=cos(ϴ)

proof see book chapter 6 section 6.3 page 389

PERIOD OF COSINE

DEFINITION

A function f is called periodic if there is a positive number p such that, whenever ϴ is in the domain of f, so is ϴ+p

f(ϴ+p)= f(ϴ). ϴ is the argument of the function.

the cosine function is periodic with period 2π

      cos(ϴ+2π)=cos(ϴ)

SINGS OF COS

QUADRANT IV

BETWEEN THE INTERVAL [270,0] DEGREE,

COSINE OF ANY ANGLE IN THAT INTERVAL IS POSITIVE,

COS(X)>0

QUADRANT III

BETWEEN THE INTERVAL [180,270] DEGREE,

COSINE OF ANY ANGLE IN THAT INTERVAL IS NEGATIVE,

COS(X)<0

QUADRANT II

BETWEEN THE INTERVAL [90,180] DEGREE,

COSINE OF ANY ANGLE IN THAT INTERVAL IS NEGATIVE,

COS(X)<0

QUADRANT I

BETWEEN THE INTERVAL [0,90] DEGREE,

COSINE OF ANY ANGLE IN THAT INTERVAL IS POSITIVE,

COS(X)>0

DOMAINE AND RANGE

THE DOMAINE OF THE COSINE FUNCTION IS THE SET OF ALL REAL NUMBERS, COS(X)

 • Domain: IR

THE RANGE OF THE COSINE FUNCTION CONSISTS OF ALL REAL NUMBERS BETWEEN -1AND 1, INCLUSIVE

 • Range: [−1,1]