4. Find solution of the system of equations. Use D-operator elimination method. 4 -5 X' = (₁-3) x X Write clean, and clear. Show steps of calculations.

A solution of a differential equation is sometimes referred to as an integral of the equation and its graph is called the slope field.

When we integrate differential equations, we get a solution. Differential equations are integrated to find the functions. The integration method is used to solve the differential equation. A differential equation can be solved through integration. In essence, the integration method provides a way to solve differential equations by means of a family of functions which differ only by a constant. We can calculate the differential equation solutions by using various methods such as separation of variables, homogeneous differential equations, linear differential equations, etc.

We can plot the solution of a differential equation on a slope field. The slope field graph shows the slope of the solution curves at various points in the xy-plane, which can help us visualize the behavior of the solutions of a differential equation. The slope field graph of a differential equation shows a field of slopes at various points in the xy-plane. These slopes are calculated from the differential equation at each point, and they provide a visual representation of how the solution curves behave in the xy-plane. The slope field graph can help us see how the solution curves behave as we move along the xy-plane, and it can help us determine the shape and characteristics of the solution curves.

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To find the mean and standard deviation in the number of errors per page, we can use the given data and apply the formulas for calculating the mean and standard deviation.

Let's denote the number of errors as x and the number of pages as n.

Step 1: Calculate the product of errors and pages for each category:

(0 errors) x (102 pages) = 0

(1 error) x (138 pages) = 138

(2 errors) x (140 pages) = 280

(3 errors) x (79 pages) = 237

(4 errors) x (33 pages) = 132

(5 errors) x (8 pages) = 40

Step 2: Calculate the sum of the products:

∑(x * n) = 0 + 138 + 280 + 237 + 132 + 40 = 827

Step 3: Calculate the total number of pages:

∑n = 102 + 138 + 140 + 79 + 33 + 8 = 500

Step 4: Calculate the mean (μ):

μ = ∑(x * n) / ∑n = 827 / 500 ≈ 1.654

Step 5: Calculate the squared deviations from the mean for each category:

(0 - 1.654)² * 102 = 273.528

(1 - 1.654)² * 138 = 102.786

(2 - 1.654)² * 140 = 102.786

(3 - 1.654)² * 79 = 105.899

(4 - 1.654)² * 33 = 56.986

(5 - 1.654)² * 8 = 16.918

Step 6: Calculate the sum of the squared deviations:

∑(x - μ)² * n = 273.528 + 102.786 + 102.786 + 105.899 + 56.986 + 16.918 = 658.903

Step 7: Calculate the variance (σ²):

σ² = ∑(x - μ)² * n / ∑n = 658.903 / 500 ≈ 1.318

Step 8: Calculate the standard deviation (σ):

σ = √σ² = √1.318 ≈ 1.147

Therefore, the mean number of errors per page is approximately 1.654, and the standard deviation is approximately 1.147.

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The budget set is not a convex set since it is not a straight line connecting the two endpoints of the budget lines, and there are points outside the budget set that can be reached by the consumer.

To show that the budget set is not a convex set. Suppose the consumer spends all of their income on commodity x. Then, they can purchase a maximum of 10 units of commodity x at a price of $1 each. So, their budget line would look like this: Budget line for commodity x Let's now consider the case where the consumer spends all of their income on commodity y.

Suppose the consumer buys only 1 unit of commodity y. Then, they spend $2 and have $8 left. With this $8, they can buy 4 more units of commodity y at a price of $1.50 each. So, their budget line would look like this: Budget line for commodity y If we plot the two budget lines on the same graph, we get the following picture: Budget lines for both commodities As we can see, the budget set is not a convex set since it is not a straight line connecting the two endpoints of the budget lines, and there are points outside the budget set that can be reached by the consumer. Therefore, the budget set is not a convex set.

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Based on the hypothesis test, there is not enough evidence to support the claim that the average number of sick days a worker takes per year is less than 5.

To determine if there is enough evidence to support the researcher's claim that the average number of sick days a worker takes per year is less than 5, we can conduct a hypothesis test.

State the hypotheses and identify the claim.

Null hypothesis (H0): The average number of sick days per year is 5.

Alternative hypothesis (Ha): The average number of sick days per year is less than 5 (researcher's claim).

Compute the test value.

We can calculate the test value using the formula:

Test value = (Sample Mean - Population Mean) / (Population Standard Deviation / sqrt(Sample Size))

Test value = (4.6 - 5) / (1.2 / sqrt(26))

Test value ≈ -1.75

Find the P-value.

To find the P-value, we can refer to the t-distribution table or use statistical software. Given that the test is one-tailed and the significance level is 0.10 (0.107 rounded to two decimal places), we find that the P-value is greater than 0.10.

Make the decision.

Since the P-value is greater than the significance level of 0.10, we fail to reject the null hypothesis. There is not enough evidence to support the claim that the average number of sick days per year is less than 5.

Summarize the results.

Based on the hypothesis test, we conclude that there is not enough evidence to support the researcher's claim. The average number of sick days per year is not significantly less than 5.

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The system of equations represented by the given matrix in reduced echelon form is:

x + 2y - z = 1

4y + 5z = 3

7z = 4

The given matrix represents a system of linear equations in reduced echelon form. Each row in the matrix corresponds to an equation, and each column represents the coefficients of the variables x, y, and z, respectively. The non-zero elements in each row indicate the coefficients of the variables in the corresponding equation.

The first row of the matrix corresponds to the equation x + 2y - z = 1. The second row represents the equation 4y + 5z = 3, and the third row corresponds to the equation 7z = 4.

In the first equation, the coefficient of x is 1, the coefficient of y is 2, and the coefficient of z is -1. The constant term is 1.

The second equation has a coefficient of 4 for y and 5 for z. The constant term is 3.

The third equation has a coefficient of 7 for z and a constant term of 4.

These equations represent a system of linear equations that can be solved simultaneously to find the values of the variables x, y, and z.

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The solution to the given differential equation using the Method of Undetermined Coefficients is -A² sin(x) - 4 A cos(x) = 12.

To solve the given differential equation, y'' + 4y' = 12[tex]e^{(-\sin(x))}[/tex].  Here can use the Method of Undetermined Coefficients.

First, let's find the complementary solution by solving the homogeneous equation y'' + 4y' = 0. The characteristic equation is obtained by substituting y = e(mx) into the equation, where m is an unknown constant:

m + 4m=0

Solving this quadratic equation gives us two roots:

m = 0 and m = -4.

Therefore, the complementary solution is given by

[tex]y_c = c_1 + c_2 e^{(-4x)}[/tex]

where,

c₁ and c₂ are arbitrary constants.

Next, we need to find a particular solution for the non-homogeneous term 12[tex]e^{(-\sin(x))}[/tex]. Since the right-hand side is a product of exponential and trigonometric functions, we can assume a particular solution of the form:

[tex]y_p = A \times e^{(-\sin(x))}[/tex]

where,

A is a constant to be determined.

Differentiating yp twice with respect to x, we obtain:

[tex]y_p'' = (A \cos(x) - A^{2 \sin(x))} \times e^{(-\sin(x))}\\[/tex]

[tex]y_p' = -A \times \cos(x) \times e^{(-\sin(x))}[/tex]

Substituting these into the original differential equation, we get:

[tex][A \cos(x) - A^{(2 \sin(x))} e^{(-\sin(x))} + 4 (-A \times \cos(x) \times e^{(-\sin(x))}][/tex]

[tex]= 12e^{(-\sin(x))}[/tex]

Simplifying and equating the coefficients of like terms, we find:

-A² sin(x) - 4 Acos(x) = 12.

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Therefore, the probability of getting at least 63 questions correct using both binomial and normal probability distributions are: P(X = 63) = 0.0082 (approx) P(X ≥ 63) = 0 (approx)

The binomial probability distribution is used when there are two possible outcomes, success or failure, in a sequence of independent trials. The binomial probability distribution can be used when the sample size is small (less than 30) and the population size is known.

The formula for binomial probability is: P(X = k) = (nCk) * p^k * (1-p)^(n-k)

where P(X = k) is the probability of getting k successes, n is the total number of trials, k is the number of successes, p is the probability of success and (1-p) is the probability of failure. nCk is the combination of n and k.

Calculation of probability of getting 63 questions correct using binomial probability distribution:

p = probability of getting a question correct = 1/5n = total number of questions = 86k = number of correct answers required = 63P(X = 63) = (nCk) * p^k * (1-p)^(n-k)= (86C63) * (1/5)^63 * (4/5)^23= 0.0082 (approx)

Normal probability distribution is used when the sample size is large (greater than or equal to 30). It is also used when the population size is unknown. The mean of the normal probability distribution is calculated using the formula:

μ = np

where μ is the mean, n is the total number of trials, and p is the probability of success. The standard deviation is calculated using the formula:

σ = sqrt(np(1-p))

where σ is the standard deviation.

Calculation of mean and standard deviation:

μ = np = 86 * 1/5 = 17.2

σ = sqrt(np(1-p))=

sqrt(86 * 1/5 * 4/5)= 3.01

Calculation of probability of getting 63 questions correct using normal probability distribution:

Using the normal distribution function, we need to find the probability of getting 63 or more questions correct. We can assume a continuity correction factor of 0.5 to include values between two integers.

z = (x - μ + 0.5) / σ= (63 - 17.5 + 0.5) / 3.01= 15.83

The probability of getting 63 or more questions correct is:

P(X ≥ 63) = P(Z ≥ 15.83) = 0 (approx)

Therefore, the probability of getting at least 63 questions correct using both binomial and normal probability distributions are:

P(X = 63) = 0.0082 (approx) P(X ≥ 63) = 0 (approx)

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The probability of a randomly selected turkey weighing less than 12 pounds is 0.0228 or 2.28%.

When we talk about probability, it means the likelihood of an event to happen. The probability of an event is always between 0 and 1. A probability of 0 means that the event is impossible and a probability of 1 means that the event is certain. The probability that a randomly selected turkey weighs less than 12 pounds can be found using a normal distribution table. The normal distribution table is a tool used to find probabilities associated with the normal distribution of a random variable. The normal distribution table gives the probability of a random variable being less than a certain value or between two values.Given that the mean weight of turkeys is 16 pounds and the standard deviation is 2 pounds. To find the probability that a randomly selected turkey weighs less than 12 pounds, we need to standardize the weight using the z-score formula. The z-score formula is given as follows;$$z = \frac{x - \mu}{\sigma}$$where x is the value of the random variable, μ is the mean of the distribution and σ is the standard deviation of the distribution.Using the formula above, we have;$$z = \frac{12 - 16}{2} = -2$$We then use the normal distribution table to find the probability of z being less than -2. From the table, the probability of z being less than -2 is 0.0228. Therefore, the probability that a randomly selected turkey weighs less than 12 pounds is 0.0228 or 2.28%.The probability of a randomly selected turkey weighing less than 12 pounds is 0.0228 or 2.28%.

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The probability that a randomly selected turkey weighs less than 12 pounds is given by P = 0.023

Given data ,

To find the probability that a randomly selected turkey weighs below 12 pounds, we again need to standardize the value using the z-score formula:

z = (x - mean) / standard deviation

where x = 12, mean = 22, and standard deviation = 5.

z = (12 - 22) / 5 = -2

Now, we can find the probability to the left of this z-score using a standard normal distribution table or calculator.

P(x < 12) = P(z < -2)

Using a standard normal distribution table , the probability is approximately 0.0228.

Rounded to three decimal places, the probability that a randomly selected turkey weighs below 12 pounds is 0.023.

Hence , the probability is P = 2.3 %

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The complete question is attached below :

The weight of turkeys is normally distributed with a mean of 22 pounds and a standard deviation of 5 pounds.

a. Find the probability that a randomly selected turkey weighs below 12 pounds. Round to 3 decimals and keep '0' before the decimal point.

The relation is symmetric and antisymmetric. Therefore, the correct option is Cantisyymetric. The given relation is yRx ⇔ y + x = 0. Let x, y, and z be real numbers.

The reflexive relation is a relation R on set A where each element of A is related to itself. The given relation y + x = 0 is not reflexive since there exists real numbers x, y such that y + x ≠ 0.

The symmetric relation is a relation R on set A where for any elements a, b ∈ A, if (a, b) ∈ R then (b, a) ∈ R.The given relation y + x = 0 is symmetric since if (y, x) ∈ R then (x, y) ∈ R.

Antisymmetric relation is a relation R on set A where for any elements a, b ∈ A, if (a, b) ∈ R and (b, a) ∈ R, then a = b. The given relation y + x = 0 is antisymmetric since if (y, x) ∈ R and (x, y) ∈ R, then y = -x.

Transitive relation is a relation R on set A where for any elements a, b, and c ∈ A, if (a, b) ∈ R and (b, c) ∈ R, then (a, c) ∈ R. The given relation y + x = 0 is transitive since if (y, x) ∈ R and (x, z) ∈ R, then (y, z) ∈ R.

Hence, the relation is symmetric and antisymmetric. Therefore, the correct option is Cantisyymetric.

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a) The probability that in a group of 9 couples, at least 6 husbands have a college degree can be calculated using the binomial probability formula.

b) In a group of 24 couples, the expected number of husbands with a college degree is 15.6, and the standard deviation is approximately 2.35.

a) To find the probability that at least 6 husbands have a college degree in a group of 9 couples, we can use the binomial probability formula. Let's denote the probability of a husband having a college degree as p = 0.65 and the number of couples as n = 9.

The probability mass function for the binomial distribution is given by P(X = k) = C(n, k) * p^k * (1 - p)^(n - k), where X is the number of husbands with a college degree and k is the number of husbands with a college degree.

To find the probability of at least 6 husbands having a college degree, we sum the probabilities of having 6, 7, 8, and 9 husbands with a college degree:

P(X ≥ 6) = P(X = 6) + P(X = 7) + P(X = 8) + P(X = 9)

P(X = k) = C(9, k) * 0.65^k * (1 - 0.65)^(9 - k)

Calculating each term and summing them up will give us the desired probability.

b) To find the expected number of husbands with a college degree in a group of 24 couples, we multiply the probability of a husband having a college degree (p = 0.65) by the number of couples (n = 24):

Expected number = p * n

To find the standard deviation of the number of husbands with a college degree, we use the formula for the standard deviation of a binomial distribution:

Standard deviation = sqrt(n * p * (1 - p))

Plug in the values of n and p to calculate the standard deviation.

Please note that in both parts, we assume that each couple is independent, and the probability of a husband having a college degree is constant across all couples.

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To prove that the set {ū1, ū2, ū3, ..., ūn} is linearly dependent, we can start by assuming that there exist scalars a1, a2, ..., an (not all zero) such that:

a1 ū1 + a2 ū2 + a3 ū3 + ... + an ūn = 0.

Now, since each ūi is a linear combination of the vectors v1, v2, ..., vn, we can express each ūi as follows:

ū1 = c11v1 + c12v2 + c13v3 + ... + c1nvn,

ū2 = c21v1 + c22v2 + c23v3 + ... + c2nvn,

...

ūn = cn1v1 + cn2v2 + cn3v3 + ... + cnnvn,

where ci1, ci2, ..., cin are scalars for each i.

Substituting these expressions into the assumed equation, we get:

(a1)(c11v1 + c12v2 + c13v3 + ... + c1nvn) + (a2)(c21v1 + c22v2 + c23v3 + ... + c2nvn) + ... + (an)(cn1v1 + cn2v2 + cn3v3 + ... + cnnvn) = 0.

Expanding this equation, we have:

(a1c11v1 + a1c12v2 + a1c13v3 + ... + a1c1nvn) + (a2c21v1 + a2c22v2 + a2c23v3 + ... + a2c2nvn) + ... + (ancn1v1 + ancn2v2 + ancn3v3 + ... + ancnnvn) = 0.

Now, since {v1, v2, v3, ..., vn} are linearly independent, we know that the only way this sum can be equal to zero is if each coefficient is zero. Therefore, we have:

a1c11 = 0,

a1c12 = 0,

a1c13 = 0,

...

a1c1n = 0,

a2c21 = 0,

a2c22 = 0,

a2c23 = 0,

...

a2c2n = 0,

...

an(cn1) = 0,

an(cn2) = 0,

an(cn3) = 0,

...

an(cnn) = 0.

Since ai's are not all zero (as assumed), and {v1, v2, v3, ..., vn} are linearly independent, it follows that ci1, ci2, ..., cin must be zero for each i.

Hence, all the coefficients ci1, ci2, ..., cin are zero, which implies that each ūi is the zero vector. Thus, the set {ū1, ū2, ū3, ..., ūn} is linearly dependent.

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The linear combination of {ū₁, ū₂, ..., ūₙ} using these scalars is not trivial and equals the zero vector, indicating that {ū₁, ū₂, ..., ūₙ} is linearly dependent.

To prove that {ū₁, ū₂, ..., ūₙ} is linearly dependent given that {v₁, v₂, ..., vₙ} are linearly independent vectors in vector space V, we need to show that there exist scalars c₁, c₂, ..., cₙ (not all zero) such that the linear combination of {ū₁, ū₂, ..., ūₙ} using these scalars equals the zero vector.

Since {ū₁, ū₂, ..., ūₙ} are each linear combinations of {v₁, v₂, ..., vₙ}, we can express them as:

ū₁ = a₁v₁ + a₂v₂ + ... + aₙvₙ

ū₂ = b₁v₁ + b₂v₂ + ... + bₙvₙ

...

ūₙ = z₁v₁ + z₂v₂ + ... + zₙvₙ

where a₁, a₂, ..., aₙ, b₁, b₂, ..., bₙ, ..., z₁, z₂, ..., zₙ are scalars.

Now, let's consider the linear combination of {ū₁, ū₂, ..., ūₙ} using scalars c₁, c₂, ..., cₙ:

c₁ū₁ + c₂ū₂ + ... + cₙūₙ

Expanding this expression:

c₁(a₁v₁ + a₂v₂ + ... + aₙvₙ) + c₂(b₁v₁ + b₂v₂ + ... + bₙvₙ) + ... + cₙ(z₁v₁ + z₂v₂ + ... + zₙvₙ)

We can rearrange the terms and factor out the vᵢ vectors:

(v₁(c₁a₁ + c₂b₁ + ... + cₙz₁)) + (v₂(c₁a₂ + c₂b₂ + ... + cₙz₂)) + ... + (vₙ(c₁aₙ + c₂bₙ + ... + cₙzₙ))

Since {v₁, v₂, ..., vₙ} are linearly independent vectors, in order for the linear combination to equal the zero vector, the coefficients multiplying each vᵢ must be zero:

c₁a₁ + c₂b₁ + ... + cₙz₁ = 0

c₁a₂ + c₂b₂ + ... + cₙz₂ = 0

...

c₁aₙ + c₂bₙ + ... + cₙzₙ = 0

This is a system of linear equations with n equations and n variables (c₁, c₂, ..., cₙ). Since {a₁, a₂, ..., aₙ}, {b₁, b₂, ..., bₙ}, ..., {z₁, z₂, ..., zₙ} are given and not all zero, this system of equations has a non-trivial solution, meaning there exist scalars c₁, c₂, ..., cₙ (not all zero) that satisfy the equations.

Therefore, the linear combination of {ū₁, ū₂, ..., ūₙ} using these scalars is not trivial and equals the zero vector, indicating that {ū₁, ū₂, ..., ūₙ} is linearly dependent.

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The calculated probability that x equals 2 is 0.14

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

x 1 2 3 4

p(x ≤ x) 0.30 0.44 0.72 1.00

From the above cumulative distribution function for the discrete random variable x, we have

p(x ≤ 2) = 0.44

p(x ≤ 1) = 0.30

Using the above as a guide, we have the following:

P(x = 2) = p(x ≤ 2) - p(x ≤ 1)

Substitute the known values in the above equation, so, we have the following representation

P(x = 2) = 0.44 - 0.30

Evaluate

P(x = 2) = 0.14

Hence, the probability that x equals 2 is 0.14

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All the four statements are true.

a) The statement is false. Two graphs can satisfy all the mentioned conditions and still not be isomorphic. Isomorphism requires a one-to-one correspondence between the vertices of the graphs that preserves adjacency and non-adjacency relationships.

b) The statement is true. If a relation R on a set A is transitive, then for any elements a, b, and c in A, if (a, b) and (b, c) are in R, then (a, c) must also be in R. The composition of relations, denoted by R², represents the composition of all possible pairs of elements in R. If R² CR, it means that for any (a, b) in R², if (a, b) is in R, then (a, b) is in R² as well, satisfying the definition of transitivity.

c) The statement is true. If a relation R on a set A is symmetric, it means that for any elements a and b in A, if (a, b) is in R, then (b, a) must also be in R. When taking the composition of R with itself (R²), the symmetry property is preserved since for any (a, b) in R², (b, a) will also be in R².

d) The statement is true. If R is an equivalence relation and [a]r ^ [b]r ‡ Ø, it means that [a]r and [b]r are non-empty and intersect. Since R is an equivalence relation, it implies that the equivalence classes form a partition of the set A. If two equivalence classes intersect, it means they are the same equivalence class. Therefore, [a]r = [b]r, as they both belong to the same equivalence class.

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Answer: The Laplace transform of a function f(t) is,

L{(t – 4)'u(t)} = [tex]1/s^2[/tex]

Step-by-step explanation:

The Laplace transform of a function is a mathematical operation that changes a time-domain function into its equivalent frequency-domain representation.

The Laplace transform of a function f(t) is denoted by L{f(t)}.

Below are the Laplace transforms of the given functions:

(a) y(t) = 14

Laplace transform of y(t) = 14 is:

L{14} = 14/s

(b) y(t) = 23

Laplace transform of

y(t) = 23+ is:

L{23+} = 23/s

(c) y(t) = sin(2t)

Laplace transform of y(t) = sin(2t) is:

L{sin(2t)} = [tex]2/(s^2+4)[/tex]

(d) y(t) =[tex]e^(-13t)[/tex]

Laplace transform of

y(t) = [tex]e^(-13t)[/tex]is:

[tex]L{e^(-13t)}[/tex] = 1/(s+13)

(e) y(t) = (t – 4)'u(t)

Laplace transform of

y(t) = (t – 4)'u(t) is:

L{(t – 4)'u(t)} = [tex]1/s^2[/tex]

Note: 'u' represents the unit step function.

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The revenue, R(q), is given by the equation R(q) = q³ - 3q² + 100q.

To find the revenue, we use the formula R(q) = q * C(q), where q represents the quantity and C(q) represents the average cost.

In this case, the average cost is given as C(q) = q² - 3q + 100.

To calculate the revenue, we substitute the expression for C(q) into the revenue formula:

R(q) = q * (q² - 3q + 100)

Expanding the expression, we get:

R(q) = q³ - 3q² + 100q

This equation represents the revenue as a function of the quantity, q. By plugging in different values for q, we can calculate the corresponding revenue values. The revenue represents the total income generated from selling a certain quantity of products or services.

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The equation of the parabola is y = (1/4)(x - 9.25)²+ 9. The arch is in the shape of a parabola with a span of 360 meters and a maximum height of 30 meters.

The equation of the parabola with directrix x = 0.75 and focus (9.25, 9) can be determined using the standard form of a parabolic equation: y = a(x - h)² + k. Given that the directrix is a vertical line x = 0.75, the vertex of the parabola is located midway between the directrix and the focus, at the point (h, k).

The x-coordinate of the vertex is the average of the directrix and focus x-coordinates, which gives us h = (0.75 + 9.25) / 2 = 5.5. Since the parabola opens upwards, the y-coordinate of the vertex is equal to k, which is 9. The coefficient 'a' can be found by using the distance formula between the focus and the vertex. The distance between (9.25, 9) and (5.5, 9) is 4.75, which is equal to 1/(4a). Solving for 'a', we get a = 1/4. Thus, the equation of the parabola is y = (1/4)(x - 9.25)² + 9.

For the arch, the equation of the parabola can be obtained by considering its span and maximum height. The vertex of the parabola represents the highest point of the arch, which corresponds to the maximum height of 30 meters. Therefore, the vertex of the parabola is at (0, 30). The span of the arch, which is the distance between the leftmost and rightmost points, is 360 meters. Since the arch is symmetric, the x-coordinate of the vertex gives us the midpoint of the span, which is 0. The coefficient 'a' can be found by using the maximum height. The distance between the vertex (0, 30) and any other point on the parabola with a y-coordinate of 24 is 6, which is equal to 1/(4a). Solving for 'a', we get a = 1/24. Thus, the equation of the parabola representing the arch is y = (1/24)x² + 30.To determine the distance from the center at which the height of the arch is 24 meters, we substitute y = 24 into the equation of the parabola and solve for x. Plugging in y = 24 and a = 1/24 into the equation y = (1/24)x² + 30, we get 24 = (1/24)x² + 30. By rearranging the equation, we have (1/24)x² = -6. Simplifying further, we find x² = -144, which does not have a real solution. Hence, the height of 24 meters cannot be achieved by the arch.

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Given: The one-to-one functions g and h are defined as follows. To find g¹(-8):To find g¹(-8), we need to find x such that g(x) = -8.  [tex](h - h-¹)(-5) = -24[/tex] is the final answer. Here's how to do it:

Step-by-step answer:

Given function is [tex]g=((-8, 6), (-6, 7). (-1, 1), (0, -8))[/tex]

Let's find[tex]g¹(-8)[/tex]

Now, [tex]g = {(-8, 6), (-6, 7), (-1, 1), (0, -8)}[/tex]

Now, to find [tex]g¹(-8)[/tex], we need to find the value of x such that g(x) = -8.

So, [tex]g(x) = -8[/tex]

If we look at the given set, we have the element (-8, 6) as part of the function g.

So, the value of x such that [tex]g(x) = -8 is -8.[/tex]

Since this is one-to-one function, we can be sure that this value of x is unique. Hence,[tex]g¹(-8) = -8[/tex]

To find h-¹(x):

Given function is h(x) = 3x - 8

Let's find h-¹(x)To find the inverse of the function h(x), we need to interchange x and y and then solve for y in terms of x.

So, x = 3y - 8x + 8 = 3y

(Dividing both sides by 3)y = (x + 8)/3

Therefore,[tex]h-¹(x) = (x + 8)/3[/tex]

Now, let's find [tex](h - h-¹)(-5):(h - h-¹)(-5)[/tex]

[tex]= h(-5) - h-¹(-5)[/tex]

Now, h(-5)

= 3(-5) - 8

[tex]= -23h-¹(-5)[/tex]

= (-5 + 8)/3

= 1

So, [tex](h - h-¹)(-5) = -23 - 1[/tex]

= -24

Hence, [tex](h - h-¹)(-5) = -24[/tex] is the final answer.

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To compute the determinants of the matrices A₁, A₂, A₃, A₄, and As obtained from Ao through the specified operations, we need to apply the given operations to the matrix Ao and calculate the determinant at each step.

Given:

Ao is a 5 x 5 matrix with det(Ao) = -3.

a) A₁: Obtained from Ao by multiplying the fourth row of Ao by 2.

To compute det(A₁), we need to perform the specified operation on Ao and calculate the determinant.

A₁ = Ao (after multiplying the fourth row by 2)

det(A₁) = 2 * det(Ao) (multiplying a row by a scalar multiplies the determinant by the same scalar)

det(A₁) = 2 * (-3) = -6

b) A₂: Obtained from A₁ by swapping the first and last rows of A₁.

To compute det(A₂), we need to perform the specified operation on A₁ and calculate the determinant.

A₂ = A₁ (after swapping the first and last rows of A₁)

det(A₂) = det(A₁) (swapping rows does not change the determinant)

det(A₂) = -6

c) A₃: Obtained from A₂ by multiplying A₂ by itself.

To compute det(A₃), we need to perform the specified operation on A₂ and calculate the determinant.

A₃ = A₂ * A₂ (multiplying A₂ by itself)

det(A₃) = det(A₂) * det(A₂) (multiplying matrices multiplies their determinants)

det(A₃) = (-6) * (-6) = 36

d) A₄: Obtained from A₃ by replacing the second row with the sum of itself plus 3 times the third row.

To compute det(A₄), we need to perform the specified operation on A₃ and calculate the determinant.

A₄ = A₃ (after replacing the second row with the sum of itself plus 3 times the third row)

det(A₄) = det(A₃) (replacing rows does not change the determinant)

det(A₄) = 36

e) As: Obtained from A₄ by scaling A₄ by the number 2.

To compute det(As), we need to perform the specified operation on A₄ and calculate the determinant.

As = 2 * A₄ (scaling A₄ by 2)

det(As) = 2 * det(A₄) (scaling a matrix multiplies the determinant by the same scalar)

det(As) = 2 * 36 = 72

Therefore, the determinants of the matrices obtained through the given operations are:

det(A₁) = -6,

det(A₂) = -6,

det(A₃) = 36,

det(A₄) = 36,

det(As) = 72.

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To differentiate the function f(x) = x³ + 4x² - 9x + 8, we can apply the power rule of differentiation. The power rule states that the derivative of x^n, where n is a constant, is given by n*x^(n-1).

Differentiating each term:

d/dx (x³) = 3x^(3-1) = 3x²

d/dx (4x²) = 4*2x^(2-1) = 8x

d/dx (-9x) = -9*1x^(1-1) = -9

d/dx (8) = 0 (since the derivative of a constant is always zero)

Combining the derivatives:

f'(x) = 3x² + 8x - 9

Therefore, the derivative of f(x) = x³ + 4x² - 9x + 8 is f'(x) = 3x² + 8x - 9.

The derivative f'(x) represents the rate of change of the function f(x) at any given point x. It provides information about the slope of the tangent line to the graph of f(x) at that point.

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a) Four-quarter and centered moving averages were computed for the quarterly gasoline sales. b) The average seasonal variable was calculated using the multiplicative model. c) Quarterly forecasts for the next year were made using the multiplicative model.

a) The four-quarter moving average is calculated by taking the average of the gasoline sales for each quarter over the past four years. This provides a smoothed value that helps identify trends over a longer time period. The centered moving average is a similar calculation, but it assigns the average value to the middle quarter of the four, providing a more centered perspective on the data.

b) To calculate the average seasonal variable using the multiplicative model, the gasoline sales for each quarter are divided by the corresponding four-quarter moving average. This helps to identify the seasonal fluctuations or patterns in the data. By averaging the seasonal variables for the four quarters, we can determine the overall average effect of the seasonal patterns on the sales.

c) To forecast quarterly sales for the next year using the multiplicative model, we multiply the seasonal variable for each quarter by the corresponding four-quarter moving average for that quarter. This incorporates the seasonal patterns into the forecasted values, allowing us to estimate the expected sales for each quarter based on historical data.

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The correct option is: The graph is centered around 0.

The statement that is NOT a descriptor of a normal distribution of a random variable is "The graph is centered around 0.

"The normal distribution is a symmetric probability distribution. Its curve is bell-shaped and symmetrical around the mean µ. It means that the distribution's mean is located in the center of the curve. Therefore, the statement

"The graph is centered around the mean" is true.

However, the statement that is not a descriptor of a normal distribution of a random variable is "The graph is centered around 0." The standard normal distribution is the only normal distribution that has its mean at zero (0) and its standard deviation at one (1). Hence, the correct option is: The graph is centered around 0.

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The PDF of W is fW(w) = c(w⁴ - 5w³ + 10w² - 10w + 4).

We are given the joint probability density function (PDF) for random variables X and Y, which is:

fx,y (x, y) = { cx³y², 0 ≤ x, y ≤ 1

0 otherwise

We need to find the PDF of W, where W = max(X,Y). Therefore, we have:

W = max(X,Y) = X if X > Y, and W = Y if Y ≥ X

Let us calculate the probability of the event W ≤ w:

P[W ≤ w] = P[max(X,Y) ≤ w]

When w ≤ 0, P(W ≤ w) = 0. When w > 1, P(W ≤ w) = 1. Hence, we assume 0 < w ≤ 1.

We split the probability into two parts, using the law of total probability:

P[W ≤ w] = P[X ≤ w]P[Y ≤ w] + P[X ≥ w]P[Y ≥ w]

Substituting for the given density function, we have:

P[W ≤ w] = ∫₀ˣ∫₀ˣ cx³y² dxdy + ∫ₓˑ₁∫ₓˑ₁ cx³y² dxdy

Here, when 0 < w ≤ 1:

P[W ≤ w] = c∫₀ˣ x³dx ∫₀ˑ₁ y²dy + c∫ₓˑ₁ x³dx ∫ₓˑ₁ y²dy

P[W ≤ w] = c(w⁵/₅) + c(1-w)⁵ - 2c(w⁵/₅)

Hence, the PDF of W is:

fW(w) = d/dw P[W ≤ w]

fW(w) = c(w⁴ - 5w³ + 10w² - 10w + 4)

Here, 0 < w ≤ 1.

Hence, the PDF of W is fW(w) = c(w⁴ - 5w³ + 10w² - 10w + 4).

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To build the confusion matrix, we compare the actual class labels with the predicted class labels. The confusion matrix is as follows:

markdown

Copy code

         Predicted Class

       |  0  |  1  |

Actual Class|-----|-----|

0 | 3 | 1 |

1 | 2 | 2 |

Based on the confusion matrix, we can calculate the metrics for "Class 1":

Classifier accuracy: (True Positives + True Negatives) / Total = (2 + 3) / 8 = 0.625

Precision: True Positives / (True Positives + False Positives) = 2 / (2 + 1) = 0.667

Recall: True Positives / (True Positives + False Negatives) = 2 / (2 + 2) = 0.5

F-score: 2 * (Precision * Recall) / (Precision + Recall) = 2 * (0.667 * 0.5) / (0.667 + 0.5) ≈ 0.571.

In the context of predicting fraudulent transactions, precision and recall are important metrics to evaluate the performance of the classifier.

Precision refers to the proportion of correctly predicted fraudulent transactions out of all the transactions predicted as fraudulent. It focuses on minimizing false positives, which means reducing the instances where a legitimate transaction is wrongly classified as fraudulent. A high precision indicates a low rate of false positives, providing assurance that the predicted fraudulent transactions are indeed likely to be fraudulent. Recall, on the other hand, measures the proportion of correctly predicted fraudulent transactions out of all the actual fraudulent transactions. It aims to minimize false negatives, which means reducing the instances where a fraudulent transaction is incorrectly classified as legitimate. A high recall indicates a low rate of false negatives, ensuring that most fraudulent transactions are detected.

Both precision and recall are important in detecting fraudulent transactions. However, the relative importance may depend on the specific context and goals of the system. In general, a balance between precision and recall is desirable, but the emphasis may vary depending on the consequences of false positives and false negatives. For example, in a fraud detection system, preventing fraudulent transactions (higher precision) may be more critical than potentially flagging some legitimate transactions as fraudulent (lower recall). Ultimately, the choice between precision and recall as the better metric depends on the specific requirements and priorities of the application.

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To calculate the probabilities, we need to use the concept of binomial probability.

For a fair coin being tossed 5 times:

(a) Probability of getting five heads:

The probability of getting a head in a single toss is 1/2.

Since each toss is independent, we multiply the probabilities together.

P(Head) = 1/2

P(Tails) = 1/2

P(Five Heads) = P(Head) * P(Head) * P(Head) * P(Head) * P(Head) = [tex](1/2)^5[/tex] = 1/32 ≈ 0.03125

So, the probability of obtaining five heads is approximately 0.03125 or 3.125%.

(b) Probability of getting four heads:

There are five possible positions for the four heads.

P(Four Heads) = (5C4) * P(Head) * P(Head) * P(Head) * P(Head) * P(Tails) = 5 * [tex](1/2)^4[/tex] * (1/2) = 5/32 ≈ 0.15625

So, the probability of obtaining four heads is approximately 0.15625 or 15.625%.

(c) Probability of getting one head:

There are five possible positions for the one head.

P(One Head) = (5C1) * P(Head) * P(Tails) * P(Tails) * P(Tails) * P(Tails) = 5 * (1/2) * [tex](1/2)^4[/tex] = 5/32 ≈ 0.15625

So, the probability of obtaining one head is approximately 0.15625 or 15.625%.

For a fair die being thrown eight times:

(a) Probability of a 6 occurring six times:

The probability of rolling a 6 on a fair die is 1/6.

Since each roll is independent, we multiply the probabilities together.

P(6) = 1/6

P(Not 6) = 1 - P(6) = 5/6

P(Six 6s) = P(6) * P(6) * P(6) * P(6) * P(6) * P(6) * P(Not 6) * P(Not 6) = [tex](1/6)^6 * (5/6)^2[/tex] ≈ 0.000021433

So, the probability of rolling a 6 six times is approximately 0.000021433 or 0.0021433%.

(b) Probability of a 6 never happening:

P(No 6) = P(Not 6) * P(Not 6) * P(Not 6) * P(Not 6) * P(Not 6) * P(Not 6) * P(Not 6) * P(Not 6) = [tex](5/6)^8[/tex] ≈ 0.23256

So, the probability of not rolling a 6 at all is approximately 0.23256 or 23.256%.

(c) Probability of an odd number of 6s:

To have an odd number of 6s, we can either have 1, 3, 5, or 7 6s.

P(Odd 6s) = P(One 6) + P(Three 6s) + P(Five 6s) + P(Seven 6s)

[tex]P(One 6) = (8C1) * P(6) * P(Not 6)^7 = 8 * (1/6) * (5/6)^7P(Three 6s) = (8C3) * P(6)^3 * P(Not 6)^5 = 56 * (1/6)^3 * (5/6)^5P(Five 6s) = (8C5) * P(6)^5 * P(Not 6)^3 = 56 * (1/6)^5 * (5/6)^3P(Seven 6s) = (8C7) * P(6)^7 * P(Not 6) = 8 * (1/6)^7 * (5/6)[/tex]

P(Odd 6s) = P(One 6) + P(Three 6s) + P(Five 6s) + P(Seven 6s)

Calculate each term and sum them up to find the final probability.

After performing the calculations, we find that P(Odd 6s) is approximately 0.28806 or 28.806%.

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The moments are Mᵣ = 10 and Mᵧ = 9, and the center of mass of the system is (xCM, yCM) = (2.5, 2.25).

To find the moments Mᵣ and Mᵧ and the center of mass (xCM, yCM) of the system, we can use the formulas:

Mᵣ = ∑mᵢxᵢ

Mᵧ = ∑mᵢyᵢ

xCM = Mᵣ / (∑mᵢ)

yCM = Mᵧ / (∑mᵢ)

Given that the particles have equal mass m, we can assume m = 1 for simplicity. Let's calculate the moments and the center of mass:

Mᵣ = (11 + 12 + 13 + 14) = 10

Mᵧ = (13 + 11 + 12 + 13) = 9

xCM = Mᵣ / (1 + 1 + 1 + 1) = 10 / 4 = 2.5

yCM = Mᵧ / (1 + 1 + 1 + 1) = 9 / 4 = 2.25

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A function f(x) = ||x||² for x∈H is called strictly convex if for all x,y∈H with x≠y and λ∈(0,1),f(λx+(1−λ)y) < λf(x)+(1−λ)f(y).Let H be an inner product space and f(x) = ||x||².

Let X be a normed space and f(x) = ||x||².

Then, to show that f is not strictly convex, we need to find x,y∈X with x≠y and λ∈(0,1) such that f(λx+(1−λ)y) = λf(x)+(1−λ)f(y).Consider X = R² and x = (1,0), y = (0,1)∈R².

Then, we have:λx+(1−λ)y = (λ,1−λ)f(λx+(1−λ)y) = ||λx+(1−λ)y||²= ||(λ,1−λ)||²

= λ² +(1−λ)²λf(x)+(1−λ)f(y) = λ||x||² +(1−λ)||y||²

= λ+(1−λ)=1

Therefore, we have f(λx+(1−λ)y) = λf(x)+(1−λ)f(y) and hence, f is not strictly convex.

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Using the substitution U = (2x + 1) is correct, and the statement is True.

We can set U = (2x + 1) by applying the substitution rule. We obtain dU = 2dx by dividing both sides with regard to x. When we solve for dx, we get dx = (1/2)dU.

Now, we substitute these values in the integral:

∫4(2x + 1)² dx = ∫4U² (1/2)dU

Simplifying the expression, we have:

(1/2)∫4U² dU

Now we can integrate with respect to U:

(1/2) * (4/3)U³ + C

(2/3)U³ + C

Finally, substituting back U = (2x + 1), we get:

(2/3)(2x + 1)³ + C

Therefore, using the substitution U = (2x + 1) is correct, and the statement is True.

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To find 3% of 400, we use the formula, A = PB, where A is P percent of B. Given, B = 400,

P = 3%.

We have been given the values of B and P, and using the formula A= PB, we need to find the value of A. Substituting the values of B and P in the given formula, we get: A= PB

= 3/100 × 400

= 12.

Therefore, 3% of 400 is 12. The percentage formula is often used in various fields, such as accounting, science, finance, and many others. When we say that A is P percent of B, it means that A is (P/100) times B. In other words, P percent is the same as P/100. Using this formula, we can easily calculate the value of one variable when the other two are known. It is a very useful tool when it comes to calculating discounts, interests, taxes, and many other things that involve percentages.

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The inner integral is:Integral from 0 to 6√3 of r dz = 3√3 r2.

The middle integral is:Integral from 0 to 4 of 3√3 r2 dr = 64√3.

The outer integral is:Integral from 0 to 2π of 64√3 dθ = 128π√3. Thus, the volume is 128π√3.

(a) i) Triple Integral:The triple integral is a calculus integral that evaluates the volume of a three-dimensional object with respect to its x, y, and z components.

It is also known as the multiple integral of a function.

ii) Integrals are useful for many things, including calculating area, volume, and other geometric properties, as well as solving differential equations and other problems in calculus and physics.

(b) Given the region G, which is bounded by the cone z = 1x2 + y2 and above by the paraboloid z = 2 - x2 - y2,

set up a triple integral in cylindrical coordinates to find the volume of the region. To begin, we must first find the intersection of the two surfaces:

z = 1x2 + y2 and z = 2 - x2 - y2. 

Substituting one equation into the other:x2 + y2 = 2 - x2 - y2 2x2 + 2y2 = 2 x2 + y2 = 1. 

So, the intersection is a circle with a radius of

1. Thus, the bounds for r are from 0 to 1, and the bounds for θ are from 0 to 2π.

The bounds for z are from 1r2 to 2 - r2. Therefore, the integral in cylindrical coordinates is:Integral from 0 to 1 (integral from 0 to 2π (integral from r2 to 2 - r2 of 1dz) dθ) r dr c)

We must first find the intersection of the two surfaces. The intersection of the sphere x2 + y2 + z2 = 49 and the cone

z = 4./(x2 + y2) is the circle x2 + y2 = 16.

Therefore, the region of integration is a cylinder with a radius of 4 and a height of 2 sqrt(49 - 16) = 6 sqrt(3).

The integral is: ∫∫∫dV = ∫0^2π∫0^4∫0^(6√3) r dz dr dθHere, r is the distance from the z-axis to the point on the xy-plane, θ is the angle measured counterclockwise from the positive x-axis to the point on the xy-plane, and z is the distance from the xy-plane to the point on the sphere.

Using cylindrical coordinates, the integral becomes: ∫0^2π∫0^4∫0^(6√3) r dz dr dθ

The inner integral is:Integral from 0 to 6√3 of r dz = 3√3 r2.

The middle integral is:Integral from 0 to 4 of 3√3 r2 dr = 64√3.

The outer integral is:Integral from 0 to 2π of 64√3 dθ = 128π√3. Thus, the volume is 128π√3.

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In a Hilbert space, there exists a vector orthogonal to any closed subspace. In a normed space, this may not be the case for finite dimensional subspaces.

(a) The set X consists of all continuous functions on [0,1] that vanish at 0, equipped with the sup norm. The set Y consists of all continuous functions of the form rex with the integral of the product of x and the constant function 1 being equal to 0. It can be shown that Y is a closed proper subspace of X. However, there is no function z in X such that its norm is 1 and its distance to Y is 1. This result can be compared to the fact that in a separable Hilbert space, there always exists a vector with norm 1 that is orthogonal to any closed subspace.

(b) If Y is a finite dimensional proper subspace of a normed space X, then there exists a nonzero x in X that is orthogonal to Y. This follows from the fact that any finite dimensional subspace of a normed space is closed, and hence has a complement that is also closed. Let y1, y2, ..., yn be a basis for Y. Then, any x in X can be written as x = y + z, where y is a linear combination of y1, y2, ..., yn and z is orthogonal to Y. Since ||y|| <= ||x||, we have ||x|| >= ||z||, which implies that dist(X,Y) = ||z||/||x|| <= 1/||z|| <= 1. To obtain the desired result, we can normalize z to obtain a unit vector x/||x|| with dist(X,Y) = 1.

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The distance between a Banach space X and a subspace Y is defined as the infimum of the distances between any point in X and any point in Y. If Y is a proper subspace of X, then there exists an x in X such that ||x|| = 1 and dist(x, Y) = 1.

(a) X is the Banach space consisting of all functions of C([0,1]) with the sup norm, such that their first values are 0. Therefore, all X members are continuous functions that are 0 at point 0, and their norm is the sup distance from the x-axis on the interval [0,1].

Y is the subspace of X formed by all functions that are of the form rex and satisfy the condition  ∫(0-1)f(x)dx=0.The subspace Y is a proper subspace of X since its dimension is smaller than that of X and does not contain all the members of X.

The distance between two sets X and Y is defined by the formula dist(X, Y) = inf { ||x-y||: x E X, y E Y }. To determine dist(X,Y) in this case, we must calculate ||x-y|| for x in X and y in Y such that ||x|| = ||y|| = 1, and ||x-y|| is as close as possible to 1.The solution to the problem is to prove that no such x exists. (Compare 5.3.) The proof for this involves the fact that, as Y is a closed subspace of X, its orthogonal complement is also closed in X; in other words, Y is a proper subspace of X, but its orthogonal complement Z is also a proper subspace of X. The same approach will not work, however, if X is not a Hilbert space.(b) Suppose Y is a finite-dimensional proper subspace of X.

Then there exists an x E X such that ||x|| = 1 and dist(x, Y) = 1. The vector x will be at a distance of 1 from Y. The proof proceeds by considering two cases:

i) If X is a finite-dimensional Hilbert space, then there exists an orthonormal basis for X.

Using the Gram-Schmidt process, the orthogonal complement of Y can be calculated. It is easy to show that this complement is infinite-dimensional, and therefore its intersection with the unit sphere is non-empty. Choose a vector x from this intersection; then ||x|| = 1 and dist(x, Y) = 1.

ii) If X is not a Hilbert space, then it can be embedded into a Hilbert space H by using the completion process. In other words, there is a Hilbert space H and a continuous linear embedding T : X -> H such that T(X) is dense in H. Let Y' = T(Y) and let x' = T(x).

Since Y' is finite-dimensional, it is a closed subset of H. By part (a) of this problem, there exists a vector y' in Y' such that ||y'|| = 1 and dist(y', Y') = 1. Now set y = T-1(y'). Then y is in Y and ||y|| = 1, and dist(x, Y) <= ||x-y|| = ||T(x)-T(y)|| = ||x'-y'||. Thus we have dist(x, Y) <= ||x'-y'|| < = dist(y', Y') = 1. Hence dist(x, Y) = 1.

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