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All Textbook Solutions for Precalculus

In problems 3946, show that (fg)(x)=(gf)(x)=x. f(x)=9x6; g(x)=19(x+6)In Problems 39-46, show that (fg)( x )=(gf)( x )=x . f( x )=43x ; g( x )=( 4x )In Problems 39-46, show that (fg)( x )=(gf)( x )=x . f( x )=ax+b ; g(x)= 1 a (xb) a0 In Problems 39-46, show that (fg)( x )=(gf)( x )=x . f(x)= 1 x ; g(x)= 1 x In Problems 47-52, find functions f and g so that fg=H . H(x)= (2x+3) 4 In Problems 47-52, find functions f and g so that fg=H . H(x)= (1+ x 2 ) 3 In Problems 47-52, find functions f and g so that fg=H . H(x)= x 2 +1 In Problems 47-52, find functions f and g so that fg=H . H(x)= 1 x 2 In Problems 47-52, find functions f and g so that fg=H . H(x)=| 2x+1 |In Problems 47-52, find functions f and g so that fg=H . H(x)=| 2 x 2 +3 |If f(x)=2 x 3 3 x 2 +4x1 and g(x)=2 , find (fg)( x ) and (gf)( x ) .If f(x)= x+1 x1 , find (ff)( x ) .If f(x)=2 x 2 +5 and g(x)=3x+a , find a so that the graph of fg crosses the y-axis at 23.If f(x)=3 x 2 7 and g( x )=2x+a , find a so that the graph of fg crosses the y-axis at 68.63AYU 64AYU 65AYU 66AYU 67AYU 68AYU 69AYU 70AYU 71AYU 72AYU 73AYU 74AYU 75AYU 76AYU 77AYU 1AYU 2AYU 3AYU 4AYU If x 1 and x 2 are two different inputs of a function f , then f is one-to-one if _____.If every horizontal line intersects the graph of a function f at no more than one point, then f is a(n) ______ function.If f is a one-to-one function and f( 3 )=8 , then f 1 ( 8 )= ________.If f 1 denotes the inverse of a function f , then the graphs of f and f 1 are symmetric with respect to the line _________.If the domain of a one-to-one function f is [ 4, ) , then the range of its inverse function f 1 is ________.True or False If f and g are inverse functions, then the domain of f is the same as the range of g .In Problems 13-20, determine whether the function is one-to-one.In Problems 13-20, determine whether the function is one-to-one.In Problems 13-20, determine whether the function is one-to-one.In Problems 13-20, determine whether the function is one-to-one.In Problems 13-20, determine whether the function is one-to-one. (2,6),(3,6),(4,9),(1,10)In Problems 13-20, determine whether the function is one-to-one. ( 2,5 ),( 1,3 ),( 3,7 ),( 4,12 )In Problems 13-20, determine whether the function is one-to-one. { ( 0,0 ),( 1,1 ),( 2,16 ),( 3,81 ) }In Problems 13-20, determine whether the function is one-to-one. { ( 1,2 ),( 2,8 ),( 3,18 ),( 4,32 ) }In Problems 21-26, the graph of a function f is given. Use the horizontal-line test to determine whether f is one-to-one.In Problems 21-26, the graph of a function f is given. Use the horizontal-line test to determine whether f is one-to-one.In Problems 21-26, the graph of a function f is given. Use the horizontal-line test to determine whether f is one-to-one.In Problems 21-26, the graph of a function f is given. Use the horizontal-line test to determine whether f is one-to-one.In Problems 21-26, the graph of a function f is given. Use the horizontal-line test to determine whether f is one-to-one.In Problems 21-26, the graph of a function f is given. Use the horizontal-line test to determine whether f is one-to-one.25AYU 26AYU 27AYU 28AYU 29AYU 30AYU 31AYU 32AYU In Problems 35-44, verify that the functions f and g are inverses of each other by showing that f(g(x))=x and g(f( x ))=x . Give any values of x that need to be excluded from the domain of f and the domain of g . f( x )=3x+4 ; g(x)= 1 3 ( x4 )In Problems 35-44, verify that the functions f and g are inverses of each other by showing that f(g(x))=x and g(f( x ))=x . Give any values of x that need to be excluded from the domain of f and the domain of g . f( x )=32x ; g( x )= 1 2 ( x3 )In Problems 35-44, verify that the functions f and g are inverses of each other by showing that f(g(x))=x and g(f( x ))=x . Give any values of x that need to be excluded from the domain of f and the domain of g . f( x )=4x8 ; g( x )= x 4 +2 In Problems 35-44, verify that the functions f and g are inverses of each other by showing that f(g(x))=x and g(f( x ))=x . Give any values of x that need to be excluded from the domain of f and the domain of g . f( x )=2x+6 ; g( x )= 1 2 x3 In Problems 35-44, verify that the functions f and g are inverses of each other by showing that f(g(x))=x and g(f( x ))=x . Give any values of x that need to be excluded from the domain of f and the domain of g . f( x )= x 3 8 ; g(x)= x+8 3 In Problems 35-44, verify that the functions f and g are inverses of each other by showing that f(g(x))=x and g(f( x ))=x . Give any values of x that need to be excluded from the domain of f and the domain of g . f( x )= (x2) 2 ; x2 ; g(x)= x +2 In Problems 35-44, verify that the functions f and g are inverses of each other by showing that f(g(x))=x and g(f( x ))=x . Give any values of x that need to be excluded from the domain of f and the domain of g . f(x)= 1 x ; g(x)= 1 x In Problems 35-44, verify that the functions f and g are inverses of each other by showing that f(g(x))=x and g(f( x ))=x . Give any values of x that need to be excluded from the domain of f and the domain of g . f(x)=x ; g(x)=x In Problems 35-44, verify that the functions f and g are inverses of each other by showing that f(g(x))=x and g(f( x ))=x . Give any values of x that need to be excluded from the domain of f and the domain of g . f(x)= 2x+3 x+4 ; g(x)= 4x3 2x In Problems 35-44, verify that the functions f and g are inverses of each other by showing that f(g(x))=x and g(f( x ))=x . Give any values of x that need to be excluded from the domain of f and the domain of g . f(x)= x5 2x+3 ; g(x)= 3x+5 12x 43AYU 44AYU 45AYU 46AYU 47AYU 48AYU In Problems 51-62, the function f is one-to-one (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . (c) Graph f , f 1 , and y=x on the same coordinate axes. f(x)=3x In Problems 51-62, the function f is one-to-one (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . (c) Graph f , f 1 , and y=x on the same coordinate axes. f(x)=4x In Problems 51-62, the function f is one-to-one (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . (c) Graph f , f 1 , and y=x on the same coordinate axes. f(x)=4x+2 In Problems 51-62, the function f is one-to-one (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . (c) Graph f , f 1 , and y=x on the same coordinate axes. f(x)=13x In Problems 51-62, the function f is one-to-one (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . (c) Graph f , f 1 , and y=x on the same coordinate axes. f( x )= x 3 1 In Problems 51-62, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . (c) Graph f , f 1 , and y=x on the same coordinate axes. f(x)= x 3 +1 In Problems 51-62, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . (c) Graph f , f 1 , and y=x on the same coordinate axes. f( x )= x 2 +4,x0 In Problems 51-62, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . (c) Graph f , f 1 , and y=x on the same coordinate axes. f(x)= x 2 +9,x0 In Problems 51-62, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . (c) Graph f , f 1 , and y=x on the same coordinate axes. f(x)= 4 x In Problems 51-62, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . (c) Graph f , f 1 , and y=x on the same coordinate axes. f(x)= 3 x In Problems 51-62, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . (c) Graph f , f 1 , and y=x on the same coordinate axes. f(x)= 1 x2 In Problems 51-62, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . (c) Graph f , f 1 , and y=x on the same coordinate axes. f(x)= 4 x+2 In Problems 63-74, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . f(x)= 2 3+x In Problems 63-74, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . f(x)= 4 2x In Problems 63-74, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . f(x)= 3x x+2 In Problems 63-74, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . f(x)= 2x x1 In Problems 63-74, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . f(x)= 2x 3x1 In Problems 63-74, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . f(x)= 3x+1 x In Problems 63-74, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . f(x)= 3x+4 2x3 In Problems 63-74, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . f(x)= 2x3 x+4 In Problems 63-74, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . f(x)= 2x+3 x+2 In Problems 63-74, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . f(x)= 3x4 x2 In Problems 63-74, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . f(x)= x 2 4 2 x 2 , x0 In Problems 63-74, the function f is one-to-one. (a) Find its inverse function f 1 and check your answer. (b) Find the domain and the range of f and f 1 . f(x)= x 2 +3 3 x 2 x0 Use the graph of to evaluate the following : Use the graph of to evaluate the following : If f( 7 )=13 and f is one-to-one, what is f 1 ( 13 ) ?If g( 5 )=3 and g is one-to-one, what is g 1 ( 3 ) ?The domain of a one-to-one function f is [ 5, ) , and its range is [ 2, ) . State the domain and the range of f 1 .The domain of a one-to-one function f is [0,) , and its range is [5,) . State the domain and the range of f 1 .The domain of a one-to-one function g is ( ,0 ] , and its range is [ 0, ) . State the domain and the range of g 1 .The domain of a one-to-one function g is [0,15] , and its range is (0,8) . State the domain and the range of g 1 .A function y=f( x ) is increasing on the interval [0,5] . What conclusions can you draw about the graph of y= f 1 (x) ?A function y=f( x ) is decreasing on the interval [0,5] . What conclusions can you draw about the graph of y= f 1 (x) ?Find the inverse of the linear function f( x )=mx+b,m0 Find the inverse of the function f(x)= r 2 + x 2 , 0xr A function f has an inverse function f 1 . If the graph of f lies quadrant I, in which quadrant does the graph of f 1 lie?86AYU 87AYU The function f( x )= x 4 is not one-to-one. Find a suitable restriction on the domain of f so that the new function that results is one-to-one. Then find the inverse of the new function.In applications, the symbols used for the independent and dependent variables are often based on common usage. So, rather than using y=f( x ) to represent a function, an applied problem might use C=C( q ) to represent the cost C of manufacturing q units of a good. Because of this, the inverse notation f 1 used in a pure mathematics problem is not used when finding inverses of applied problems. Rather, the inverse of a function such as C=C( q ) will be q=q( C ) . So C=C( q ) is a function that represents the cost C as a function of the number q of units manufactured, and q=q( C ) is a function that represents the number q as a function of the cost C . Problems 91-94 illustrate this idea. Vehicle Stopping Distance Taking into account reaction time, the distance d (in feet) that a car requires to come to a complete stop while traveling r miles per hour is given by the function d( r )=6.97r90.39 (a) Express the speed r at which the car is traveling as a function of the distance d required to come to a complete stop. (b) Verify that r=r( d ) is the inverse of d=d( r ) by showing that r( d( r ) )=r and d( r( d ) )=d . (c) Predict the speed that a car was traveling if the distance required to stop was 300 feet.In applications, the symbols used for the independent and dependent variables are often based on common usage. So, rather than using y=f( x ) to represent a function, an applied problem might use C=C( q ) to represent the cost C of manufacturing q units of a good. Because of this, the inverse notation f 1 used in a pure mathematics problem is not used when finding inverses of applied problems. Rather, the inverse of a function such as C=C( q ) will be q=q( C ) . So C=C( q ) is a function that represents the cost C as a function of the number q of units manufactured, and q=q( C ) is a function that represents the number q as a function of the cost C . Problems 91-94 illustrate this idea. Height and Head Circumference The head circumference C of a child is related to the height H of the child (both in inches) through the function H( C )=2.15C10.53 (a) Express the head circumference C as a function of height H . (b) Verify that C=C( H ) is the inverse of H=H( C ) by showing that H( C( H ) )=H and C( H( C ) )=C . (c) Predict the head circumference of a child who is 26 inches tall.In applications, the symbols used for the independent and dependent variables are often based on common usage. So, rather than using y=f( x ) to represent a function, an applied problem might use C=C( q ) to represent the cost C of manufacturing q units of a good. Because of this, the inverse notation f 1 used in a pure mathematics problem is not used when finding inverses of applied problems. Rather, the inverse of a function such as C=C( q ) will be q=q( C ) . So C=C( q ) is a function that represents the cost C as a function of the number q of units manufactured, and q=q( C ) is a function that represents the number q as a function of the cost C . Problems 91-94 illustrate this idea. Ideal Body Weight One model for the ideal body weight W for men (in kilograms) as a function of height h (in inches) is given by the function W( h )=50+2.3( h60 ) (a) What is the ideal weight of a 6-foot male? (b) Express the height h as a function of weight W . (c) Verify that h=h( W ) is the inverse of W=W( h ) by showing that h( W( h ) )=h and W( h( W ) )=W . (d) What is the height of a male who is at his ideal weight of 80 kilograms? [Note: The ideal body weight W for women (in kilograms) as a function of height h (in inches) is given by W( h )=45.5+2.3( h60 ) .In applications, the symbols used for the independent and dependent variables are often based on common usage. So, rather than using y=f( x ) to represent a function, an applied problem might use C=C( q ) to represent the cost C of manufacturing q units of a good. Because of this, the inverse notation f 1 used in a pure mathematics problem is not used when finding inverses of applied problems. Rather, the inverse of a function such as C=C( q ) will be q=q( C ) . So C=C( q ) is a function that represents the cost C as a function of the number q of units manufactured, and q=q( C ) is a function that represents the number q as a function of the cost C . Problems 91-94 illustrate this idea. Temperature Conversion The function F( C )= 9 5 C+32 converts a temperature from C degrees Celsius to F degrees Fahrenheit. (a) Express the temperature in degrees Celsius C as a function of the temperature in degrees Fahrenheit F . (b) Verify that C=C( F ) is the inverse of F=F( C ) by showing that C( F( C ) )=C and F( C( F ) )=F . (c) What is the temperature in degrees Celsius if it is 70 degrees Fahrenheit?93AYU 94AYU Gravity on Earth If a rock falls from a height of 100 meters on Earth, the height H (in meters) after t seconds is approximately H( t )=1004.9 t 2 (a) In general, quadratic functions are not one-to-one. However, the function H is one-to-one. Why? (b) Find the inverse of H and verify your result. (c) How long will it take a rock to fall 80 meters?Period of a Pendulum The period T (in seconds) of a simple pendulum as a function of its length l (in feet) is given by T( l )=2 l 32.2 (a) Express the length l as a function of the period T . (b) How long is a pendulum whose period is 3 seconds?Given f( x )= ax+b cx+d f 1 ( x ) . If c0 , under what conditions on a , b , c , d is f= f 1 ?98AYU 99AYU 100AYU 101AYU 102AYU 103AYU 4 3 = ; 8 2/3 = ; 3 2 = . (pp. A8-A9 and pp, A89-A91)Solve: x 2 +3x=4 (pp. A47-A52)True or False To graph y= (x2) 3 , shift the graph of y= x 3 to the left 2 units. (pp. 106-114)4AYU True or False The function f(x)= 2x x3 has y=2 as a horizontal asymptote. (pp. 227-229)6AYU 7AYU 8AYU 9AYU 10AYU 11AYU 12AYU 13AYU 14AYU 15AYU 16AYU 17AYU 18AYU 19AYU 20AYU 21AYU 22AYU 23AYU 24AYU In Problems 27-34, determine whether the given function is linear, exponential, or neither. For those that are linear functions, find a linear function that models the data; for those that are exponential, find an exponential function that models the data.In Problems 27-34, determine whether the given function is linear, exponential, or neither. For those that are linear functions, find a linear function that models the data; for those that are exponential, find an exponential function that models the data.In Problems 27-34, determine whether the given function is linear, exponential, or neither. For those that are linear functions, find a linear function that models the data; for those that are exponential, find an exponential function that models the data.In Problems 27-34, determine whether the given function is linear, exponential, or neither. For those that are linear functions, find a linear function that models the data; for those that are exponential, find an exponential function that models the data.In Problems 27-34, determine whether the given function is linear, exponential, or neither. For those that are linear functions, find a linear function that models the data; for those that are exponential, find an exponential function that models the data.30AYU In Problems 27-34, determine whether the given function is linear, exponential, or neither. For those that are linear functions, find a linear function that models the data; for those that are exponential, find an exponential function that models the data.In Problems 27-34, determine whether the given function is linear, exponential, or neither. For those that are linear functions, find a linear function that models the data; for those that are exponential, find an exponential function that models the data.In Problems 35-42, the graph of an exponential function is given. Match each graph to one of the following functions: (A) y =3 x (B) y =3 x (C) y= 3 x (D) y= 3 x (E) y =3 x 1 (F) y =3 x1 (G) y =3 1x (H) y=1 3 x In Problems 35-42, the graph of an exponential function is given. Match each graph to one of the following functions: (A) y =3 x (B) y =3 x (C) y= 3 x (D) y= 3 x (E) y =3 x 1 (F) y =3 x1 (G) y =3 1x (H) y=1 3 x In Problems 35-42, the graph of an exponential function is given. Match each graph to one of the following functions: (A) y =3 x (B) y =3 x (C) y= 3 x (D) y= 3 x (E) y =3 x 1 (F) y =3 x1 (G) y =3 1x (H) y=1 3 x In Problems 35-42, the graph of an exponential function is given. Match each graph to one of the following functions: (A) y =3 x (B) y =3 x (C) y= 3 x (D) y= 3 x (E) y =3 x 1 (F) y =3 x1 (G) y =3 1x (H) y=1 3 x In Problems 35-42, the graph of an exponential function is given. Match each graph to one of the following functions: (A) y =3 x (B) y =3 x (C) y= 3 x (D) y= 3 x (E) y =3 x 1 (F) y =3 x1 (G) y =3 1x (H) y=1 3 x In Problems 35-42, the graph of an exponential function is given. Match each graph to one of the following functions: (A) y =3 x (B) y =3 x (C) y= 3 x (D) y= 3 x (E) y =3 x 1 (F) y =3 x1 (G) y =3 1x (H) y=1 3 x In Problems 35-42, the graph of an exponential function is given. Match each graph to one of the following functions: (A) y =3 x (B) y =3 x (C) y= 3 x (D) y= 3 x (E) y =3 x 1 (F) y =3 x1 (G) y =3 1x (H) y=1 3 x In Problems 35-42, the graph of an exponential function is given. Match each graph to one of the following functions: (A) y =3 x (B) y =3 x (C) y= 3 x (D) y= 3 x (E) y =3 x 1 (F) y =3 x1 (G) y =3 1x (H) y=1 3 x In problems 4556, use the transformations to the graph each function. Determine the domain, range, horizontal asymptote and y-intercept of each function, f(x)=2x+1 In problems 4556, use the transformations to the graph each function. Determine the domain, range, horizontal asymptote and y-intercept of each function, f(x)=3x2 In problems 4556, use the transformations to the graph each function. Determine the domain, range, horizontal asymptote and y-intercept of each function, f(x)=3x1 In problems use the transformations to the graph each function. Determine the domain, range, horizontal asymptote and y-intercept of each function, In problems use the transformations to the graph each function. Determine the domain, range, horizontal asymptote and y-intercept of each function, In problems 4556, use the transformations to the graph each function. Determine the domain, range, horizontal asymptote and y-intercept of each function, f(x)=4(13)x In problems use the transformations to the graph each function. Determine the domain, range, horizontal asymptote and y-intercept of each function, In problems use the transformations to the graph each function. Determine the domain, range, horizontal asymptote and y-intercept of each function, In problems use the transformations to the graph each function. Determine the domain, range, horizontal asymptote and y-intercept of each function, In problems use the transformations to the graph each function. Determine the domain, range, horizontal asymptote and y-intercept of each function, In problems use the transformations to the graph each function. Determine the domain, range, horizontal asymptote and y-intercept of each function, In problems use the transformations to the graph each function. Determine the domain, range, horizontal asymptote and y-intercept of each function, In Problems 55-62, begin with the graph of y= e x (Figure 31) and use transformations to graph each function. Determine the domain, range, and horizontal asymptote of each function. f( x )= e x In Problems 55-62, begin with the graph of y= e x (Figure 31) and use transformations to graph each function. Determine the domain, range, and horizontal asymptote of each function. f(x)= e x In Problems 55-62, begin with the graph of y= e x (Figure 31) and use transformations to graph each function. Determine the domain, range, and horizontal asymptote of each function. f(x)= e x +2 In Problems 55-62, begin with the graph of y= e x (Figure 31) and use transformations to graph each function. Determine the domain, range, and horizontal asymptote of each function. f(x)= e x 1 In Problems 55-62, begin with the graph of y= e x (Figure 31) and use transformations to graph each function. Determine the domain, range, and horizontal asymptote of each function. f(x)=5 e x In Problems 55-62, begin with the graph of y= e x (Figure 31) and use transformations to graph each function. Determine the domain, range, and horizontal asymptote of each function. f(x)=93 e x In Problems 55-62, begin with the graph of y= e x (Figure 31) and use transformations to graph each function. Determine the domain, range, and horizontal asymptote of each function. f(x)=2 e x/2 In Problems 55-62, begin with the graph of y= e x (Figure 31) and use transformations to graph each function. Determine the domain, range, and horizontal asymptote of each function. f(x)=73 e 2x 61AYU 62AYU 63AYU 64AYU 65AYU 66AYU 67AYU 68AYU 69AYU 70AYU 71AYU 72AYU 73AYU 74AYU 75AYU 76AYU 77AYU 78AYU 79AYU 80AYU 81AYU 82AYU 83AYU 84AYU In Problems 89-92, determine the exponential function whose graph is given. 89.In Problems 89-92, determine the exponential function whose graph is given. 90.In Problems 89-92, determine the exponential function whose graph is given. 91.In Problems 89-92, determine the exponential function whose graph is given. 92.89AYU 90AYU 91AYU 92AYU 93AYU 94AYU 95AYU 96AYU 97AYU 98AYU 99AYU 100AYU 105. Optics If a single pane of glass obliterates 3 of the light passing through it, the percent p of light that passes through n successive panes is given approximately by the function p(n)=100 ( 0.97 ) n (a) What percent of fight will pass through 10 panes? (b) What percent of light will pass through 25 panes? (c) Explain the meaning of the base 0.97 in this problem.102AYU 107. Depreciation The price p, in dollars, of a Honda Civic EX-L sedan that is x years old is modeled by p( x )=22,265 ( 0.90 ) x (a) How much should a 3-year-old Civic EX-L sedan cost? (b) How much should a 9-year-old Civic EX-L sedan cost? (c) Explain the meaning of the base 0.90 in this problem.104AYU 105AYU 106AYU 107AYU 108AYU 109AYU 110AYU 117. Relative Humidity The relative humidity is the ratio (expressed as a percent) of the amount of water vapor in the air to the maximum amount that the air can hold at a specific temperature. The relative humidity, R, is found using the following formula: R= 10 ( 4221 T+459.4 4231 D+459.4 +2 ) where T is the air temperature (in F ) and D is the dew point temperature (in F ). (a) Determine the relative humidity if the air temperature is 50 Fahrenheit and the dew point temperature is 41 Fahrenheit. (b) Determine the relative humidity if the air temperature is 68 Fahrenheit and the dew point temperature is 59 Fahrenheit. (c) What is the relative humidity if the air temperature and the dew point temperature arc the same?112AYU 119. Current in an RL Circuit The equation governing the amount of current I (in amperes) after time t (in seconds) in a single RL circuit consisting of a resistance R (in ohms), an inductance L (in henrys), and an electromotive force E (in voles) is I= E R [1 e (R/L)t ] (a) If E=120 volts, R=10 ohms, and L=5 henrys, how much current I1 is flowing after 0.3 second? After 0.5 second? After 1 second? (b) What is the maximum current? (c) Graph this function I= I 1 (t), measuring I along the y-axis and t along the x-axis . (d) If E=120 volts, R=5 ohms, and L=10 henrys, how much current I2 is flowing after 0.3 second? After 0.5 second? After 1 second? (e) What is the maximum current? (f) Graph the function I= I 2 ( t ) on the same coordinate axes as I 1 (t) .120. Current in an RC Circuit The equation governing the amount of current I (in amperes) after lime t (in microseconds) in a single RC circuit consisting of a resistance R (in ohms), a capacitance C (in microfarads), and an electromotive force E (in volts) is I= E R e t/ (RC) (a) If E=120 volts, R=2000 ohms, and C=1.0 microfarad, how much current I1 is flowing initially ( t=0 )? After 1000 microseconds? After 3000 microseconds? (b) What is the maximum current? (c) Graph this function I= I 1 (t), measuring I along the y-axis and t along the x-axis . (d) If E=120 volts, R=1000 ohms, and C=2.0 microfarads, how much current I2 is flowing initially? After 1000 microseconds? After 3000 microseconds? (e) What is the maximum current? (f) Graph the function I= I 2 ( t ) on the same coordinate axes as I 1 (t) .115AYU 116AYU 117AYU 118AYU 119AYU 120AYU 121AYU 122AYU 123AYU 124AYU 125AYU 126AYU 127AYU 128AYU 129AYU Solve each inequality: (a) 3x782x (pp.A79-A80) (b) x 2 x60 (pp.170-172)Solve the inequality: x1 x+4 0 (pp. 245-247)3AYU 4AYU 5AYU 6AYU 7AYU True or False The graph of f(x)=logax , where a0anda1 , has an x-intercept equal to 1 and no y-intercept .In Problems 11-18, change each exponential statement to an equivalent statement involving a logarithm. 9= 3 2 In Problems 11-18, change each exponential statement to an equivalent statement involving a logarithm. 16= 4 2 In Problems 11-18, change each exponential statement to an equivalent statement involving a logarithm. a 2 =1.6 In Problems 11-18, change each exponential statement to an equivalent statement involving a logarithm. a 3 =2.1 In Problems 11-18, change each exponential statement to an equivalent statement involving a logarithm. 2 x =7.2 In Problems 11-18, change each exponential statement to an equivalent statement involving a logarithm. 3 x =4.6 In Problems 11-18, change each exponential statement to an equivalent statement involving a logarithm. e x =8 In Problems 11-18, change each exponential statement to an equivalent statement involving a logarithm. e 2. 2 =M In Problems 19-26, change each logarithmic statement to an equivalent statement involving an exponent. log 2 8=3 In Problems 19-26, change each logarithmic statement to an equivalent statement involving an exponent. log 3 ( 1 9 )=2 In Problems 19-26, change each logarithmic statement to an equivalent statement involving an exponent. log a 3=6 In Problems 19-26, change each logarithmic statement to an equivalent statement involving an exponent. log b 4=2 In Problems 19-26, change each logarithmic statement to an equivalent statement involving an exponent. log 3 2=x In Problems 19-26, change each logarithmic statement to an equivalent statement involving an exponent. log 2 6=x In Problems 19-26, change each logarithmic statement to an equivalent statement involving an exponent. ln4=x In Problems 19-26, change each logarithmic statement to an equivalent statement involving an exponent. lnx=4 In Problems 27-38, find the exact value of each logarithm without using a calculator. log 2 1 In Problems 27-38, find the exact value of each logarithm without using a calculator. log 8 8 In Problems 27-38, find the exact value of each logarithm without using a calculator. log 5 25 In Problems 27-38, find the exact value of each logarithm without using a calculator. log 3 ( 1 9 )In Problems 27-38, find the exact value of each logarithm without using a calculator. log 1/2 16 In Problems 27-38, find the exact value of each logarithm without using a calculator. log 1/3 9 In Problems 27-38, find the exact value of each logarithm without using a calculator. log 10 10 In Problems 27-38, find the exact value of each logarithm without using a calculator. log 5 25 3 In Problems 27-38, find the exact value of each logarithm without using a calculator. log 2 4 In Problems 27-38, find the exact value of each logarithm without using a calculator. log 3 9 In Problems 27-38, find the exact value of each logarithm without using a calculator. ln e In Problems 27-38, find the exact value of each logarithm without using a calculator. ln e 3 In Problems 39â€”50, find the domain of each function. f(x)=ln(x3)38AYU In Problems 39â€”50, find the domain of each function. F(x)= log 2 x 2

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