Trig test 2

The value of tan^-1X is an angle in the interval

(-pi/2,pi/2)

What is the range of y=tan^−1x​?

(-pi/2,pi/2)

In the function y=tan^−1x​, the x in tan^−1x is defined over the interval

(−∞,∞)

Sec t=

1/x

Csc t=

1/y

If the terminal side of an angle lies in Quadrant I​, then

All of the trigonometric functions are positive.

Reference angle case 1

Case​ 1: If the terminal side of θC lies in quadrant​ I, then theta θR=θC.

Reference angle case 2

Case​ 2: If the terminal side of θC lies in quadrant​ II, then θR=π−θC.

Reference angle case 3

Case​ 3: If the terminal side of θC lies in quadrant​ III, then θR=θC−π.

Reference angle case 4

Case​ 4: If the terminal side of θC lies in quadrant​ IV, then θR=2π−θC

Properties of graph y=cotx

D: R: (−∞,∞)​ Period: pi Odd y intercept: None Zeros of the form ((2N+1)/2)pi, where n is an integer Every halfway point has a y-coordinate of: −1 or 1​ Principle cycle: (0,pi)

Properties of graph y=cosx

D: (-infinity,infinity) All real numbers R: [-1,1] Period: 2pi Even y intercept: 1 X intercept: (2n+1)*pi/2, where n is an integer relative max: X=2piN, where N is an integer relative min: X=Pi+ 2piN, where N is an integer Zeros of the form ((2N+1)/2)pi, where n is an integer

Properties of graph y=sinx

D: (-infinity,infinity) All real numbers R: [-1,1] Period: 2pi Odd y intercept: 0 X intercept: npi, where n is an integer relative max: x= pi/2 + 2piN, where N is an integer relative min: 3pi/2 + 2piN, where N is an integer Zeros of the form: Nπ​, where n is any​ integer

Properties of graph y=tanx

D: (-infinity,infinity) All real numbers, except odd integer multiples of pi/2 R: (−∞,∞)​ Period: pi Odd y intercept: 0 X intercept: Zeros of the form Nπ​, where n is any​ integer Every halfway point has a y-coordinate of: −1 or 1​ Principle cycle: (-pi/2,pi/2)

Properties of graph y=secx

D: all real numbers except odd integer multiples of π/2​ R: (−∞,−1]∪[1,∞) Period: 2pi Even relative max: x=πn where n is an odd integer Vertical asymptotes of the form: x= nπ/2 where n is an odd integer

Properties of graph y=cscx

D: all real numbers except odd integer multiples of π/2​,pi, R: (−∞,−1]∪[1,∞) Period: 2pi Odd relative max: x= -pi/2 + 2piN, where N is an integer Vertical asymptotes of the form: x=nπ where n is an integer

Which of the following statements is not true about the function y=Acos(Bx)​?

If B>0​, then the function y=Acos(−Bx) is equivalent to the function y=−Acos(Bx).

Graph of y=cos x

Quarter points: (0,1), (pi/2,0), (pi, -1), (3pi/2,0), (2pi, 1)

Which of the following statements describes the definition of amplitude of a sine or cosine​ function?

The amplitude is the measure of half the distance between the maximum and minimum values.

If theta= sine^-1x​, then which of the following statements best describes angle θ​?

The angle θ is an angle satisfying the inequality -π/ 2 ≤ θ ≤ π/2 having a terminal side lying in Quadrant​ I, Quadrant​ IV, on the positive​ x-axis, on the positive​ y-axis, or on the negative​ y-axis.

If θ=cos^−1x​, then which of the following statements best describes angle θ​?

The angle θ is an angle satisfying the inequality 0≤θ≤π having a terminal side lying in Quadrant​ I, Quadrant​ II, on the positive​ x-axis, on the positive​ y-axis, or on the negative​ x-axis

If θ=tan^−1x​, then which of the following statements best describes angle θ​?

The angle θ is an angle satisfying the inequality −π/2 < θ < π/2 having a terminal side lying in Quadrant​ I, Quadrant​ IV, or on the positive​ x-axis.

Given the expression Csc (cos^-1(-1/2)) which of the following is not​ true?

The expression Csc (cos^-1(-1/2)) is equal to -2/square root of 3

If​ A, B, and C are constants such that B>1​, then which of the following statements is true about the graph of y=Acos(Bx−C)​?

The period is 2π/B and the phase shift is C/B.

If​ A, B,​ C, and D are​ constants, then which of the following statements is true about the graph y=Acos(Bx−C)+D​?

The range is [−IAI+D, IAI+D].

Which of the following is not a characteristic of the sine​ function?

The sine function obtains a relative maximum at x equals x= π/2+πn where n is an integer.

When sketching the graph of y=Atan(Bx+C)+D which of the following best describes how to determine the​ x-coordinates of the halfway points of the principal​ cycle?

The​ x-coordinate of each halfway point is located halfway between the​ x-coordinate of the center point and a vertical asymptote.

Which of the following statements is​ true?

The​ x-intercepts of y=tanx are the same as the​ x-coordinates of the center points of y=tanx.

Which of the following is not a characteristic of the cosine​ function?

The​ y-intercept is 0.

The graph y=sin(x+C) can be obtained by horizontally shifting each quarter point of y=sin(x) to the left C units.

Which of the following statement best describes the graph of y=sin(x+C) where Upper C greater than 0C>0​?

In the function y=cos^−1x​, the x in cos^−1x is defined over the interval

[-1,1]

In the function y=sin^−1x​, the x in sin^−1x is defined over the interval

[-1,1]

The value of sine^-1X is an angle in the interval

[-pi/2,pi/2]

The value of cos^-1X is an angle in the interval

[0,pi]

What is the domain of the restricted cosine function whose inverse function is y=cos^−1x​?

[0,pi]

If 3π/4<θ<5π/6​, then which of the following mathematical statements is​ true?

cos^−1(cosθ)=θ

Graph of y=sin x

quarter points: (0,0),(pi/2,1),(pi,0),(3pi/2,-1),(2pi,0)

Secant/Sec

r/x= Hyp/Adj

Cosecant/Csc

r/y= Hyp/Opp

Which of the following expressions does not result in an angle having a terminal side that lies in Quadrant​ I?

sin^-1(sin6pi/5)

Which of the following expressions is equivalent to the angle pi/6?

tan^-1(tan(-5pi/6))

tan: the angle lies in the interval 0<theta<pi/2

terminal side: Quad 1

sin: the angle lies in the interval 0<theta<pi/2

terminal side: Quad 1 or positive y-axis

tan: the angle lies in the interval -pi/2<theta<0

terminal side: Quad 4

sin: the angle lies in the interval -pi/2<theta<0

terminal side: Quad 4 or negative y-axis

cos: the angle lies in the interval pi/2<theta<pi

terminal side: Quadrant 2 or negative​ x-axis

cos: the angle lies in the interval 0<theta<pi/2

terminal side: Quadrant I or positive​ x-axis

If the terminal side of an angle lies in Quadrant IV​, then

the Cosine ​(and secant) functions are positive

If the terminal side of an angle lies in Quadrant II​, then

the Sine ​(and cosecant) functions are positive

If the terminal side of an angle lies in Quadrant III​, then

the Tangent ​(and cotangent) functions are positive.

Value of B

to graph divide period into 4 and then add that number to each x value.

Value of A

to graph multiple Y value of quarter points by A.

Cos t=

x/1

Cosine/Cos

x/r= Adj/Hyp

Cot t=

x/y

Cotangent/Cot

x/y= Adj/Opp

Sin t=

y/1

Sine/Sin

y/r= Opp/Hyp

Tan t=

y/x

Tangent/Tan

y/x= Opp/Adj

y=-2cos(-4x) is the same as

y=-2cos(4x)

y=sin(-pix) is the same as

y=-sin(pix)

Phase shift:

y=Asin(Bx+C) C/B

Amplitude

y=AsinX IAI absolute value of A so always positive. Changes range

Period

y=sin(BX) Period= 2pi/B as long as B is positive

Finding the principle cycle of y=Atan(Bx−C)+D​,

−π/2<Bx−C<π/2