A random sample of size 36 is taken from a population with mean µ = 17 and standard deviation σ = 4. The probability that the sample mean is greater than 18 is ________.
a. 0.8413
b. 0.0668
c. 0.1587
d. 0.9332

The survey of 400 doctors represents the sample size. The sample size is the number of subjects that are part of a statistical study or experiment.

A sample size is calculated through a formula that considers the variability of the population, the size of the error margin, and the level of confidence. In this particular problem, the survey has already been conducted, and the sample size is given in the question.

A larger sample size is generally preferred because it is more representative of the population and has a smaller margin of error.

A smaller sample size, on the other hand, may not accurately reflect the population's characteristics and can result in unreliable data.

It's important to note that the sample size should be determined based on the research question and objectives, and there are various methods to determine the appropriate sample size, depending on the study design.

To learn more about experiment visit;

https://brainly.com/question/17314369

#SPJ11

P(77 < X < 122) = 0.85.

To find the probability of a range of values in a normal distribution, we need to calculate the area under the curve between those values. In this case, we want to find the probability that X falls between 77 and 122.

First, we need to standardize the values by converting them into z-scores. The formula for calculating the z-score is (X - μ) / σ, where X is the value, μ is the mean, and σ is the standard deviation.

For 77, the z-score is (77 - 98) / 18 = -1.17, and for 122, the z-score is (122 - 98) / 18 = 1.33.

Using a standard normal distribution table or calculator, we can find that the area to the left of -1.17 is 0.121 and the area to the left of 1.33 is 0.908. To find the area between the two z-scores, we subtract the smaller area from the larger area: 0.908 - 0.121 = 0.787.

Therefore, P(77 < X < 122) = 0.787, rounded to 2 decimal places, is 0.79.

To learn more about normal distribution click here : brainly.com/question/31327019

#SPJ11

The quadratic and cubic approximations of the function f(x, y) = 5 sin(x) cos(y) near the origin can be obtained using Taylor's formula. The quadratic approximation of f(x, y) at the origin can be written as:

[tex]Q(x, y) = f(0, 0) + f_x(0, 0)x + f_y(0, 0)y + (1/2)f_xx(0, 0)x^2 + (1/2)f_yy(0, 0)y^2 + f_xy(0, 0)xy[/tex],

The quadratic approximation of f(x, y) at the origin :

[tex]Q(x, y) = f(0, 0) + f_x(0, 0)x + f_y(0, 0)y + (1/2)f_xx(0, 0)x^2 + (1/2)f_yy(0, 0)y^2 + f_xy(0, 0)xy[/tex]where[tex]f_x, f_y, f_{xx}, f_{yy[/tex], and[tex]f_{xy[/tex]denote the partial derivatives of f with respect to x and y.

In this case, f(0, 0) = 0, and the partial derivatives at the origin are[tex]f_x(0, 0) = 0, f_y(0, 0) = 5, f_{xx}(0, 0) = 0, f_{yy}(0, 0) = -5,[/tex] and [tex]f_{xy}(0, 0) = 0[/tex]. Plugging these values into the formula, the quadratic approximation becomes:

Q(x, y) = 5y - (5/2)y².

The cubic approximation of f(x, y) at the origin can be obtained by including the third-order terms in the Taylor's formula. However, since the function f(x, y) = 5 sin(x) cos(y) does not have any third-order derivatives at the origin, the cubic approximation will be zero.

To summarize, the quadratic approximation of f(x, y) near the origin is Q(x, y) = 5y - (5/2)y², while the cubic approximation is zero due to the absence of third-order derivatives. These approximations provide an estimation of the function's behavior in the vicinity of the origin.

Learn more about partial derivatives here: https://brainly.com/question/28751547

#SPJ11

the correct answer OF separable differential equation  is:

a. In (x-2) + (In y)² + C

To solve the separable differential equation given as:

In y dx + dy = 0

x-2 y

Let's separate the variables and integrate:

∫ In y dy + ∫ dx = ∫ 0 (x-2) dx

Integrating the left-hand side:

∫ In y dy = y In y - y

Integrating the right-hand side:

∫ 0 (x-2) dx = ∫ 0 x dx - 2 ∫ 0 dx

               = 1/2 x² - 2x + C

Combining the integrals and simplifying:

y In y - y = 1/2 x² - 2x + C

Rewriting the equation in exponential form:

y * e^(In y - 1) = e^(1/2 x² - 2x + C)

Simplifying further:

y * e^(In y - 1) = e^(1/2 x² - 2x) * e^C

y * (e^(In y) * e^(-1)) = C * e^(1/2 x² - 2x)

Since C is an arbitrary constant, we can write C = e^C.

Simplifying the equation:

y * y^(-1) = e^(1/2 x² - 2x) * e^C

y² = e^(1/2 x² - 2x) * e^C

y² = C * e^(1/2 x² - 2x)

Taking the square root of both sides:

y = ±√(C * e^(1/2 x² - 2x))

Therefore, the general solution of the given differential equation is:

y = ±√(C * e^(1/2 x² - 2x))

Comparing this solution with the given options, we can see that the correct answer is: a. In (x-2) + (In y)² + C

To know more about differential equation,

https://brainly.com/question/32538700#

#SPJ11

The parametric equation of the plane is,

`x = 2 + 3t`,

`y = 1 + 2t` and

`z = t`.

Given that the point A(2, 1, 0), B(-2, -5, 0), C(2, 1, 0) and D(0, 3, -2).

To find the parametric equation of the plane connecting point A to B and point C to D,

follow the steps below:

Step 1:

Find the vector AB

Let `r` be the position vector of any point on the plane connecting A and B.

Then the vector AB = `OB - OA`,

where `OA` is the position vector of the point A and `OB` is the position vector of the point B.

So, vector AB = `<-2, -5, 0> - <2, 1, 0>`

= `<-2-2, -5-1, 0-0>`

= `<-4, -6, 0>`

Step 2:

Find the vector CD

Let `r` be the position vector of any point on the plane connecting

C and D.

Then the vector CD = `OD - OC`,

where `OC` is the position vector of the point C and `OD` is the position vector of the point D.

So, vector CD = `<0, 3, -2> - <2, 1, 0>`

= `<0-2, 3-1, -2-0>`

= `<-2, 2, -2>`

Step 3:

Find the normal vector N of the plane

The normal vector N of the plane connecting A and B, and C and D is the cross product of vectors AB and CD.

N = AB × CD= `<-4, -6, 0>` × `<-2, 2, -2>`

= `<(-6)(-2) - 0(2), 0(-2) - (-4)(-2), (-4)(2) - (-6)(-2)>`

= `<12, 8, -8>`

Step 4:

Write the parametric equation of the plane

Let P(x, y, z) be any point on the plane connecting A to B and C to D.

Then the vector connecting A to P is given by `r - OA`.

This vector and the normal vector N are perpendicular.

Therefore, their dot product is zero.

So, `N · (r - OA) = 0`

=> `12(x - 2) + 8(y - 1) - 8(z - 0) = 0`

=> `12x + 8y - 8z - 8 = 0`

=> `3x + 2y - 2z - 2 = 0`

This is the required parametric equation of the plane connecting point (2, 1, 0) to point (-2, -5, 0), and point (2, 1, 0) to point (0, 3, -2).

Therefore, the parametric equation of the plane is `x = 2 + 3t`,

`y = 1 + 2t` and

`z = t`.

To know more about parametric equation, visit:

https://brainly.com/question/30748687

#SPJ11

Part 1: The value of function, f(x) = 90 * 1.4^x

Part 2:

a. The initial concentration of the drug in the organ is 0.07 mg/cm³.

b. The concentration of the drug in the organ after 17 seconds is approximately 0.1153 mg/cm³.

Part 1: Finding the function f(x) = Ae^(kx) given f(0) and f(1)

We are given that f(0) = 90 and f(1) = 126. We can use these values to form a system of equations and solve for the constants A and k.

Substituting x = 0 and f(0) = 90 into the function f(x), we have:

90 = Ae^(k*0)

90 = A

Substituting x = 1 and f(1) = 126 into the function f(x), we have:

126 = Ae^(k*1)

126 = Ae^k

Now, we can solve these two equations simultaneously:

A = 90 (from the first equation)

126 = 90e^k

Dividing both sides of the second equation by 90, we have:

e^k = 126/90

e^k = 1.4

Taking the natural logarithm (ln) of both sides, we get:

k = ln(1.4)

Therefore, the function f(x) = Ae^(kx) becomes:

f(x) = 90e^(ln(1.4)x)

f(x) = 90 * 1.4^x

Part 2: Absorption of Drugs

(a) Initial concentration of the drug in the organ:

Given the equation x(t) = 0.07 + 0.18(1 - e^(-0.017)), we need to find x(0) which represents the initial concentration.

Substituting t = 0 into the equation, we have:

x(0) = 0.07 + 0.18(1 - e^(-0.017 * 0))

x(0) = 0.07 + 0.18(1 - e^0)

x(0) = 0.07 + 0.18(1 - 1)

x(0) = 0.07 + 0.18(0)

x(0) = 0.07

Therefore, the initial concentration of the drug in the organ is 0.07 mg/cm³.

(b) Concentration of the drug in the organ after 17 seconds:

We need to find x(17) using the given equation x(t) = 0.07 + 0.18(1 - e^(-0.017)).

Substituting t = 17 into the equation, we have:

x(17) = 0.07 + 0.18(1 - e^(-0.017 * 17))

x(17) = 0.07 + 0.18(1 - e^(-0.289))

x(17) = 0.07 + 0.18(1 - 0.748214)

x(17) = 0.07 + 0.18(0.251786)

x(17) = 0.07 + 0.04532268

x(17) ≈ 0.1153

Therefore, the concentration of the drug in the organ after 17 seconds is approximately 0.1153 mg/cm³.

To learn more about function: https://brainly.com/question/11624077

#SPJ11

The solution is x1 = 14, x2 = 5, and x3 = 6. Hence, the correct choice is:

a. The unique solution is x1 = 14, x2 = 5, and x3 = 6.

To find the number of each type of tank car that should be leased, we can set up a system of equations based on the given information.

Let x1 be the number of cars with a 7,000-gallon capacity, x2 be the number of cars with a 14,000-gallon capacity, and x3 be the number of cars with a 28,000-gallon capacity.

Based on the carrying capacity information, we can write the following equations:

Equation 1: x1 + x2 + x3 = 25 (Total number of tank cars)

Equation 2: 7,000x1 + 14,000x2 + 28,000x3 = 406,000 (Total carrying capacity in gallons)

To solve this system of equations, we can use substitution or elimination methods.

Using the elimination method, we can multiply Equation 1 by 7,000 to match the units of Equation 2:

7,000(x1 + x2 + x3) = 7,000(25)

7,000x1 + 7,000x2 + 7,000x3 = 175,000

Now we have the following equations:

Equation 3: 7,000x1 + 7,000x2 + 7,000x3 = 175,000

Equation 2: 7,000x1 + 14,000x2 + 28,000x3 = 406,000

Subtracting Equation 3 from Equation 2, we get:

7,000x1 + 14,000x2 + 28,000x3 - (7,000x1 + 7,000x2 + 7,000x3) = 406,000 - 175,000

7,000x2 + 21,000x3 = 231,000

Now we have the following equations:

Equation 4: 7,000x2 + 21,000x3 = 231,000

Equation 1: x1 + x2 + x3 = 25

We now have a system of two equations with two unknowns (x2 and x3). By solving this system, we can find the values of x2 and x3, and then determine x1 using Equation 1.

Solving the system of equations, we find:

x2 = 5

x3 = 6

Substituting these values back into Equation 1:

x1 + 5 + 6 = 25

x1 = 14

Therefore, the solution is x1 = 14, x2 = 5, and x3 = 6.

Hence, the correct choice is:

a. The unique solution is x1 = 14, x2 = 5, and x3 = 6.

for such more question on number

https://brainly.com/question/859564

#SPJ8

To derive the demand functions for goods X and Y, we will use the concept of utility maximization subject to the budget constraint.

First, let's set up the optimization problem by maximizing utility subject to the budget constraint: max U(X, Y) subject to PxX + PyY = M.

To find the demand function for good X, we need to solve for X in terms of Y. Taking the derivative of the utility function with respect to X and setting it equal to the price ratio, we have MUx / MUy = Px / Py. Substituting the given marginal utility functions, we get 2X^(-0.8)Y^(-0.8) / (8X^0.2Y^(-0.2)) = Px / Py. Simplifying the equation, we have X^(-1) / (4Y) = Px / Py, which implies X = (4PxY)^(0.25).

Similarly, to find the demand function for good Y, we need to solve for Y in terms of X. Taking the derivative of the utility function with respect to Y and setting it equal to the price ratio, we have MUy / MUx = Py / Px. Substituting the given marginal utility functions, we get 8X^0.2Y^(-0.2) / (2X^(-0.8)Y^(-0.8)) = Py / Px. Simplifying the equation, we have Y^(0.25) / (4X) = Py / Px, which implies Y = (4PyX)^(0.25).

Therefore, the demand functions for goods X and Y are X = (4PxY)^(0.25) and Y = (4PyX)^(0.25), respectively. These equations represent the optimal quantities of goods X and Y that maximize utility, given the budget constraint and the prices of the goods.

Learn more about function here: brainly.com/question/30721594

#SPJ11

The given function is continuous. The graph will be a smooth curve without any jumps or holes.

The given function is continuous. The given function is f(x) = 8x² - 1. The continuous functions are those functions that do not have any kind of breaks, jumps, or holes in their graphs.

Therefore, continuous functions can be drawn without lifting a pencil from the paper.In this case, the given function is a polynomial function, so it is continuous on the whole real line.

Hence, the given function is continuous.You can verify this conclusion by graphing the function on a graphing utility such as Desmos, Wolfram Alpha, or GeoGebra. The graph will be a smooth curve without any jumps or holes.

To know more about curve visit:

https://brainly.com/question/28789772

#SPJ11

The given function is continuous.What is a continuous function?

A function is said to be continuous if its graph is an unbroken curve without any jumps or gaps.

A continuous function is one whose graph can be drawn without taking your pen off of the paper and without any breaks, jumps, or holes.

In the case of the function f(x) = 8x² - 1, it can be seen that there are no asymptotes or any breaks in the graph. As a result, it can be concluded that the function is continuous.

As per the given question, we are also asked to verify this conclusion by graphing the function with a graphing utility, which further supports our claim that the given function is continuous.

https://brainly.com/question/31062578

#SPJ11

The trace of the linear transformation L on V, defined by L(X) = (AX + XAY), can be calculated as the trace of the matrix A. In this case, since A is a 2x2 diagonal matrix with diagonal entry 2, the trace of L is 4.

The linear transformation L on V is defined by L(X) = (AX + XAY), where X is a 2x2 matrix and A is a diagonal matrix. To calculate the trace of L, we need to find the trace of the resulting matrix when L is applied to X.

Let's consider an arbitrary 2x2 matrix X:

X = | a b |

| c d |

We can now apply L to X:

L(X) = (AX + XAY)

= AX + XA*Y

To calculate the product A*X, we multiply each entry of A by the corresponding entry of X:

A*X = | 2a 0 |

| 0 2d |

Similarly, the product XAY is obtained by multiplying each entry of X by the corresponding entry of A*Y:

XAY = | a b | * | 2b 0 |

| c d | | 0 2c |

Multiplying these matrices and summing the entries, we get:

L(X) = | 2a + 2b² 2b² |

| 2c 2c + 2d² |

The trace of a matrix is the sum of its diagonal entries. In this case, the diagonal entries of L(X) are 2a + 2b² and 2c + 2d². So the trace of L(X) is:

Trace(L(X)) = 2a + 2b² + 2c + 2d²

Since the matrix A is diagonal with diagonal entry 2, the trace of A is 2. Therefore, the trace of the linear transformation L is:

Trace(L) = 2 + 2 = 4 Hence, the trace of L is 4.

To learn more about linear.

Click here:brainly.com/question/31510530?

#SPJ11

The general solution for y is y = C1e^(-4x/3) + C2e^0 - sin(t)/3, from y(0) = 0, we find C1 + C2 = 0.

The given system of differential equations is:

D^2x - 2D(D+1)y = sin(t),

Dy + x = 0,

with initial conditions x(0) = 0, x'(0) = 1/5, and y(0) = 0.

To solve this system, we can start by solving the second equation for y in terms of x. Differentiating the equation Dy + x = 0, we get: D^2y + Dx = 0.

Since we have the expression D^2y in terms of Dx, we can substitute this into the first equation: (Dx - 2D(D+1)y) - 2(D(D+1)y) = sin(t).

Simplifying, we get: Dx - 4D(D+1)y = sin(t).

Now we have a single differential equation involving only x and y. To solve this, we can find the homogeneous solution and the particular solution.

For the homogeneous solution, we assume y = e^mx, where m is a constant. Substituting this into the equation, we get: m^2x - 4m(m+1)x = 0.

Simplifying, we have:

(m^2 - 4m^2 - 4m)x = 0,

-3m^2 - 4m = 0.

This gives us two possible values for m: m = 0 or m = -4/3.

For the particular solution, we assume y = Ax + B, where A and B are constants. Substituting this into the equation, we get: A - 4A = sin(t).

Solving for A, we find A = -sin(t)/3.

Therefore, the general solution for y is:

y = C1e^(-4x/3) + C2e^0 - sin(t)/3,

where C1 and C2 are constants determined by the initial conditions.

To find the solution for x, we integrate the second equation with respect to t: x = -∫y dt.

Substituting the expression for y, we have:

x = -∫(C1e^(-4t/3) + C2 - sin(t)/3) dt.

Integrating, we obtain:

x = -C1e^(-4t/3) - C2t + cos(t)/3 + D,

where D is a constant of integration.

Now we can apply the initial conditions to determine the values of the constants. From x(0) = 0, we find D = C2. From x'(0) = 1/5, we have -4/3C1 - C2 + 1/3 = 1/5. Finally, from y(0) = 0, we find C1 + C2 = 0.

Solving these equations simultaneously, we can determine the values of C1 and C2, which will give us the specific solution for the given initial conditions.

To know more about equation click here

brainly.com/question/649785

#SPJ11

1) cos 15° is the exact value of sin(-105°) using a sum or difference identity.

2) sin 15° is the exact value of cos(285°) using a sum or difference identity.

3) The exact value of sin(u + v) is 33/65.

4) The exact value of cos(u - v) is -16/65.

5) The exact value of tan(u + v) is -17/23.

6) The exact value of csc(u - v) is 3/5.

7) The exact value of the expression is (1 + √3)/8.

8) The exact value of the expression is -7/6.

1. The given function is sin(-105°).

The following sum or difference identity can be used for this expression.

sinq-r = sin q cos r - cos q sin r

Since we need to determine sin(-105°) = -sin105°, and sin105° is a first-quadrant value that can be calculated using a calculator,

    we use the identity with q = 15°

                                        and r = 90°.

Therefore,

                  -sin 105° = -sin(90°+15°)

                                 = -sin 90° cos 15° - cos 90° sin 15°

                                  = -cos 15°

Answer: cos 15° is the exact value of sin(-105°) using a sum or difference identity.

2. The given function is cos(285°).

The following sum or difference identity can be used for this expression.

                cosq-r = cos q cos r + sin q sin r

Since we need to determine cos(285°) = cos(360°-75°), and cos 75° is a second-quadrant value that can be calculated using a calculator,

we use the identity with

                             q = 15°

                       and r = 90°.

Therefore,

               cos 75° = cos(90° - 15°)

                           = cos 90° cos 15° + sin 90° sin 15°

                            = 0 cos 15° + 1 sin 15°

                             = sin 15°

Answer: sin 15° is the exact value of cos(285°) using a sum or difference identity.

3. sin(u + v) = sin u cos v + cos u sin v

We are given,

                    sin u = 5/13

             and cos v = -3/5

Therefore,

               sin(u + v) = sin u cos v + cos u sin v

                              = (5/13) (-3/5) + (12/13) (4/5)

                               = -15/65 + 48/65

                               = 33/65

Answer: The exact value of sin(u + v) is 33/65.

4. cos(u - v) = cos u cos v + sin u sin v

We are given

                      sin u = 5/13

             and cos v = -3/5

Therefore,

                cos(u - v) = cos u cos v + sin u sin v

                                 = (12/13) (-3/5) + (5/13) (4/5)

                                 = -36/65 + 20/65

                                 = -16/65

Answer: The exact value of cos(u - v) is -16/65.

5. tan(u + v) = (tan u + tan v) / (1 - tan u tan v)

We are given sin u = 5/13

               and cos v = -3/5

Therefore,

          tan(u + v) = (tan u + tan v) / (1 - tan u tan v)

                          = (5/12 - 4/3) / (1 - 5/12 * -4/3)

                          = (-17/12) / (23/12)

                            = -17/23

Answer: The exact value of tan(u + v) is -17/23.

6. csc(u - v) = csc u csc v + cot u cot v

We are given

                      sin u = 5/13

                      cos v = -3/5

Therefore,

             csc(u - v) = csc u csc v + cot u cot v

                             = (13/5) (-5/3) + (12/5) (4/3)

                             = -39/15 + 48/15

                             = 9/15

                                = 3/5

Answer: The exact value of csc(u - v) is 3/5.

7. sinπ/12cosπ/4+cosπ/12sinπ/4= (1/4)(sin(π/12 + π/4) + sin(π/4 - π/12))

                                                    = (1/4)(sin(π/3) + sin(π/6))

                                                    = (1/4)(√3/2 + 1/2)

                                                     = √3/8 + 1/8

                                                      = (1 + √3)/8

Answer: The exact value of the expression is (1 + √3)/8.

8. (tan 25°+ tan 110°)/1- tan 25° tan 110°

We can use the following identity to solve the given expression.

tan(a + b) = (tan a + tan b) / (1 - tan a tan b)

Let a = 25

      b = 110,

then,

(tan 25°+ tan 110°)/1- tan 25° tan 110°= tan (25° + 110°) / (1 - tan 25° tan 110°)

                                                             = tan 135° / (1 - tan 25° tan 110°)

                                                              = -1 / (1 - (-1/7))

                                                                = -7/6

Answer: The exact value of the expression is -7/6.

To know more about first-quadrant, visit:

https://brainly.com/question/29556891

#SPJ11

To show that A is similar to Ak for each k = 1, 2, 3, ..., we need to demonstrate that there exists an invertible matrix P such that[tex]P^{-1}AP = Ak[/tex].

Given that λ = 1 is the only eigenvalue of matrix A, it implies that the characteristic polynomial of [tex]A = (\lambda - 1)^n[/tex], where n is the size of matrix A (since the eigenvalues are the roots of the characteristic polynomial). Since the only eigenvalue is 1, we can deduce that the algebraic multiplicity of λ = 1 is n.

Now, let's consider the Jordan canonical form of matrix A. Since the only eigenvalue is 1, the Jordan canonical form will consist of Jordan blocks with eigenvalue 1. Each Jordan block corresponds to an eigenvector associated with the eigenvalue 1.

In the Jordan canonical form, the blocks corresponding to eigenvalue 1 will have the form:

[tex]Jk=\begin{bmatrix}1 & 1 & 0 & 0 & \dots & 0 \\0 & 1 & 1 & 0 & \dots & 0 \\0 & 0 & 1 & 1 & \dots & 0 \\0 & 0 & 0 & 1 & \dots & 0 \\\vdots & \vdots & \vdots & \vdots & \ddots & \vdots \\0 & 0 & 0 & 0 & \dots & 1 \\\end{bmatrix}[/tex]

where k is the size of the Jordan block.

We can see that for each k, Ak will have a block diagonal form consisting of k Jordan blocks Jk. The diagonal blocks of Ak will be:

[tex]Ak=\begin{bmatrix}Jk & 0 & 0 & \dots & 0 \\0 & Jk & 0 & \dots & 0 \\0 & 0 & Jk & \dots & 0 \\\vdots & \vdots & \vdots & \ddots & \vdots \\0 & 0 & 0 & \dots & Jk \\\end{bmatrix}[/tex]

Now, we can define the matrix P as the block diagonal matrix formed by stacking the eigenvectors corresponding to the Jordan blocks:

[tex]P=\begin{bmatrix}v_1 & 0 & 0 & \dots & 0 \\0 & v_2 & 0 & \dots & 0 \\0 & 0 & v_3 & \dots & 0 \\\vdots & \vdots & \vdots & \ddots & \vdots \\0 & 0 & 0 & \dots & v_k \\\end{bmatrix}[/tex]

where v1, v2, v3, ..., vk are the eigenvectors associated with the Jordan blocks J1, J2, J3, ..., Jk, respectively.

It can be shown that [tex]P^{-1}AP = Ak[/tex], which means that A is similar to Ak for each k = 1, 2, 3, ....

This similarity transformation demonstrates that A can be transformed into Ak through a change of basis using the matrix P.

Answer: A is similar to Ak for each k = 1, 2, 3, ...

To know more about Matrix visit-

brainly.com/question/28180105

#SPJ11

Using substitution method, the cost of hotel per night is $ 85

Let hotel cost per night = x

Let car rental per day = y

4x + 2y = 500 ____(1)

4x + 5y = 740 ____(2)

Solving for x in the equation

Equation (1) - (2)

-3y = - 240

y = 80

Substitute the value of y in (1)

4x + 2(80) = 500

4x + 160 = 500

4x = 500-160

4x = 340

x = $85

Therefore, hotel cost per night is $85

Learn more on equations ; https://brainly.com/question/148035

#SPJ1

The critical value for a right-tailed test with α = 0.025, degrees of freedom in the numerator= 15, and degrees of freedom in the denominator = 25 is 2.602.

Step 1: Determine the alpha level.α = 0.025

Step 2: Look up the degrees of freedom in the numerator (dfn) and the degrees of freedom in the denominator (dfd) in the t-distribution table with alpha level α of 0.025, a right-tailed test.

Critical value = 2.602 (approximately)Therefore, the critical value for a right-tailed test with α = 0.025, degrees of freedom in the numerator= 15, and degrees of freedom in the denominator = 25 is 2.602.

The critical value for a right-tailed test with α = 0.025, degrees of freedom in the numerator= 15, and degrees of freedom in the denominator = 25 is 2.602. The critical value of a test statistic is defined as the minimum value of the test statistic that must be exceeded to reject the null hypothesis. If the calculated test statistic is greater than the critical value, the null hypothesis is rejected.

To know more about right-tailed test, visit:

brainly.com/question/14502783

#SPJ11

Therefore, there are 14,850 different committees that can be formed from 6 teachers and 45 students if the committee consists of 4 teachers and 2 students.

To determine the number of different committees that can be formed, we will use the combination formula.

The number of ways to choose 4 teachers out of 6 is given by C(6, 4) which can be calculated as:

C(6, 4) = 6! / (4!(6-4)!) = 6! / (4!2!) = (6 * 5) / (2 * 1) = 15

Similarly, the number of ways to choose 2 students out of 45 is given by C(45, 2) which can be calculated as:

C(45, 2) = 45! / (2!(45-2)!) = 45! / (2!43!) = (45 * 44) / (2 * 1) = 990

To form a committee consisting of 4 teachers and 2 students, we multiply the number of ways to choose the teachers and the number of ways to choose the students:

Total number of committees = C(6, 4) * C(45, 2) = 15 * 990 = 14,850

To know more about different committees,

https://brainly.com/question/29166199

#SPJ11

The volume of the given rectangular prism is 396 cubic kilometer.

From the given figure,

Length = 9 km, Breadth=4 km and Height=11 km

We know that, the formula to find the volume of a rectangular prism is Length×Breadth×Height.

Here, volume = 9×4×11

= 396 cubic kilometer

Therefore, the volume of the given rectangular prism is 396 cubic kilometer.

To learn more about the volume visit:

https://brainly.com/question/13338592.

#SPJ1

"Your question is incomplete, probably the complete question/missing part is:"

Find the volume of the figure. Round your answers to the nearest hundredth, if necessary. (Figure is attached below).

The probability is 1/56, or approximately 0.0179. To calculate the probability that a randomly selected customer ordered wine and pasta, we need to determine the number of customers who ordered wine and pasta,and divide it by the total number of customers.

From the given data, we can see that there are 10 customers who ordered wine and 1 customer who ordered pasta.

Total number of customers = 3 + 1 + 3 + 12 + 5 + 16 + 3 + 10 + 3 = 56

Therefore, the probability that a randomly selected customer ordered wine and pasta is:

P(Wine and Pasta) = Number of customers who ordered wine and pasta / Total number of customers

                 = 1 / 56

So, the probability is 1/56, or approximately 0.0179.

To know more about Probability visit-

brainly.com/question/31828911

#SPJ11

The  probability that the change in heart rate of a randomly selected subject is below 8.3 beats per minute is approximately 0.4641 or 0.46411. option C

We'll use the standard normal distribution to find this probability.

Step 1: Standardize the value of 8.3 using the formula:

z = (x - μ) / σ

z = (8.3 - 7.3) / 11.1

z ≈ 0.09009

Look up the cumulative probability corresponding to the standardized value z using a standard normal distribution table or calculator.

From the standard normal distribution table, the cumulative probability for z ≈ 0.09009 is approximately 0.4641 or 0.46411.

Therefore, the probability that the change in heart rate of a randomly selected subject is below 8.3 beats per minute is approximately 0.4641 or 0.46411.

Learn more about probability at https://brainly.com/question/13604758

#SPJ4

1) The values of A and B are, A = 2, B = 7

Since A>B, we enter "-7" into the calculator.

2) Since both roots are the same, the general solution is of the form:

y = (C₁ + C₂x) exp(-4x)

So we enter "-4" into the calculator.

3) A = 8 ± 2i and B = 8, and C₁ = -C₂.

Now, For the first equation, we can assume that the solution is of the form:

y = C₁ exp(Ax) + C₂ exp(Bx)

where A and B are constants to be determined.

To find A and B, we first need to find the characteristic equation, which is obtained by substituting y = exp(mx) into the differential equation.

Doing so, we get:

m² - 9m + 14 = 0

Solving this quadratic equation, we get:

m₁ = 2

m₂ = 7

Therefore, the general solution is of the form:

⇒ y = C₁ exp(2x) + C₂ exp(7x)

Comparing this with the assumed form, we see that: A = 2, B = 7

Since A>B, we enter "-7" into the calculator.

For the second equation, we can assume that the solution is of the form:

y = (C₁ + C₂x) exp(Ax)

To find A, we first need to find the characteristic equation, which is obtained by substituting y = exp(mx) into the differential equation.

we get:

m² + 8m + 16 = 0

Solving this quadratic equation, we get:

m₁ = -4

m₂ = -4

Since both roots are the same, the general solution is of the form:

y = (C₁ + C₂x) exp(-4x)

So we enter "-4" into the calculator.

For third equation,

we can start by finding the first and second derivative of y.

First derivative:

y' = (A exp(Ax))[(C₁ cos(Bx) + C₂ sin(Bx))] + exp(Ax) [(-C₁B sin(Bx) + C₂B cos(Bx))]

Second derivative:

y'' = (A exp(Ax))[(C₁ cos(Bx) + C₂ sin(Bx))] + (2A exp(Ax))[(-C₁B sin(Bx) + C₂B cos(Bx))] + (exp(Ax))[(-C₁B cos(Bx) - C₂B sin(Bx))]

Now, we can substitute these expressions into the given differential equation:

(y'') + (-16y') + (68y) = 0

((A exp(Ax))[(C₁ cos(Bx) + C₂ sin(Bx))] + (2A exp(Ax))[(-C₁B sin(Bx) + C₂B cos(Bx))] + (exp(Ax))[(-C₁B cos(Bx) - C₂B sin(Bx))]) - 16((A exp(Ax))[(C₁ cos(Bx) + C₂ sin(Bx))] + exp(Ax) [(-C₁B sin(Bx) + C₂B cos(Bx))]) + 68((exp (Ax))[(C₁)cos (Bx) + (C₂) sin(Bx)]) = 0

Now, we can collect like terms;

(A - 16A + 68) exp(Ax) [(C₁ cos(Bx) + C₂ sin(Bx))] + (2AB - 16B) exp(Ax) [(-C₁sin(Bx) + C₂ cos(Bx))] + (-B C₁ - B C₂) exp(Ax) [(cos(Bx) + sin(Bx))] = 0

Since the expression is true for all values of x, we can equate the coefficients of each term to zero.

This gives us the following system of equations:

A - 16A + 68 = 0

2AB - 16B = 0

-B(C1 + C2) = 0

Solving the first equation, we get:

A = 8 ± 2i

Solving the second equation, we get:

B = 8

Substituting these values into the third equation, we get:

C₁ + C₂ = 0

Therefore, A = 8 ± 2i and B = 8, and C₁ = -C₂.

Learn more about systems of equations at:

brainly.com/question/14323743

#SPJ4

The probability from part (a) is more relevant when considering the comfort and safety of passengers because it shows the proportion of male passengers who will not need to bend when entering the aircraft. Women are not specifically considered in this case, but a separate statistical analysis should be carried out for the case of women to ensure their comfort and safety as well.

(a) The probability from part (a) is more relevant when considering the comfort and safety of passengers because it provides information about the proportion of male passengers who can fit through the doorway without bending. This probability helps assess the ease of access for male passengers and indicates the likelihood of them experiencing any discomfort or safety issues due to the door height. By knowing this probability, appropriate measures can be taken to ensure the convenience and well-being of male passengers.

(b) The probability from part (b) is not directly related to the comfort and safety of passengers. It calculates the probability that the mean height of the 200 men is less than the door height. While this information may be of interest for statistical analysis or research purposes, it does not directly address the comfort and safety concerns of passengers during boarding.

To learn more about probability click here: brainly.com/question/31828911

#SPJ11

Note that the complete solution set of x²-3x = 4 is x = 4, -1.

To find   the two possible values of x²-3x,we need to solve the equation |x²-3x| = 4.

We found that the two possible   values are x = 4   and x = - 1.

Using the positive value, we can write the equation x²-3x = 4 and solve it using factoring -

x²-3x - 4 = 0

(x-4)(x+1) = 0

From this, we get two solutions - x = 4 and x = -1.

Using the negative value, we can write the equation x²-3x = -4 and solve it using the quadratic formula  -

x²-3x + 4 = 0

Using the quadratic formula  -  x = (-(-3) ± √((-3)² - 4(1)(4))) / (2(1))

Simplifying, we get - x = (3 ± √(9 - 16)) / 2

Since the discriminant is negative, there are no real solutions. Therefore, there are no real number solutions for x in this case.

Hence, the complete solution set of x²-3x = 4 is x = 4, -1.

Learn more about solution set:
https://brainly.com/question/10588366
#SPJ4

The set S is a subspace of V = R3 [x].

In the given question, we are dealing with a vector space V = R3 [x], which represents the set of polynomials with coefficients from the field of real numbers. The set S is defined as the span of five polynomials: f1, f2, f3, f4, and f5.

To determine if S is a subspace of V, we need to verify three conditions: closure under addition, closure under scalar multiplication, and containing the zero vector.

Firstly, closure under addition means that for any two polynomials in S, their sum must also be in S. Since the sum of polynomials is a polynomial itself, this condition is satisfied.

Secondly, closure under scalar multiplication states that for any polynomial in S and any scalar c, the scalar multiple of the polynomial must also be in S. Again, since multiplying a polynomial by a scalar yields another polynomial, this condition holds true.

Lastly, S must contain the zero vector, which is the polynomial where all coefficients are zero. In this case, the zero vector is the polynomial 0. As S is a span of polynomials, it contains all linear combinations of its generating polynomials, including the zero vector.

In conclusion, the set S, defined as the span of f1, f2, f3, f4, and f5, is indeed a subspace of the vector space V = R3 [x] because it satisfies all three conditions for a subspace.

Learn more about subspace

brainly.com/question/32720751

#SPJ11

The equation of the parabola that has its focus 13 at (-51,-1) -1) and has directrix. = 4 is (x + 51)² = -11(y – 3/2). Answer is therefore (x + 51)² = -11(y – 3/2).

The given focus of the parabola is (−51, −1) and the given directrix of the parabola is y = 4. We know that for a parabola, the distance between the point and the directrix is equal to the distance between the point and the focus. Therefore, using the formula, we can find the equation of the parabola whose focus and directrix are given.

Let P(x, y) be any point on the parabola. Let F be the focus and l be the directrix. Draw a perpendicular line from point P to the directrix l. Let this line intersect l at a point Q. The distance between point P and the directrix is PQ, and the distance between point P and the focus is PF. Using the distance formula, we can write:

PF = √[(x − x₁)² + (y − y₁)²]PQ = |y − k|

where (x₁, y₁) is the coordinates of the focus, k is the distance between the vertex and the directrix, and the absolute value is taken to ensure that PQ is positive. Since the parabola is equidistant from the focus and directrix, we have:

PF = PQ √[(x − x₁)² + (y − y₁)²] = |y − k|

The equation of the parabola is of the form (x – h)^2 = 4p(y – k).We can write the above equation in terms of the distance between the vertex and the directrix, which is given by k = 4p/(1).Thus, the equation of the parabola is             (x – h)² = 4p(y – k) = 4p(y – 4p) = 16p(y – 4).

The vertex of the parabola is equidistant from the focus and directrix, so the vertex is halfway between the focus and directrix. Therefore, the vertex has coordinates (−51, 3/2).The distance between the vertex and the focus is p, so we have: p = (distance between vertex and focus)/4 = (-2.5 - 3/2)/4 = -11/16.

Substituting this value of p and the coordinates of the vertex into the equation of the parabola, we get:(x + 51)² = -44/16(y – 3/2) ⇒ (x + 51)² = -11(y – 3/2).

More on parabola: https://brainly.com/question/11911877

#SPJ11

The differential equation of the form x"(t) - 10x'(t) + 25x(t) = 3te5 can be solved by the method of undetermined coefficients. The method of undetermined coefficients is applied to obtain a particular solution to the given differential equation.

Firstly, the characteristic equation of the differential equation is obtained by assuming the solution of the form x(t) = e^(rt),r² - 10r + 25 = 0.

By solving this quadratic equation, we get r1 = 5, r2 = 5. Therefore, the general solution of the given differential equation is x(t) = (c1 + c2t) e^(5t)Where c1 and c2 are arbitrary constants.

The next step is to assume a particular solution to the given differential equation as x(t) = (at + b)e^(5t) and substitute this particular solution in the differential equation.x"(t) - 10x'(t) + 25x(t) = 3te5a(25e5t) = 3te5On.

solving, we get a = 3/25So, the particular solution is x(t) = (3t/25 + b)e^(5t)

to know more about constants visit:

https://brainly.com/question/17225511

#SPJ11

The general solution of the given differential equation is:y(x) = -3e^(-x^2)2. To consider the IVP dy/dx = xV(y) – 1; y(1) = 0.

To solve the IVP dy = 2xy + y; y(0) = -3. dx.The differential equation is of the form dy/dx + P(x)y = Q(x), which is a first-order linear differential equation. Here, P(x) = 2x, Q(x) = y and integrating factor (IF) = exp [ ∫ P(x) dx ] = exp [ ∫ 2x dx ] = e^(x^2)Multiplying the given equation by e^(x^2), we get:e^(x^2) dy/dx + 2xye^(x^2) + ye^(x^2) = 0.Now, we apply the product rule of differentiation to the left-hand side, we get:(y(x)e^(x^2))' = 0Integrating both sides with respect to x, we get:y(x) e^(x^2) = C, where C is a constant.Substituting y(0) = -3 in this expression, we have:-3e^0 = C, i.e., C = -3

To know more about differential equation  visit :-

https://brainly.com/question/32524608

#SPJ11

The value of c that makes f'(π / 4) = 6 is c = 7.Setting this equal to 6, we solved for c and found that c = 7.

To find the value of c such that f'(π / 4) = 6, we need to first find the derivative of f(x) and then evaluate it at x = π / 4. Let's start by finding the derivative of f(x).

The derivative of cx is simply c, and the derivative of ln(cos x) can be found using the chain rule. The derivative of ln(u) with respect to x is (1/u) * du/dx. In this case, u = cos x, so the derivative of ln(cos x) is (1/cos x) * (-sin x).

Therefore, the derivative of f(x) = cx + ln(cos x) is f'(x) = c - (sin x / cos x).

Now, we evaluate f'(x) at x = π / 4:

f'(π / 4) = c - (sin(π / 4) / cos(π / 4))

Since sin(π / 4) = cos(π / 4) = 1 / √2, we can simplify f'(π / 4):

f'(π / 4) = c - (1 / √2) / (1 / √2) = c - 1

We want f'(π / 4) to equal 6, so we have the equation:

c - 1 = 6

Solving for c, we find: c = 6 + 1 = 7

Therefore, the value of c that makes f'(π / 4) = 6 is c = 7.

In summary, by finding the derivative of f(x) = cx + ln(cos x) and evaluating it at x = π / 4, we obtained f'(π / 4) = c - 1. Setting this equal to 6, we solved for c and found that c = 7.

To know more about derivatives click here

brainly.com/question/26171158

#SPJ11

The lateral surface area of the pyramid is 168 cm² and the height of the pyramid is 23 cm

A pyramid is formed by connecting the bases to an apex. Each edge of the base is connected to the apex, and forms the triangular face, called the lateral face.

The lateral area of a figure is the area of the non-base faces only.

For a square based pyramid. It will have equal triangular lateral faces.

Therefore, lateral area = 4 × area of triangle

The area of triangle is expressed as;

A = 1/2bh

The height of the triangle = √25²-7²

= √ 625-49

= √ 576

= 24

A = 1/2 × 24 × 14

A = 24 × 7

= 168 cm²

lateral area = 4 × 168

= 672 cm²

To find the height of the pyramid

The diagonal of the base = √14²+14²

= √ 196+196

= √ 392

= 19.8 cm

using Pythagorean theorem

h = √25²-9.9²

h = √ 526.99

h = 23 ( nearest whole number)

learn more about lateral area of pyramid from

https://brainly.com/question/5429426

#SPJ1

The shaded area of the figure is 0.86 square feet

From the question, we have the following parameters that can be used in our computation:

The figure

The area of the shaded region is the difference of the areas of the shapes

So, we have

Shaded area = 2 * 2 - 3.14 * 1²

Evaluate

Shaded area = 0.86

Hence, the shaded area of the figure is 0.86 square feet

Read more about area at

brainly.com/question/26403859

#SPJ1

DeMorgan's Laws for Sets: The complement of the union of two sets is equal to the intersection of their complements. The complement of the intersection of two sets is equal to the union of their complements.

Given sets U, A, and B, we can calculate the required expressions:

(AUB)' represents the complement of the union of sets A and B. The union of A and B is {a, b, c, d, e}. Taking the complement of this set with respect to U gives {f}. Thus, (AUB)' = {f}.

(An B)' represents the complement of the intersection of sets A and B. The intersection of A and B is {b, d}. Taking the complement of this set with respect to U gives {a, c, e, f}. Thus, (An B)' = {a, c, e, f}.

A'U B' represents the union of the complements of sets A and B. The complement of A is {e, f}, and the complement of B is {a, c, f}. Taking the union of these two sets gives {a, c, e, f}.

A' B' represents the intersection of the complements of sets A and B. The complement of A is {e, f}, and the complement of B is {a, c, f}. Taking the intersection of these two sets gives {f}.

DeMorgan's Laws for Sets state that:

The complement of the union of two sets is equal to the intersection of their complements.

The complement of the intersection of two sets is equal to the union of their complements.

In the given calculations, we can see that the results are consistent with DeMorgan's Laws for Sets. The expressions (AUB)'.(An B)' and A'U B' follow the first law, while A' B' follows the second law.

Learn more about sets here:

https://brainly.com/question/30705181

#SPJ11