what is the exact duplication of elements (shapes, forms, etc.) on either side of a central axis?

The equation to model the population y after x years is y = [tex]100,000(1.042)^x.[/tex]This equation gives us the population of the city after x years, assuming a constant annual growth rate of 4.2%.

[tex]y = a(1 + r)^x[/tex]

where:

a = initial population = 100,000

r = annual growth rate = 4.2% = 0.042 (converted to decimal)

x = number of years

Substituting the values into the formula, we get:

[tex]y = 100,000(1 + 0.042)^x[/tex]

Simplifying this equation, we get:

[tex]y = 100,000(1.042)^x[/tex]

An equation is a statement that asserts the equality of two mathematical expressions. These expressions can be comprised of variables, constants, mathematical operations, and functions. An equation typically takes the form of an expression on one side of an equals sign, with another expression on the other side.

Equations can also be classified according to their degree or order, which is the highest power of the variable in the equation. For example, a linear equation has a degree of 1, while a quadratic equation has a degree of 2. Equations are a fundamental concept in mathematics, and their understanding is essential for many applications in science, technology, and everyday life.

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Find the following limit...

[tex]\lim_{x \to \infty} (\frac{1-x^2}{x^3-x+1} )[/tex]

~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

[tex]\Longrightarrow \lim_{x \to \infty} (\frac{1-x^2}{x^3-x+1} )[/tex]

Step 1: Divide everything by the highest power in the denominator, x^3.

[tex]\Longrightarrow \lim_{x \to \infty} (\frac{\frac{1}{x^3} -\frac{x^2}{x^3} }{\frac{x^3}{x^3} -\frac{x}{x^3} +\frac{1}{x^3} } )[/tex]

After simplifying we get,

[tex]\Longrightarrow \lim_{x \to \infty} (\frac{\frac{1}{x^3} -\frac{1}{x} }{1-\frac{1}{x^2} +\frac{1}{x^3} } )[/tex]

Step 2: Apply [tex]\lim_{x \to a} [\frac{f(x)}{g(x)} ]=\frac{ \lim_{x \to a} f(x) }{ \lim_{x \to a} g(x) }[/tex]

[tex]\Longrightarrow\frac{ \lim_{x \to \infty} (\frac{1}{x^3} -\frac{1}{x} ) }{ \lim_{x \to \infty} (1-\frac{1}{x^2} +\frac{1}{x^3}) }[/tex]

Step 3: Plug in "∞" and solve.

[tex]\Longrightarrow\frac{ \lim_{x \to \infty} (\frac{1}{(\infty)^3} -\frac{1}{\infty} ) }{ \lim_{x \to \infty} (1-\frac{1}{(\infty)^2} +\frac{1}{(\infty)^3}) }[/tex]

[tex]\Longrightarrow\frac{ \lim_{x \to \infty} (0-0) }{ \lim_{x \to \infty} (1-0+0) }[/tex]

[tex]\Longrightarrow \lim_{x \to \infty} (\frac{0}{1} ) = \boxed{0}[/tex]

[tex]\Longrightarrow \boxed{\boxed{\lim_{x \to \infty} (\frac{1-x^2}{x^3-x+1} )=0}} \therefore Sol.[/tex]

Thus, the limit is solved.

Using a computer to randomly determine who gets what treatment would be the most effective recommendation for randomization in this scenario.

For this experiment, it would be best to use a computer to randomly determine who gets what treatment.

This is known as randomization, which ensures that each participant has an equal chance of being assigned to any of the three music groups, as well as to the mouse or touchpad groups.

Randomization also helps to eliminate any potential biases that could arise from letting participants pick their music group or choosing treatments based on some non-random pattern.

By using a computer to randomly assign participants to each group, the study's results will be more reliable and accurate.

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The highest temperature on the surface of the sphere is 64000sqrt(55), and the lowest temperature is -64000sqrt(55).

Using Lagrange multipliers, we want to optimize the temperature function subject to the constraint of the sphere equation:

F(x, y, z) = 400xyz

G(x, y, z) = x^2 + y^2 + z^2 - 22 = 0

The Lagrangian function is:

L(x, y, z, λ) = F(x, y, z) - λG(x, y, z) = 400xyz - λ(x^2 + y^2 + z^2 - 22)

Taking partial derivatives with respect to x, y, z, and λ and setting them to zero, we get:

400yz - 2λx = 0

400xz - 2λy = 0

400xy - 2λz = 0

x^2 + y^2 + z^2 - 22 = 0

Solving the first three equations for x, y, and z, we get:

x = 200yz/λ

y = 200xz/λ

z = 200xy/λ

Substituting these into the sphere equation, we get:

(200yz/λ)^2 + (200xz/λ)^2 + (200xy/λ)^2 - 22 = 0

Simplifying this equation and solving for λ, we get:

λ = ±80sqrt(55)

Using these values of x, y, z, and λ, we can find the corresponding temperature values:

T(x, y, z) = 400xyz = ±64000sqrt(55)

Therefore, the highest temperature on the surface of the sphere is 64000sqrt(55), and the lowest temperature is -64000sqrt(55).

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The average value of f(x) = 3x^2 + 5x on the interval [3, 7] is 109, and the value of C for which f(c) = f_average is approximately 3.99.

a) To determine the average value of f(x) on the interval [7, 3], you need to calculate the integral of the function over the interval and divide it by the width of the interval. First, we need to correct the interval [7, 3] to [3, 7] since the smaller number should come first. The width of the interval is 7 - 3 = 4.

∫(3x^2 + 5x) dx from 3 to 7 = [(x^3 + (5/2)x^2) evaluated from 3 to 7] = [(7^3 + (5/2)7^2) - (3^3 + (5/2)3^2)] = 436.

Now, we divide this by the width of the interval: f_average = 436/4 = 109.

b) To find the value of C, we need to solve f(c) = f_average on the interval [3, 7]. We are given that f(c) = f_average = 109, so we set the function equal to the average value and solve for c:

3c^2 + 5c = 109

3c^2 + 5c - 109 = 0

This quadratic equation can be solved using the quadratic formula, factoring, or other methods, but it does not factor easily. Using the quadratic formula, you will find two possible values for c: approximately 3.99 and -9.16. Since -9.16 is not within the interval [3, 7], the value of c is approximately 3.99.

So, On the range [3, 7], the average value of f(x) = 3x2 + 5x is 109, and the value of C for which f(c) = f_average is roughly 3.99.

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Complete question:

f(x) = 3x^2 + 5x in (7,3) a) Determine faverage in [7,3] b) Find the value of C, f(c)= fave in [7,3]

we can make an educated guess and say that the total length of the six cars is likely to be close to the length of the roller coaster track they are traveling on.

To find the total length of the six cars, we need to add up the length of each car. Without any information about the length of each car, we cannot provide an exact answer. However, we can make an educated guess and say that the total length of the six cars is likely to be close to the length of the roller coaster track they are traveling on. This is because roller coaster tracks are designed to accommodate the length of the cars and provide a smooth ride. Therefore, the answer is likely to be close to the length of the roller coaster track.

Based on the information provided, I understand that you need to determine the total length of the six cars of a roller coaster. To provide an accurate answer, I would need some more details like the length of each car or the average length of a car. Once I have that information, I can help you find the closest total length of the six cars using the principles of geometry.

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The combination is solved and number of ways the driver select the students to ride the bus is A = 5005 ways

Given data ,

Let the initial number of students be n = 15

Now , the number of students selected = 6

And , from the combination rule , we get

ⁿCₓ = n! / ( ( n - x )! x! )

On simplifying the equation , we get

¹⁵C₆ = 15! / 6!(15-6)!

¹⁵C₆ = 5005 ways

Hence , the number of students selection is 5005 ways

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The series converges to the sum 7 / (1 + 2z) for all values of z such that |z| < 1/2.

To find the sum of the series, we can rewrite it as:

7(1 - 2z + 4z² - 8z³ + ⋯)

This is a geometric series with first term 1 and common ratio -2z. The sum of a geometric series with first term a and common ratio r is given by:

sum = a / (1 - r)

In this case, we have a = 7 and r = -2z. Thus, the sum of the series is:

sum = 7 / (1 + 2z)

To determine the domain where the series converges to this sum, we must ensure that the common ratio |r| < 1. That is:

|-2z| < 1

or

|z| < 1/2

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To find s', we need to take the derivative of s with respect to t. Using the chain rule, we have: s' = -sin(t-1) * (d/dt) (t-1)
Notice that the derivative of (t-1) with respect to t is simply 1. Therefore, we have: s' = -sin(t-1) * 1
s' = -sin(t-1)
So, the derivative of s with respect to t is -sin(t-1).

We need to find s', which is the derivative of s with respect to t, given that s = cos(t-1). To do this, we'll use the chain rule. Here are the steps:
1. Identify the outer and inner functions:
  Outer function: f(u) = cos(u)
  Inner function: u = t-1
2. Find the derivatives of both functions:
  f'(u) = -sin(u)
  du/dt = 1
3. Apply the chain rule:
  s' = f'(u) * (du/dt)
4. Substitute the expressions for f'(u) and du/dt into the chain rule equation:
  s' = (-sin(u)) * (1)
5. Replace u with the inner function (t-1):
  s' = -sin(t-1)
So, the derivative of s with respect to t, s', is -sin(t-1).

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The equation that expresses the total cost in terms of the number of hours required to complete the job is: Total cost = (K32 x number of hours) + K31.50.

This equation takes into account the hourly rate of K32 per hour, as well as the one-time charge of K31.50.

By multiplying the hourly rate by the number of hours required to complete the job and adding the one-time charge, the equation provides the total cost of the service to the customer. This equation can be used to calculate the total cost for any number of hours required to complete the job, making it a valuable tool for David when pricing his services and for customers when budgeting for their printing and typing needs.

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4. Inverse Laplace transform of F(s) is f(t) = e^(-t) * cos(2t) + sin(2t), 5. f(t) = (3/4) * e^(2t) - (1/4) * e^(-2t). This is the inverse Laplace transform of F(s)

For Problem 4, we can first use partial fraction decomposition to write F(s) as:

F(s) = (2s+2)/(s²+2s+5) = A/(s+1-i√2) + B/(s+1+i√2)

where A and B are constants to be determined. To find A and B, we can multiply both sides by the denominator and then set s = -1+i√2 and s = -1-i√2, respectively. This gives us the system of equations:

2(-1+i√2)A + 2(-1-i√2)B = 2+2i√2
2(-1-i√2)A + 2(-1+i√2)B = 2-2i√2

Solving this system, we get A = (1+i√2)/3 and B = (1-i√2)/3. Therefore, we have:

F(s) = (1+i√2)/(3(s+1-i√2)) + (1-i√2)/(3(s+1+i√2))

To find the inverse Laplace transform of F(s), we can use the formula:

L⁻¹{a/(s+b)} = ae^(-bt)

Applying this formula to each term in F(s), we get:

f(t) = (1+i√2)/3 e^(-(-1+i√2)t) + (1-i√2)/3 e^(-(-1-i√2)t)
    = (1+i√2)/3 e^(t-√2t) + (1-i√2)/3 e^(t+√2t)

This is the inverse Laplace transform of F(s).

For Problem 5, we can also use partial fraction decomposition to write F(s) as:

F(s) = (2s-3)/(s²-4) = A/(s-2) + B/(s+2)

where A and B are constants to be determined. To find A and B, we can multiply both sides by the denominator and then set s = 2 and s = -2, respectively. This gives us the system of equations:

2A - 2B = -3
2A + 2B = 3

Solving this system, we get A = 3/4 and B = -3/4. Therefore, we have:

F(s) = 3/(4(s-2)) - 3/(4(s+2))

To find the inverse Laplace transform of F(s), we can again use the formula:

L⁻¹{a/(s+b)} = ae^(-bt)

Applying this formula to each term in F(s), we get:

f(t) = 3/4 e^(2t) - 3/4 e^(-2t)

This is the inverse Laplace transform of F(s).

In each of Problems 4 and 5, find the inverse Laplace transform of the given function.

4. F(s) = (2s + 2) / (s^2 + 2s + 5)
To find the inverse Laplace transform of F(s), first complete the square for the denominator:
s^2 + 2s + 5 = (s + 1)^2 + 4
Now, F(s) = (2s + 2) / ((s + 1)^2 + 4)
The inverse Laplace transform of F(s) is f(t) = e^(-t) * cos(2t) + sin(2t)

5. F(s) = (2s - 3) / (s^2 - 4)
To find the inverse Laplace transform of F(s), recognize this as a partial fraction decomposition problem:
F(s) = A / (s - 2) + B / (s + 2)
Solve for A and B, then apply inverse Laplace transform to each term:
f(t) = (3/4) * e^(2t) - (1/4) * e^(-2t)

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The associated homogeneous equation is v (t) + ½' (t) -6y(t) = 0. To find a solution to this equation, we can assume that the solution is in the form of y(t) = e^(rt), where r is a constant. Plugging this into the equation, we get the characteristic equation r^2 - 6 = 0. Solving for r, we get r = ±√6.

Thus, the general solution to the associated homogeneous equation is y(t) = c1e^(√6t) + c2e^(-√6t), where c1 and c2 are constants.

To find a solution to the original differential equation, we can use the method of undetermined coefficients. Assuming that the particular solution is in the form of y(t) = At + B, we can plug this into the equation and solve for A and B.

Taking the derivative of y(t), we get y'(t) = A. Plugging this and y(t) into the differential equation, we get:

A + ½ - 6(At + B) = g(t)

Simplifying, we get:

A(1-6t) + ½ - 6B = g(t)

To solve for A and B, we need to have information about the function g(t). Once we have that, we can solve for A and B and find the particular solution to the differential equation.

In summary, the solution to the associated homogeneous equation is y(t) = c1e^(√6t) + c2e^(-√6t), and the particular solution to the differential equation can be found using the method of undetermined coefficients with information about the function g(t).

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The horizontal distance of the soda from the bottle when it hits the ground is 6.5.

The given parabolic equation is y=-0.5x²+3x+2.

Graph the parabola using the direction, vertex, focus, and axis of symmetry.

Direction: Opens Down

Vertex: (3,13/2)

Focus: (3,6)

Axis of Symmetry: x=3

Directrix: y=7

The horizontal distance:

Find where the first derivative is equal to 0. Enter the solutions into the original equation and simplify.

y=6.5

Therefore, the horizontal distance of the soda from the bottle when it hits the ground is 6.5.

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The weight that separates the bottom 5% is approximately 5.02 ounces.

To find the weights that separate the top 5% and the bottom 5%, we need to use the z-score formula and the standard normal distribution table.

First, let's find the z-score for the top 5%. Using the standard normal distribution table, we find that the z-score for the top 5% is approximately 1.645.

Next, we can use the formula z = (x - μ) / σ, where z is the z-score, x is the weight we're trying to find, μ is the mean, and σ is the standard deviation.

For the top 5%, we have:

1.645 = (x - 5.12) / 0.07

Solving for x, we get:

x = 5.12 + 1.645 * 0.07

x ≈ 5.22 ounces

Therefore, the weight that separates the top 5% is approximately 5.22 ounces.

To find the weight that separates the bottom 5%, we use the same process but with a negative z-score. The z-score for the bottom 5% is approximately -1.645.

-1.645 = (x - 5.12) / 0.07

Solving for x, we get:

x = 5.12 - 1.645 * 0.07

x ≈ 5.02 ounces

Therefore, the weight that separates the bottom 5% is approximately 5.02 ounces.

These weights could serve as limits used to identify which components should be rejected. Any component with a weight less than 5.02 ounces or greater than 5.22 ounces should be rejected.

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The integral of x²(49-x²)³/² dx is [tex](1/2)(49-x^2)^{(5/2)} - (5/2)x^2(49-x^2)^{(3/2)} + C[/tex], where C is the constant of integration.

To evaluate the integral, we can use substitution. Let u = 49-x², then du/dx = -2x, or dx = -du/(2x). Substituting this into the integral, we get:

∫ x²(49-x²)³/² dx = ∫ x²u³/²(-du/(2x)) = -1/2 ∫ u³/² du = -1/2 * (2/5) u^(5/2) + C

Substituting u = 49-x² back into the expression, we get:

[tex]= -(1/5)(49-x^2)^{(5/2)} + C'x[/tex]

To simplify this expression, we can distribute the factor of x and express the constant of integration as C' = C/2. Thus, we have:

[tex]= (1/2)(49-x^2)^{(5/2)} - (5/2)x^2(49-x^2)^{(3/2)} + C[/tex]

Therefore, the integral is [tex](1/2)(49-x^2)^{(5/2)} - (5/2)x^2(49-x^2)^{(3/2)} + C[/tex], where C is the constant of integration.

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The equation:  f(x,y)= √x⁴+4xy+y⁴+10fx(x,y) = fy(x,y)=fx (2, - 2) = fy(1,3) = (2(3)³ + 4(1)) / (2√(1)⁴ + 4(1)(3) + 2(3)⁴) = 26/38 = 13/19

To find the partial derivatives fx(x, y) and fy(x, y) for the equation f(x, y) = √(x⁴ + 4xy + y⁴ + 10), we will differentiate f with respect to x and y, respectively. fx(x, y) = ∂f/∂x = (1/2)(x⁴ + 4xy + y⁴ + 10)^(-1/2) * (4x³ + 4y) fy(x, y) = ∂f/∂y = (1/2)(x⁴ + 4xy + y⁴ + 10)^(-1/2) * (4x + 4y³)

Now, we'll find the values of fx(2, -2) and fy(1, 3): fx(2, -2) = (1/2)((2^4) + 4(2)(-2) + (-2)^4 + 10)^(-1/2) * (4(2)^3 + 4(-2)) = -0.5 fy(1, 3) = (1/2)((1^4) + 4(1)(3) + (3)^4 + 10)^(-1/2) * (4(1) + 4(3)^3) = 0.0625 So, we have: fx(x, y) = (1/2)(x⁴ + 4xy + y⁴ + 10)^(-1/2) * (4x³ + 4y) fy(x, y) = (1/2)(x⁴ + 4xy + y⁴ + 10)^(-1/2) * (4x + 4y³) fx(2, -2) = -0.5 fy(1, 3) = 0.0625

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The income has increased by 10%.

Let's assume that the original price of the product was P, and the original quantity sold was Q. Then, the original income (revenue) would be:

Income1 = P x Q

After the price decreased by 12%, the new price would be:

P2 = P - 0.12P = 0.88P

And the new quantity sold would be 25% higher than the original quantity, or:

Q2 = 1.25Q

The new income would be:

Income2 = P2 x Q2 = (0.88P) x (1.25Q) = 1.1PQ

Therefore, the percent change in income would be:

[(Income2 - Income1) / Income1] x 100% = [(1.1PQ - PQ) / PQ] x 100%

= (0.1PQ / PQ) x 100%

= 10%

So the income has increased by 10%.

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Therefore, the vector ä = AB is (8, -2, 2). To find the vector ä = AB, we simply subtract the coordinates of point A from the coordinate

To find the vector AB (also denoted as vector ä) between the points A (-5, 1, 4) and B (3, -1, 6), we need to calculate the difference between the coordinates of point B and point A. This can be done using the formula: AB = (Bx - Ax, By - Ay, Bz - Az).

Using the given coordinates, we have:

Ax = -5, Ay = 1, Az = 4
Bx = 3, By = -1, Bz = 6

Now, we'll apply the formula to find the components of vector AB:

ABx = Bx - Ax = 3 - (-5) = 8
ABy = By - Ay = -1 - 1 = -2
ABz = Bz - Az = 6 - 4 = 2

So, the vector AB (or vector ä) is given by:

AB = (8, -2, 2)

Thus, the vector connecting points A and B has components (8, -2, 2).

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The probability of getting 2 blue candies without replacement from a bag of 7 red candies and 5 blue candies can be calculated as follows:

First, we need to find the total number of ways to choose 2 candies from the bag, which is:

12 choose 2 = (12!)/(2!*(12-2)!) = 66

Next, we need to find the number of ways to choose 2 blue candies from the bag, which is:

5 choose 2 = (5!)/(2!*(5-2)!) = 10

Therefore, the probability of getting 2 blue candies without replacement from the bag is:

10/66 = 5/33

So the probability of getting 2 blue candies without replacement from the bag is 5/33, or approximately 0.152.

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a. A confidence interval must be used for statistical inference when we want to estimate an unknown population parameter based on a sample of data.

For example, if we want to estimate the average height of all students in a particular school, we could take a random sample of students and use a confidence interval to estimate the true population mean height with a certain degree of certainty.

b. Hypothesis testing must be used for statistical inference when we want to test a specific hypothesis about a population parameter.

For example, we might want to test whether the average salary of male employees in a company is significantly different from the average salary of female employees.

The P-value is the probability of observing a test statistic as extreme as or more extreme than the one calculated from our sample data, assuming the null hypothesis is true. In other words, it represents the likelihood of obtaining the observed result if the null hypothesis is actually true. A small P-value indicates that the observed result is unlikely to have occurred by chance and provides evidence against the null hypothesis.

Hypothesis testing and confidence intervals are closely related. In hypothesis testing, we use a significance level (such as 0.05) to determine whether to reject or fail to reject the null hypothesis based on the P-value. In contrast, a confidence interval gives a range of plausible values for the unknown population parameter based on the sample data, with a specified level of confidence (such as 95%). However, the decision to reject or fail to reject the null hypothesis in a hypothesis test is equivalent to whether the null value (such as zero difference or equality) falls within the confidence interval or not. Therefore, a significant result in a hypothesis test (a small P-value) and a non-overlapping confidence interval both provide evidence against the null hypothesis.

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Answer:

The rate of change for height is 1/6 cubic feet/min at 2 min.

Step-by-step explanation:

Answer: The value of P is 14.

Step-by-step explanation: To find the value of P, we can use the formula for the mean of a set of numbers:

mean = (sum of numbers) / (number of numbers)

We know that the mean of the set {6, 8, 9, P, 13} is 10. So we can write:

10 = (6 + 8 + 9 + P + 13) / 5

Multiplying both sides by 5, we get:

50 = 6 + 8 + 9 + P + 13

Combining like terms, we get:

50 = 36 + P

Subtracting 36 from both sides, we get:

14 = P

Therefore, the value of P is 14.

The rate of change of the volume of the hailstone is 108π mm³/min when the radius is 3 mm.

The formula for the volume of a sphere is V = (4/3)πr³, where V is the volume and r is the radius.

We can use implicit differentiation to find the rate of change of the volume with respect to time.

Taking the derivative of both sides with respect to time t, we get:

dV/dt = d/dt[(4/3)πr³]

Using the chain rule, we get:

dV/dt = (4/3)π×3r² dr/dt

Now, we substitute the given values to find dV/dt at the moment when the radius is 3 mm:

r = 3 mm

dr/dt = 2 mm/min

dV/dt = (4/3)π × 3(3)² × 2

dV/dt = (4/3)π × 27 × 2

= 72π mm³/min

Therefore, the rate of change of the volume of the hailstone is 108π mm³/min when the radius is 3 mm.

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Answer:

= -77

Step-by-step explanation:

11/2 x -14 =

Express 11/2 (-14) as a single fraction.

11(-14)/2

Multiply 11 and -14 to get -154.

-154/2

Divide -154 by  2 to get -77.

-77.

a.) Both defective cylinders are selected:  the probability of both defective cylinders being selected is 1/28. b.) No defective cylinder is selected:  the probability of no defective cylinder being selected is 15/28. c.) At least one defective cylinder is selected: the probability of selecting at least one defective cylinder is 13/28.

a. The probability of selecting both defective cylinders can be calculated by multiplying the probability of selecting the first defective cylinder (which is 2/8, or 1/4 since there are 2 defective cylinders out of 8 total) by the probability of selecting the second defective cylinder given that the first one was already selected (which is 1/3 since there are now only 3 cylinders left and only 1 of them is defective). So the probability of both defective cylinders being selected is (1/4) x (1/3) = 1/12.
b. The probability of selecting no defective cylinder can be calculated by selecting two non-defective cylinders from the six remaining ones. The probability of selecting the first non-defective cylinder is 6/8 (or 3/4) and the probability of selecting the second non-defective cylinder given that the first one was already selected is 5/7. So the probability of selecting no defective cylinder is (3/4) x (5/7) = 15/28.
c. The probability of selecting at least one defective cylinder can be calculated by subtracting the probability of selecting no defective cylinder from 1 (since either at least one defective cylinder is selected or no defective cylinder is selected). So the probability of selecting at least one defective cylinder is 1 - (15/28) = 13/28.

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Answer: Common denominator

Step-by-step explanation:

Turn them into common denominators such as 10 (hint) has a denominator of 10.

Answer:

A

Step-by-step explanation:

add them up then divide the fractions and get ur amount of hours into a decimal into a fraction

The total number of outcomes, if one picks a month of a year, is 12 and tosses a coin is 2.

The total number of outcomes refers to the possible events that can occur if an event takes place. These are helpful in calculating probability.

The events that can occur if one picks a month of the year is he or she picks one of the following months: January, February, March, April, May, June, July, August, September, October, November, and December. Thus, the number of outcomes possible is 12.

The events that can occur if one tosses is he or she gets the following side of the coin: Heads or Tails. Thus, the number of outcomes possible is 2.

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The corresponding z-score is -1.80 (rounded to two decimal places).  The x value corresponding to z = -0.25 is x = μ - 1.697 = μ - 1.80 * (12 / sqrt(50)).

To find the x value corresponding to z = -0.25, we need to use the standard normal distribution table or calculator. First, we calculate the z-score:
z = (x - μ) / (s / sqrt(n))
where μ is the population mean (which we don't know), s is the sample standard deviation, n is the sample size, and x is the value we want to find. Rearranging this formula, we get:
x = μ + z * (s / sqrt(n))
Substituting the given values, we get:
x = μ + (-0.25) * (12 / sqrt(50))
x = μ - 1.697
Now we need to find the corresponding value of x from the standard normal distribution table or calculator. Looking up -1.697 in the table, we find that the corresponding area is 0.0445. Since we're looking for the left-tail area (z < 0), we subtract this area from 0.5 (the total area under the curve):
0.5 - 0.0445 = 0.4555
Looking up 0.4555 in the table (or using a calculator), Therefore, the x value corresponding to z = -0.25 is:
x = μ - 1.697 = μ - 1.80 * (12 / sqrt(50))

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The elementary matrix E = [1 0 0; 0 1 0; 5/3 -2 1] such that EC = A.

To find an elementary matrix E such that EC = A, we need to perform row operations on the matrix C such that it becomes A.

We can achieve this by performing the following row operations on C:

R3 ← R3 + R1

R1 ← R1/3

R2 ← R2 - 3R1

R3 ← R3 + 5R2

The resulting matrix after these row operations is:

1 0 0

0 1 0

5/3 -2 1

Therefore, the elementary matrix E that corresponds to these row operations is:

1 0 0

0 1 0

5/3 -2 1

We can verify that EC = A by multiplying EC:

[0 3 -5 0 1 2-1 2 0 0 0 0-1 2 0 0 0 0] x [0 3 -5 0 1 2                      

0 1 2 0 0 0                      -1 2 0 0 0 0]

= [0 3 -5 1 -1 2   -1 2 0 0 0 0   0 3 -5 0 1 2]

= A

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The quadratic equation can be written as:

y =x^2 - 6x + 13

We can see that this is the table for a quadratic equation, there we can see that we have the vertex at (3, -4), then if the leading coefficient is a, we can write the equation in the vertex form as:

y = a*(x - 3)^2 - 4

Now, also notice that the function passes through (0, 5), then:

5 = a*(0 - 3)^2 - 4

5 = 9a - 4

9 = 9a

1 = a

The qudratic is:

y = (x - 3)^2 - 4

Expanding it we get:

y = x^2 - 6x + 9 + 4

y =x^2 - 6x + 13

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