1. The amount of gasoline sold daily at a service station is uniformly distributed with a minimum of 2,000 gallons and a maximum of 5,000 gallons.
a. Find the probability that daily sales will fall between 2,500 and 3,000 gallons.
b. What is the probability that the service station will sell at least 4,000 gallons.
c. What is the probability that the station will sell exactly 2,500 gallons?

F is a constant value along all the given curves that end at (0,0): y=kx^2, y=kx+kx^2, y=kx^3, and y=kx.

To examine the values of f along the curves that end at (0,0) and determine along which set of curves f is a constant value, let's analyze each given equation:

1. y = kx^2:
For (0,0) to be on the curve, we have:
0 = k(0)^2
0 = 0, which is always true. Thus, f is a constant value along this curve.

2. y = kx + kx^2:
For (0,0) to be on the curve, we have:
0 = k(0) + k(0)^2
0 = 0, which is always true. Thus, f is a constant value along this curve.

3. y = kx^3:
For (0,0) to be on the curve, we have:
0 = k(0)^3
0 = 0, which is always true. Thus, f is a constant value along this curve.

4. y = kx:
For (0,0) to be on the curve, we have:
0 = k(0)
0 = 0, which is always true. Thus, f is a constant value along this curve.

In conclusion, f is a constant value along all the given curves that end at (0,0): y=kx^2, y=kx+kx^2, y=kx^3, and y=kx.

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Among the following pairs of sets, I'll help you identify the ones that are equal:

1. {1, 3, 3, 3, 5, 5, 5, 5, 5} and {5, 3, 1}:

These sets are equal because in set notation, repetitions are not counted.

Both sets have the unique elements {1, 3, 5}.

2. {{1}} and {1, [1]}:

These sets are not equal because the first set contains a single element which is the set {1}, while the second set contains two distinct elements, 1 and [1]

(assuming [1] is a different notation for an element).

3. {0} and [1, 2]:

These sets are not equal because they have different elements. The first set contains the single element 0, while the second set contains the elements 1 and 2.

4. [[1], [2]]:

This is not a pair of sets, so it cannot be compared for equality.

In summary, the equal pair of sets among the given options is {1, 3, 3, 3, 5, 5, 5, 5, 5} and {5, 3, 1}.

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Answer: The total amount that must be paid back at the end of the 8-year period is $65,206.49

Step-by-step explanation:

A = P*(1 + r/n)^(n*t)

A = the amount to be paid back

P = the principal amount borrowed ($37,000 in this case)

r = the annual interest rate (7.25%)

n = the number of times the interest is compounded per year (once annually in this case)

t = the time period (8 years)

A = 37000*(1 + 0.0725/1)^(18)

A = 37000(1.0725)^8

A = 65,206.49

[tex]A = P(1 + r/n)^{(nt)}[/tex]

[tex]A = 37000(1 + 7.25)^8[/tex]

[tex]\longrightarrow A = \boxed{\bold{794,023,420,332.60}}[/tex]

Test cross allows us to verify that the heterozygous individual produced all 4 possible gamete types in equal frequencies during meiosis due to independent assortment. A

Punnett Square for the given test cross can be drawn as follows:

      E B e b

e b eBeb ebeb

a p aPeb ap eb

In this

Punnett Square, the gametes produced by the heterozygous individual (EB eb; AP ap) are represented along the top and left sides, and the gametes produced by the homozygous recessive individual (eb eb; ap ap) are represented along the bottom and right sides. The possible offspring resulting from the mating is shown in the four boxes in the middle.

To verify that the heterozygous individual produced all 4 possible gamete types (EB AP, EB ap, eb AP, eb ap) in equal frequencies during meiosis due to independent assortment, we can look at the resulting offspring in the Punnett Square. If the heterozygous individual produced all 4 possible gamete types in equal frequencies, then we would expect to see each of the four possible offspring genotypes represented equally in the resulting offspring.

From the Punnett Square, we can see that there are four possible offspring genotypes: eBeb, ebeb, aPeb, and ap eb. Each of these genotypes appears once in the resulting offspring, which suggests that the heterozygous individual produced all 4 possible gamete types in equal frequencies during meiosis due to independent assortment.

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To find a matrix S such that S⁻¹AS = D, where D is a diagonal matrix, you need to diagonalize matrix A using eigenvectors and eigenvalues.

First, find the eigenvalues and eigenvectors of matrix A. Then, form matrix S using the eigenvectors as its columns. Finally, find the inverse of matrix S (S⁻¹) and multiply S⁻¹AS to obtain the diagonal matrix D.

In this process, the eigenvalues of matrix A will be the diagonal elements of matrix D. By diagonalizing A, you are transforming it into a simpler diagonal form using a change of basis given by matrix S and its inverse S⁻¹.

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Answer:

376.990444... [tex]cm^{2}[/tex] or 376.99 [tex]cm^{2}[/tex] ( It says in terms of π so your answer is 120 π, sorry :) )

Hope this helps!

Step-by-step explanation:

To find the surface area of a cylinder you need to find the area of the 2 circles and the area of the rectangle.

The area of a circle is [tex]\pi[/tex] × [tex]r^{2}[/tex]

So, the area of one circle is [tex]\pi[/tex] × 36 = 113.097335529...

113.097 × 2 = 226.194

The area of the rectangle is 4 × 2[tex]\pi r[/tex] ( circumference of the circle is the rectangle's length )

The area of the rectangle is 4 × 12[tex]\pi[/tex] = 4 × 37.699111... = 150.796444...

Add the area of the rectangle with the area of the 2 circles to get 376.990444... [tex]cm^{2}[/tex].

The particular solution to the differential equation by the method of undetermined coefficients is [tex]y \_p(x) = (-6x^2 - 16x - 80) + e^{(2x)}(x^2 + x - 44).[/tex]

To solve this differential equation using the method of undetermined coefficients, we assume that the particular solution takes the form:

[tex]y \_ p(x) = (Ax^2 + Bx + C) + e^{(2x)}(Dx^2 + Ex + F)[/tex]

where A, B, C, D, E, and F are constants to be determined.

To determine the values of these constants, we differentiate y_p(x) four times and substitute the result into the differential equation. We get:

[tex]y \_p(x) = Ax^2 + Bx + C + e^{(2x)}(Dx^2 + Ex + F)[/tex]

[tex]y\_p'(x) = 2Ax + B + 2e^{(2x)}(Dx^2 + Ex + F) + 2e^{(2x)}(2Dx + E)[/tex]

[tex]y \_p''(x) = 2A + 4e^{(2x)}(Dx^2 + Ex + F) + 8e^{(2x)}(Dx + E) + 4e^{(2x)(2D)}[/tex]

[tex]y\_p''(x) = 8e^{(2x)}(Dx^2 + Ex + F) + 24e^{(2x)(Dx + E)} + 16e^{(2x)(D)}[/tex]

[tex]y \_p^4(x) = 32e^{(2x)(Dx + E) }+ 32e^{(2x)(D)}[/tex]

Substituting these into the original differential equation, we get:

[tex](32e^{(2x)(Dx + E)} + 32e^{(2x)(D))} - 2(8e^{(2x)}(Dx^2 + Ex + F) + 24e^{(2x)(Dx + E)} + 16e^{(2x)(D))} + (Ax^{2 }+ Bx + C + e^{(2x)}(Dx^2 + Ex + F))(x - 4)^2 = (x - 4)^2[/tex]

Simplifying this expression, we get:

[tex](-6D + A)x^4 + (4D - 8E + B)x^3 + (4D - 16E + 4F - 32D + C + 16E - 32D)x^2 + (-8D + 24E - 16F + 64D - 32E)x + (32D - 32E) = x^2 - 8x + 16[/tex]

Comparing the coefficients of like terms, we get the following system of equations:

-6D + A = 0

4D - 8E + B = 0

-24D + 4F - 32D + C = 16

-8D + 24E - 16F + 64D - 32E = 0

32D - 32E = 0

Solving this system of equations, we get:

D = E = 1

A = -6

B = -16

C = -80

F = -44

Therefore, the particular solution to the differential equation is:

[tex]y \_p(x) = (-6x^2 - 16x - 80) + e^{(2x)}(x^2 + x - 44)[/tex]

The general solution to the differential equation is the sum of the particular solution and the complementary function, which is the solution to the homogeneous equation:

[tex]y'''' - 2y'' + y = 0[/tex]

The characteristic equation of this homogeneous equation is:

[tex]r^4 - 2r^2 + 1 = 0[/tex]

Factoring the characteristic equation, we get:

[tex](r^2 - 1)^[/tex].

The particular solution to the differential equation by the method of undetermined coefficients is [tex]y \_p(x) = (-6x^2 - 16x - 80) + e^{(2x)}(x^2 + x - 44).[/tex]

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The graph of the parametric equations x(θ) = 2cos(θ) and y(θ) = 5sin(θ) over the interval [0,π] is show below.

What is parametric equation?

A parametric equation is a set of equations that expresses a set of related variables in terms of one or more independent variables, called parameters. In other words, it is a way to describe a curve or a surface in terms of one or more parameters that control the motion of a point or a set of points.

For the parametric equations x(θ) = 2cos(θ) and y(θ) = 5sin(θ) over the interval [0,π], we can create a table of values by plugging in values of θ and finding the corresponding values of x and y:

θ x = 2cos(θ) y = 5sin(θ)

0 2 0

π/6 √3 5/2

π/4 √2 5/√2

π/3 1 5√3/2

π/2 0 5

2π/3 -1 5√3/2

3π/4 -√2 5/√2

5π/6 -√3 5/2

π -2 0

We can then plot these points on a graph and connect them to form a curve.

Here is the graph of the parametric equations x(θ) = 2cos(θ) and y(θ) = 5sin(θ) over the interval [0,π]:

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The probability that y takes a value less than 1/3 is approximately 0.11.

We are given that the cumulative distribution function (cdf) of the random variable y is defined as:

F(x) = { 0, x ≤ 0

[tex]x^2,[/tex] 0 < x < 1

1, x ≥ 1

We want to find the probability that the random variable y takes a value less than 1/3, i.e., P(y < 1/3).

Since F(x) is the cdf of y, we have:

P(y < 1/3) = P(y ≤ 1/3) = F(1/3)

To find F(1/3), we need to consider two cases:

Case 1: 0 ≤ 1/3 < 1

In this case, we have:

F(1/3) = (1/3[tex])^2[/tex] = 1/9

Case 2: 1/3 ≥ 1

In this case, we have:

F(1/3) = 1

Therefore, the probability that y takes a value less than 1/3 is:

P(y < 1/3) = F(1/3) = 1/9

Rounding off to the second decimal place, we get:

P(y < 1/3) ≈ 0.11

Therefore, the probability that y takes a value less than 1/3 is approximately 0.11.

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Full Question

Let y be a random variable with cdf F(x) = { 0, x 0 Find P(x < 1/3) (round off to second decimal place).

The confidence interval can be expressed as:

p ± E = 0.888 ± 0.111

To express the confidence interval 0.777 < p < 0.999 in the form p ± E, we need to first calculate the point estimate of the population proportion p.

The point estimate is simply the midpoint of the confidence interval, which is given by:

Point estimate = (lower limit + upper limit) / 2

= (0.777 + 0.999) / 2

= 0.888

Next, we need to calculate the margin of error (E) using the formula:

E = (upper limit - point estimate) = (0.999 - 0.888) = 0.111

Therefore, the confidence interval can be expressed as:

p ± E = 0.888 ± 0.111

So the confidence interval is 0.777 < p < 0.999, which can also be written as p ± 0.111.

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In conclusion, while Mi-Young's sample is random and the population standard deviation is not known, the sample size is not large enough, and we cannot assume the population is normal. Thus, the requirements for a one-sample t-confidence interval for a mean have not been fully met in this case.

To determine if the requirements for a one-sample t-confidence interval for a mean have been met in Mi-Young's case, we should consider the following:

1. The sample is random: Mi-Young randomly selects 18 state employees, so this requirement is met.
2. The population is normal: We don't have enough information to determine this, but the Central Limit Theorem states that for sample sizes greater than or equal to 30, the sampling distribution is approximately normal. Since Mi-Young's sample size is smaller, we cannot assume the population is normal.
3. The sample size is large enough: Mi-Young's sample size is 18, which is smaller than the recommended size of 30 or more. Therefore, the sample size is not large enough.
4. The population standard deviation is not known: We have no information about the population standard deviation, so we assume it's not known.

In conclusion, while Mi-Young's sample is random and the population standard deviation is not known, the sample size is not large enough, and we cannot assume the population is normal. Thus, the requirements for a one-sample t-confidence interval for a mean have not been fully met in this case.

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The 99% confidence interval estimate for the population proportion is approximately 0.4172 to 0.5828, or 41.72% to 58.28% (rounded to two decimal places).

To construct a 99% confidence interval to estimate the population proportion with a sample proportion of 0.50 and a sample size of 250, we can use the formula for confidence intervals for proportions, which is given by:

Confidence Interval = Sample Proportion ± Critical Value * Standard Error

where:

Sample Proportion = 0.50 (given)

Sample Size (n) = 250 (given)

Confidence Level = 99% (given)

To find the critical value, we can refer to a standard normal distribution table or use a statistical calculator. For a 99% confidence level, the critical value is approximately 2.62 for a standard normal distribution.

The standard error (SE) for estimating a population proportion is given by the formula:

SE = sqrt[(p * (1 - p)) / n]

where:

p = sample proportion

n = sample size

Plugging in the given values:

Sample Proportion (p) = 0.50

Sample Size (n) = 250

SE = sqrt[(0.50 * (1 - 0.50)) / 250]

SE = sqrt[(0.50 * 0.50) / 250]

SE = sqrt(0.001)

SE = 0.0316 (rounded to four decimal places)

Now, we can plug the values for the sample proportion, critical value, and standard error into the confidence interval formula:

Confidence Interval = 0.50 ± 2.62 * 0.0316

Calculating the upper and lower bounds of the confidence interval:

Upper Bound = 0.50 + 2.62 * 0.0316

Upper Bound = 0.50 + 0.0828

Upper Bound = 0.5828 (rounded to four decimal places)

Lower Bound = 0.50 - 2.62 * 0.0316

Lower Bound = 0.50 - 0.0828

Lower Bound = 0.4172 (rounded to four decimal places)

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The farmer would need to sample at least 108 1-acre plots to estimate the mean yield per acre with a margin of error of 1 bushel and a 99% confidence level.

What is Standard deviation ?

Standard deviation is a measure of how spread out a set of data is from the mean (average) value. It tells you how much the individual data points deviate from the mean. A smaller standard deviation indicates that the data points are clustered closer to the mean, while a larger standard deviation indicates that the data points are more spread out.

a. To find the 99% confidence interval (CI) for the mean yield per acre, we can use the formula:

CI = X' ± Zα÷2 * σ÷√n

where X' is the sample mean, σ is the population standard deviation, n is the sample size, and Zα÷2 is the critical value for a 99% confidence level, which can be found using a standard normal distribution table or calculator.

Zα÷2 = 2.576 (from a standard normal distribution table for a 99% confidence level)

Substituting the given values, we get:

CI = 61.49 ± 2.576 * 3.754÷√25

CI = 61.49 ± 1.529

CI = (59.96, 63.02)

Therefore, we are 99% confident that the true mean yield per acre for the farmer using the organic method is between 59.96 and 63.02 bushels.

b. To find the sample size required to have a margin of error of 1 bushel and a 99% confidence level, we can use the formula:

n = (Zα÷2 * σ÷E)²

where Zα÷2 is the critical value for a 99% confidence level (2.576), σ is the population standard deviation (which we assume to be 3.754), and E is the desired margin of error (1 bushel).

Substituting the given values, we get:

n = (2.576 * 3.754÷1)²

n ≈ 108

Therefore, the farmer would need to sample at least 108 1-acre plots to estimate the mean yield per acre with a margin of error of 1 bushel and a 99% confidence level.

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To get the running time equation of the given program, let's analyse it step by step.

The program consists of the following operations:
Step:1. Check if the length of the list is less than 2.
Step:2. Divide the list into two parts (left and right).
Step:3. Iterate through the left part and calculate the sum.
Step:4. Call the function recursively on the left part.
The running time equation can be represented as T(n), where n is the length of the list. The steps can be analyzed as follows:
1. The comparison takes constant time, so O(1).
2. Dividing the list also takes constant time, O(1).
3. Iterating through the left part takes O(n/2) as it processes half of the list.
4. Recursively calling the function with half of the list will have a running time of T(n/2).
Putting everything together, we get the following equation: T(n) = T(n/2) + O(n/2) + O(1)
This represents the running time equation of the given program.

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The probability density function is f(x) = (1/5)e^(-x/5) for x >= 0, the probability it will take the mechanic less than 6 minutes to change oil is 0.699

a. The probability density function (PDF) for the time it takes a mechanic to change the oil in a car, given that it follows an exponential distribution with a mean of 5 minutes, is:

f(x) = (1/5)e^(-x/5) for x >= 0

b. The probability that it will take a mechanic less than 6 minutes to change the oil is given by:

P(X < 6) = ∫0^6 f(x) dx

= ∫0^6 (1/5)e^(-x/5) dx

= [-e^(-x/5)]_0^6

= 1 - e^(-6/5)

≈ 0.699

c. The probability that it will take a mechanic between 3 and 5 minutes to change the oil is given by:

P(3 < X < 5) = ∫3^5 f(x) dx

= ∫3^5 (1/5)e^(-x/5) dx

= [-e^(-x/5)]_3^5

= e^(-3/5) - e^(-1)

≈ 0.181

d. The variance of the time it takes to change the oil can be calculated using the formula:

Var(X) = σ^2 = 1/λ^2

where λ is the rate parameter of the exponential distribution, which is the reciprocal of the mean. Therefore, in this case:

λ = 1/5

σ^2 = (1/λ)^2 = 5^2 = 25

So, the variance of the time it takes to change the oil is 25.

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The correct state equations for the given transfer function model are (b) x2=1/3(6f(t)-10x1-6x2) and (e) x2=1/3(6f(t)-10x1-6x2).

The state equations represent the dynamics of a system in terms of its state variables. In this case, the given transfer function model relates the output variable y(s) to the input variable F(s) in the Laplace domain. The state variables are defined as x1 = y and x2 = y, which means both x1 and x2 represent the same variable y.

From the given transfer function, we can rewrite it in state-space form as follows:

y(s)/F(s) = 6/(3x2 + 6x + 10)

Multiplying both sides by (3x2 + 6x + 10) to eliminate the fraction, we get:

y(s) = 2x2 + 4x + 6/(3x2 + 6x + 10)F(s)

Now, we can express this equation in state-space form as:

x1' = x2

x2' = 1/3(6f(t) - 10x1 - 6x2)

where x1' and x2' represent the derivatives of x1 and x2 with respect to time t, respectively, and f(t) represents the input function in the time domain.

Therefore, the correct state equations for the given transfer function model are (b) x2=1/3(6f(t)-10x1-6x2) and (e) x2=1/3(6f(t)-10x1-6x2).

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The solution to the given trigonometric identity is: cos y

The problem we are given to solve is:

[(sec y - tan y)(sec y + tan y)]/(sec y)

Multiplying out the numerator gives us:

(sec²y - tan²y)/sec y

Dividing each term by sec y gives us:

sec y - ((tan²y)/sec y)

We know that tan y = sin y/cos y

Thus:

tan²y = (sin y/cos y)*(sin y/cos y)

1/cos y = sec y

Thus, we now have:

sec y - sin²y(sec y)

We can rewrite this as:

1/cos y - sin²y/cos y

= (1 - sin²y)/cos y

= cos²y/cos y

= cos y

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To determine whether there is convincing evidence that the true proportion of cockroaches that would die on plasterboard is different than the true proportion of cockroaches that would die on glass.

We need to conduct a hypothesis test.

Let p1 be the true proportion of cockroaches that would die on glass and p2 be the true proportion of cockroaches that would die on plasterboard.

The null hypothesis is that there is no difference between the true proportions, that is, H0: p1 = p2. The alternative hypothesis is that the true proportions are different, that is, Ha: [tex]p1 ≠ p2.[/tex]

We can use a two-sample proportion test to test this hypothesis. The test statistic is given by:

[tex]z = (p1 - p2) / sqrt(p_hat * (1 - p_hat) * (1/n1 + 1/n2))[/tex]

where p_hat [tex]= (x1 + x2) / (n1 + n2),[/tex] x1 and x2 are the number of cockroaches that died on glass and plasterboard, respectively, and n1 and n2 are the sample sizes.

Using the given data, we have:

[tex]p_hat = (25 + 18) / (36 + 36) = 0.694[/tex]

[tex]n1 = 36, n2 = 36[/tex]

[tex]x1 = 25, x2 = 18[/tex]

Plugging these values into the formula for the test statistic, we get:

[tex]z = (0.694 - 0.5) / sqrt(0.5 * 0.5 * (1/36 + 1/36)) = 1.414[/tex]

Using a standard normal distribution table or calculator, we find that the p-value for this test is approximately 0.157. Since this p-value is greater than the common significance level of 0.05, we fail to reject the null hypothesis.

Therefore, based on the given interval with null hypothesis, we do not have convincing evidence to suggest that the true proportion of cockroaches that would die on plasterboard is different than the true proportion of cockroaches that would die on glass.

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Since point A is an element of a direct variation, each point, other than A, that are elements of this direct variation are (-2, -8) and (2, 8).

In Mathematics, a direct variation is also referred to as direct proportion and it can be modeled by using the following mathematical expression or function:

y = kx

Where:

Under direct variation, the value of x represent an independent variable while the value of y represents the dependent variable. Therefore, the constant of proportionality (variation) can be calculated as follows:

Constant of proportionality (k) = y/x

Constant of proportionality (k) = -4/-1 = 8/2 = -8/-2

Constant of proportionality (k) = 4.

Therefore, the required function is given by;

y = kx

y = 4x

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For the cumulative distribution function, p(1 < X ≤ 2) ≈ 0.2222.

The probability p(1 < X ≤ 2) can be computed by finding the area under the curve of the probability density function (pdf) between x = 1 and x = 2.

Since the cumulative distribution function (cdf) is given, we can differentiate it to obtain the pdf. Thus, the pdf is:

f(x) = { 0, x < 0

18x, 0 ≤ x < 1/4

31/6 - 79x/12, 1/4 ≤ x < 2/3

0, x ≥ 2/3

The probability that 1 < X ≤ 2 can then be computed as follows:

p(1 < X ≤ 2) = ∫₁² f(x) dx

Using the pdf defined above, we can evaluate the integral as follows:

p(1 < X ≤ 2) = ∫₁^(2/3) (31/6 - 79x/12) dx

= [(31/6)x - (79/24)x^2]₁^(2/3)

= (31/6)(2/3) - (79/24)(4/9) - (0) (substituting x = 2/3 and x = 1)

= 0.2222

Therefore, p(1 < X ≤ 2) ≈ 0.2222.

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For the cumulative distribution function, p(1 < X ≤ 2) ≈ 0.2222.

The probability p(1 < X ≤ 2) can be computed by finding the area under the curve of the probability density function (pdf) between x = 1 and x = 2.

Since the cumulative distribution function (cdf) is given, we can differentiate it to obtain the pdf. Thus, the pdf is:

f(x) = { 0, x < 0

18x, 0 ≤ x < 1/4

31/6 - 79x/12, 1/4 ≤ x < 2/3

0, x ≥ 2/3

The probability that 1 < X ≤ 2 can then be computed as follows:

p(1 < X ≤ 2) = ∫₁² f(x) dx

Using the pdf defined above, we can evaluate the integral as follows:

p(1 < X ≤ 2) = ∫₁^(2/3) (31/6 - 79x/12) dx

= [(31/6)x - (79/24)x^2]₁^(2/3)

= (31/6)(2/3) - (79/24)(4/9) - (0) (substituting x = 2/3 and x = 1)

= 0.2222

Therefore, p(1 < X ≤ 2) ≈ 0.2222.

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Using the simple interest system, the interest rate for which Gary deposited $9,000 and earned $180 in interest after four months is 6%.

The simple interest system is based on the process of computing interest on the principal only for each period.

This contrasts with the compound interest system that charges interest on both accumulated interest and the principal.

The simple interest formula is given as SI = (P × R × T)/100, where SI = simple interest, P = Principal, R = Rate of Interest in % per annum, and T = Time.

The principal amount invested by Gary = $9,000

Time = 4 months = 4/12 years

Interest = $180

Therefore, 180 = ($9,000 x R x 4/12)/100

R = 180/($9,000 x 4/12)/100

R = 6%

Thus, the interest rate is 6%.

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Using the laws of simplification of fractions, we can find that in the simplest terms, cos M has a fraction value of 3/5.

In order to express a piece of a whole or a ratio of two numbers, a fraction requires a numerator (top number) and a denominator (bottom number) separated by a fraction bar.

The ratio of the neighbouring side to the hypotenuse of a right triangle is known as the cosine of an angle.

As a result, to calculate cos M, we must find the side that is perpendicular to M and divide it by the hypotenuse.

The length of the triangle's third side, KL, can be calculated using the Pythagorean theorem as shown below:

KL² + LM² = KM²

12² + 9² = 15²

144 + 81 = 225

225 = 15²

Taking the square root of both sides:

KL = √ (15² - 12²)

KL = √ (225 - 144)

KL = √81

KL = 9

As a result, angle M's neighbouring side, KL, has a length of 9. Therefore, by dividing 9 by 15, we can calculate cos M:

KL/KM = cos M = 9/15

To make this fraction simpler, divide the numerator and denominator by their 3 largest common factor:

cos M = (9/3)/ (15/3) = 3/5

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Answer:

C. 8x + 3y = 45

Step-by-step explanation:

Currently, the line we're given is in standard form, whose general form is

[tex]Ax+By=C[/tex]

We know that parallel lines have the same slope (m), as

[tex]m_{2}=m_{1}[/tex], where m2 is the slope of the line we're trying to find and m1 is the slope of the line we're given.

We don't know the slope (m1) of the line we're already given while the line is in standard form, but we can find it by converting the line from standard form to slope-intercept form, whose general form is

[tex]y=mx+b[/tex], where m is the slope and b is the y-intercept.

To convert from standard form to slope-intercept form, we must simply isolate y on the left-hand side of the equation:

[tex]8x+3y=15\\3y=-8x+15\\y=-8/3x+5[/tex]

Thus, the slope of the first line is -8/3 and the slope of the other line is also -8/3.

We can find the y-intercept of the other line by using the slope-intercept form and plugging in -8/3 for m, and (6, -1) for x and y:

[tex]-1=-8/3(6)+b\\-1=-16+b\\15=b[/tex]

Thus, the equation of the line in slope-intercept form is y = -8/3x + 15

We can covert this into standard form, first by clearing the fraction (multiply both sides by 3) and isolate the constant made after multiplying both sides by 3 on the right-hand side of the equation

[tex]3(y=-8/3x+15)\\3y=-8x+45\\8x+3y=45[/tex]

Answer:

7/2x+30

Step-by-step explanation:

(9/4x+6)-(-5/4x-24)

9/4x+6-(-5/4x)-(-24)

9/4x+6+5/4x+24

14/4x+30

7/2x+30

A test for two proportions and the null hypothesis would be the best test statistic to assess the variance in bacon consumption from 2011 to 2016.

The null hypothesis for the test is that the proportion of adults who consumed at least 3 pounds of bacon in 2011 is equivalent to the proportion of adults who consumed at least three pounds of bacon in 2016. A potential explanation would be that the percentage of adults who ate at least 3 pounds of bacon in 2011 and 2016 differed.

Additionally, the test statistic may be likened to a chi-squared distribution with one degree of freedom; hence, it is necessary to compute the test statistic's p-value in order to establish whether the null hypothesis can be ideally rejected or not.

Complete Question:

In 2011, 17 percent of a random sample of 200 adults in the United States indicated that they consumed at least 3 pounds of bacon that year. In 2016, 25 percent of a random sample of 600 adults in the United States indicated that they consumed at least 3 pounds of bacon that year.  Assuming all conditions for inference are met which is the most appropriate test statistic to determine variation of bacon consumption from 2011 to 2016 ?

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Answer:

b=7

Step-by-step explanation:

We know that for a parallelogram, The formula is a=bh

so plug it in

28=b4

Divide both sides by 4:

b=7

Answer:

b = 7 m

Step-by-step explanation:

the area (A) of a parallelogram is calculated as

A = bh ( b is the base and h the perpendicular height )

here h = 4 and A = 28 , then

28 = 4b ( divide both sides by 4 )

7 = b

In the given, the average life span for American women in 2000 was approximately 79.1 years.

The given equation for the average life span of American women from 1907 through 2007 is:

W(t) = 49.9 + 17.1 ln(t)

Here, t is measured in 20-year intervals, with t=1 corresponding to 1907.

To find the average life span for American women in a specific year, we need to first determine the corresponding value of t. For example, to find the average life span in 1950, we can use:

t = (1950 - 1907) / 20 + 1 = 3.22

Using this value of t in the equation, we get:

W(3.22) = 49.9 + 17.1 ln(3.22) ≈ 68.5 years

Therefore, the average life span for American women in 1950 was approximately 68.5 years.

Similarly, we can find the average life span for other years by using the corresponding values of t. For example, for the year 2000, we have:

t = (2000 - 1907) / 20 + 1 = 5.65

W(5.65) = 49.9 + 17.1 ln(5.65) ≈ 79.1 years

Therefore, the average life span for American women in 2000 was approximately 79.1 years.

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It states that as the sample size increases, the distribution of the sample mean approaches a normal distribution regardless of the underlying population distribution.

A numerical measure calculated from a sample is known as a statistic. A statistic is a summary measure that describes a characteristic of a sample. It is used to estimate the corresponding population parameter.

For example, the sample mean is a statistic that summarizes the average value of a variable in the sample. This value can be used to estimate the population mean, which is the parameter that describes the average value of the variable in the entire population.

In contrast, a parameter is a numerical measure that describes a characteristic of a population. It is typically unknown and must be estimated from a sample. Examples of parameters include the population mean, population standard deviation, population proportion, etc.

The central limit theorem is a statistical theory that describes the behavior of the mean of a large number of independent, identically distributed random variables. It states that as the sample size increases, the distribution of the sample mean approaches a normal distribution regardless of the underlying population distribution.

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The answer for the differential equation is:

f(theta) = -sin(theta) - cos(theta) + 4*theta + 2

To solve for f(theta), we need to integrate twice since f''(theta) is given.

First, we integrate f''(theta) with respect to theta to get:

f'(theta) = -cos(theta) + sin(theta) + C₁

where C₁ is an arbitrary constant of integration.

Next, we integrate f'(theta) with respect to theta to get:

f(theta) = -sin(theta) - cos(theta) + C₁*theta + C₂

where C₂ is another arbitrary constant of integration.

To solve for C₁ and C₂, we use the initial conditions given:

f(0) = 2 => C₂ = 2

f'(0) = 2 => C₁ = 4

Therefore, the solution to the differential equation is:

f(theta) = -sin(theta) - cos(theta) + 4*theta + 2

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The probability that the time between two events is less than or equal to 14 minutes is 0.865.

An exponential probability distribution is used to model the time between two events that occur randomly and independently of each other, and the probability density function of the distribution is given by:

f(x) = λe^(-λx)

where λ is the rate parameter and is equal to the inverse of the mean, λ = 1/μ.

In this problem, we are given that the mean is equal to 5 minutes per customer, so μ = 5. Therefore, the rate parameter λ = 1/5 = 0.2.

a) P(x ≤ 10)

To find this probability, we need to integrate the probability density function from 0 to 10:

P(x ≤ 10) = ∫0^10 λe^(-λx) dx

= -e^(-λx)|0^10

= -e^(-0.2*10) + 1

= 0.632

Therefore, the probability that the time between two events is less than or equal to 10 minutes is 0.632.

b) P(x ≤ 5)

To find this probability, we need to integrate the probability density function from 0 to 5:

P(x ≤ 5) = ∫0^5 λe^(-λx) dx

= -e^(-λx)|0^5

= -e^(-0.2*5) + 1

= 0.393

Therefore, the probability that the time between two events is less than or equal to 5 minutes is 0.393.

c) P(x ≤ 4)

To find this probability, we need to integrate the probability density function from 0 to 4:

P(x ≤ 4) = ∫0^4 λe^(-λx) dx

= -e^(-λx)|0^4

= -e^(-0.2*4) + 1

= 0.329

Therefore, the probability that the time between two events is less than or equal to 4 minutes is 0.329.

d) P(x ≤ 14)

To find this probability, we need to integrate the probability density function from 0 to 14:

P(x ≤ 14) = ∫0^14 λe^(-λx) dx

= -e^(-λx)|0^14

= -e^(-0.2*14) + 1

= 0.865

Therefore, the probability that the time between two events is less than or equal to 14 minutes is 0.865.

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