Simplify each expression. (2-3i) / (1+5i).

Correct option is y = -x-1 + e^x.

The given linear ODE:

y' - y = x; y(0) = 0 can be solved by the following method:

We first need to find the integrating factor of the given differential equation. We will find it using the following formula:

IF = e^integral of P(x) dx

Where P(x) is the coefficient of y (the function multiplying y).

In the given differential equation, P(x) = -1, hence we have,IF = e^-x We multiply this IF to both sides of the equation. This will reduce the left side to a product of the derivative of y and IF as shown below:

e^-x y' - e^-x y = xe^-x We can simplify the left side by applying the product rule of differentiation as shown below:

d/dx (e^-x y) = xe^-x We can integrate both sides to obtain the solution of the differential equation. The solution to the given linear ODE:y' - y = x; y(0) = 0 is:y = -x-1 + e^x + C where C is the constant of integration. Substituting y(0) = 0, we get,0 = -1 + 1 + C

Therefore, C = 0

Hence, the solution to the given differential equation: y = -x-1 + e^x

So, the correct option is y = -x-1 + e^x.

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Answer:

Step-by-step explanation:

3x12=36inches in 1yard

5 yards= 5(36) =180 inches

The second equation after eliminating the variable x is 0.5y + 3.5z = 11.5.

To solve the system of linear equations using Gaussian elimination, we'll perform row operations to eliminate variables one by one. Let's start with the given system of equations:

Eliminate x from equations 2 and 3:

To eliminate x, we'll multiply equation 1 by -1.5 and add it to equation 2. We'll also multiply equation 1 by -2 and add it to equation 3.

New equation 3: (4x - 2y + 3z) - 2 * (2x + y - z) = -9 - 2 * 1

Simplifying the equation 3: 4x - 2y + 3z - 4x - 2y + 2z = -9 - 2

Simplifying further: -0.5y - 3.5z = -11.5

So, the second equation after eliminating the variable x is 0.5y + 3.5z = 11.5.

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The present value of the annuity is $4,813.52.

To calculate the present value of the annuity, we can use the formula for the present value of an increasing annuity:

PV = C * (1 - (1 + r)^(-n)) / (r - g)

Where:

PV = Present Value

C = Payment amount at time t=1

r = Interest rate

n = Number of payments

g = Growth rate of payments

In this case:

C = $300

r = 8% or 0.08

n = Number of payments = Last payment amount - First payment amount / Growth rate + 1 = ($1000 - $300) / $50 + 1 = 14

g = Growth rate of payments = $50

Plugging in these values into the formula, we get:

PV = $300 * (1 - (1 + 0.08)^(-14)) / (0.08 - 0.05) = $4,813.52

Therefore, the present value of this annuity is $4,813.52. This means that if we were to invest $4,813.52 today at an interest rate of 8%, it would grow to match the future cash flows of the annuity.

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(e) The overall solution is given by the equation x(t) =  C1t^3 + C2/t^3,, where C1 and C2 are arbitrary constants.

(a) The Wronskian of x(1) and x(2) is given by:

W = | x1(t) x2(t) |

| x1'(t) x2'(t) |

Let's evaluate the Wronskian of x(1) and x(2) using the given formula:

W = | t 2t^2 | - | 4t t^2 |

| 1 2t | | 2 2t |

Simplifying the determinant:

W = (t)(2t^2) - (4t)(1)

= 2t^3 - 4t

= 2t(t^2 - 2)

(b) For x(1) and x(2) to be linearly independent, the Wronskian W should be non-zero. Since W = 2t(t^2 - 2), the Wronskian is zero when t = 0, t = -√2, and t = √2. For all other values of t, the Wronskian is non-zero. Therefore, x(1) and x(2) are linearly independent in the intervals (-∞, -√2), (-√2, 0), (0, √2), and (√2, +∞).

(c) Since x(1) and x(2) are linearly dependent for the values t = 0, t = -√2, and t = √2, it implies that the coefficients in the system of homogeneous differential equations satisfied by x(1) and x(2) are not all zero. At least one of the coefficients must be non-zero.

(d) The system of equations x': = 9t^2x is already given.

(e) The general solution of the differential equation x' = 9t^2x can be found by solving the characteristic equation. The characteristic equation is r^2 = 9t^2, which has roots r = ±3t. Therefore, the general solution is:

x(t) = C1t^3 + C2/t^3,

where C1 and C2 are arbitrary constants.

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Consider the system x'=8y+x+12 y'=x−y+12t

A. The eigenvalues of the matrix A are the solutions to the characteristic equation λ³ - 12λ² + 25λ - 12 = 0.

B. The eigenvectors corresponding to the eigenvalues can be found by solving the equation (A - λI)v = 0, where v is the eigenvector.

C. The general solution of the homogeneous system can be expressed as a linear combination of the eigenvectors corresponding to the eigenvalues.

D. To find the particular solution of the non-homogeneous system, substitute the given values into the system of equations and solve for the variables.

E. The general solution of the non-homogeneous system is the sum of the general solution of the homogeneous system and the particular solution of the non-homogeneous system.

F. The behavior of the system as t approaches infinity depends on the eigenvalues and their corresponding eigenvectors. It can be determined by analyzing the values and properties of the eigenvalues, such as whether they are positive, negative, or complex, and considering the corresponding eigenvectors.

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The function that has a period of 4π and an amplitude of 8 is y = 8sin(2θ), which is option (H).

The general form of the equation of a sine function is given as f(θ) = a sin(bθ + c) + d

where, a is the amplitude of the function, the distance between the maximum or minimum value of the function from the midline, b is the coefficient of θ, which determines the period of the function and is calculated as:

Period = 2π / b.c

which is the phase shift of the function, which is calculated as:

Phase shift = -c / bd

which is the vertical shift or displacement from the midline. The period of the function is 4π, and the amplitude is 8. Therefore, the function that meets these conditions is given as:

f(θ) = a sin(bθ + c) + df(θ) = 8 sin(bθ + c) + d

We know that the period is given by:

T = 2π / b

where T = 4π4π = 2π / bb = 1 / 2

The equation now becomes:

f(θ) = 8sin(1/2θ + c) + d

The amplitude of the function is 8. Hence

= 8 or -8

The function becomes:

f(θ) = 8sin(1/2θ + c) + df(θ) = -8sin(1/2θ + c) + d

We can take the positive value of a since it is the one given in the answer options. Also, d is not important since it does not affect the period and amplitude of the function.

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this answer is 7 that is your answer

The equation that represents the line passing through the point (2, -5) with a slope of -3 is y = -3x + 1.

The equation of a line can be represented in the slope-intercept form, which is y = mx + b. In this form, "m" represents the slope of the line and "b" represents the y-intercept.

Given that the line passes through the point (2, -5) and has a slope of -3, we can substitute these values into the slope-intercept form to find the equation of the line.

The slope-intercept form is y = mx + b. Substituting the slope of -3, we have y = -3x + b.

To find the value of "b", we can substitute the coordinates of the point (2, -5) into the equation and solve for "b".

-5 = -3(2) + b

-5 = -6 + b

b = -5 + 6

b = 1

Now that we have the value of "b", we can substitute it back into the equation to find the final equation of the line.

y = -3x + 1

Therefore, the equation that represents the line passing through the point (2, -5) with a slope of -3 is y = -3x + 1.

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The domain and the range of the table are

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

The table of values

The rule of a function is that

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

Domain = -1 ≤ x ≤ 1

Range = {3,4,5,6,7}

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The equation of the least-squares line that best fits the given data points is y = 2 + (2/3)x.

To find the equation of the least-squares line that best fits the given data points, we can use the method of least squares to minimize the sum of the squared differences between the actual y-values and the predicted y-values on the line.

Calculate the mean of the x-values and the mean of the y-values.

[tex]\bar x[/tex] = (0 + 1 + 2 + 3) / 4 = 1.5

[tex]\bar y[/tex]= (2 + 2 + 5 + 5) / 4 = 3.5

Calculate the deviations from the means for both x and y.

x₁ = 0 - 1.5 = -1.5

x₂ = 1 - 1.5 = -0.5

x₃ = 2 - 1.5 = 0.5

x₄ = 3 - 1.5 = 1.5

y₁ = 2 - 3.5 = -1.5

y₂ = 2 - 3.5 = -1.5

y₃ = 5 - 3.5 = 1.5

y₄ = 5 - 3.5 = 1.5

Calculate the sum of the products of the deviations from the means.

Σ(xᵢ * yᵢ) = (-1.5 * -1.5) + (-0.5 * -1.5) + (0.5 * 1.5) + (1.5 * 1.5) = 4

Calculate the sum of the squared deviations of x.

Σ(xᵢ²) = (-1.5)² + (-0.5)² + (0.5)² + (1.5)² = 6

Calculate the least-squares slope (B₁) using the formula:

B₁ = Σ(xᵢ * yᵢ) / Σ(xᵢ²) = 4 / 6 = 2/3

Calculate the y-intercept (Bo) using the formula:

Bo = [tex]\bar y[/tex] - B₁ * [tex]\bar x[/tex] = 3.5 - (2/3) * 1.5 = 2

Therefore, the equation of the least-squares line that best fits the given data points is y = 2 + (2/3)x.

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The parameterization of a circle of radius r in the xy-plane, centered at (a, b), and traversed once in a clockwise fashion can be represented by the following equations:

[tex]\[ x = a + r \cos(t) \]\[ y = b - r \sin(t) \][/tex]

where:

- (a, b) represents the center of the circle,

- r represents the radius of the circle,

- t represents the parameter that ranges from 0 to 2π (or 0 to 360 degrees) to traverse the circle once in a clockwise fashion.

In the equation for x, the cosine function is used to determine the x-coordinate of points on the circle based on the angle t. Adding the center's x-coordinate, a, gives the correct position of the points on the circle in the x-axis.

In the equation for y, the sine function is used to determine the y-coordinate of points on the circle based on the angle t. Subtracting the center's y-coordinate, b, ensures that the points are correctly positioned on the y-axis.

Together, these equations form a parameterization that represents a circle of radius r, centered at (a, b), and traversed once in a clockwise fashion.

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Mary Dinsmore's 2021 federal income tax is $2,002.

To determine Mary Dinsmore's federal income tax, we need to consider her filing status, standard deduction, adjusted gross income, and the applicable tax rates. Mary uses the single filing status and the standard deduction. For the tax year 2021, the standard deduction for a single filer under the age of 65 is $12,550.

To calculate taxable income, we subtract the standard deduction from the adjusted gross income. In this case, Mary's adjusted gross income is $32,417, and the standard deduction is $12,550. Therefore, her taxable income would be $32,417 - $12,550 = $19,867.

For the tax year 2021, the tax brackets for single filers are as follows:

- 10% on taxable income up to $9,950

- 12% on taxable income over $9,950 up to $40,525

Since Mary's taxable income of $19,867 falls within the 12% tax bracket, we can calculate her federal income tax by applying the 12% tax rate.

$19,867 * 0.12 = $2,384.04

However, since Mary is eligible for the standard deduction, her taxable income is reduced to $19,867. This means she only pays taxes on that amount.

Therefore, Mary's 2021 federal income tax is $2,002, which is the 12% tax rate applied to her taxable income of $19,867.

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The formula \forall x \exists y(x\oplus y=c) in first-order logic states that for any value of x, there exists a value of y such that the binary function \oplus of x and y is equal to a constant c.

To determine the interpretations for which this formula is valid, we need to consider the possible interpretations of the binary function \oplus and the constant c.

Since the formula does not provide specific information about the binary function \oplus or the constant c, we cannot determine a single interpretation for which the formula is valid. The validity of the formula depends on the specific interpretation of \oplus and the constant c.

To evaluate the validity of the formula, we need additional information about the properties and constraints of the binary function \oplus and the constant c. Without this information, we cannot determine the interpretation(s) for which the formula is valid.

In summary, the validity of the formula \forall x \exists y(x\oplus y=c) depends on the specific interpretation of the binary function \oplus and the constant c, and without further information, we cannot determine a specific interpretation for which the formula is valid.

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To complete each ordered pair using the function y = 200 tan(x) on the interval 0° ≤ x ≤ 141°, we need to substitute different values of x within that interval and calculate the corresponding values of y. Let's calculate the ordered pairs by rounding the answers to the nearest whole number:

1. For x = 0°:

  y = 200 tan(0°) = 0

  The ordered pair is (0, 0).

2. For x = 45°:

  y = 200 tan(45°) = 200

  The ordered pair is (45, 200).

3. For x = 90°:

  y = 200 tan (90°) = ∞ (undefined since the tangent of 90° is infinite)

  The ordered pair is (90, undefined).

4. For x = 135°:

  y = 200 tan (135°) = -200

  The ordered pair is (135, -200).

5. For x = 141°:

  y = 200 tan (141°) = -13

  The ordered pair is (141, -13).

So, the completed ordered pairs (rounded to the nearest whole number) are:

(0, 0), (45, 200), (90, undefined), (135, -200), (141, -13).

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There exist A, B ∈ Z that satisfy the equation A² + B² = 2(a² + b²).

To prove the statement using complex numbers, let's start by representing the integers a and b as complex numbers:

a = a + 0i

b = b + 0i

Now, we can rewrite the equation a² + b² = 2(a² + b²) in terms of complex numbers:

(a + 0i)² + (b + 0i)² = 2((a + 0i)² + (b + 0i)²)

Expanding the complex squares, we get:

(a² + 2ai + (0i)²) + (b² + 2bi + (0i)²) = 2((a² + 2ai + (0i)²) + (b² + 2bi + (0i)²))

Simplifying, we have:

a² + 2ai - b² - 2bi = 2a² + 4ai - 2b² - 4bi

Grouping the real and imaginary terms separately, we get:

(a² - b²) + (2ai - 2bi) = 2(a² - b²) + 4(ai - bi)

Now, let's choose A and B such that their real and imaginary parts match the corresponding sides of the equation:

A = a² - b²

B = 2(a - b)

Substituting these values back into the equation, we have:

A + Bi = 2A + 4Bi

Equating the real and imaginary parts, we get:

A = 2A

B = 4B

Since A and B are integers, we can see that A = 0 and B = 0 satisfy the equations. Therefore, there exist A, B ∈ Z that satisfy the equation A² + B² = 2(a² + b²).

This completes the proof.

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A and E are true statements A. A³ is invertible.

Since A is an invertible matrix, A³ is also invertible because the inverse of A³ is (A⁻¹)³, which exists since A⁻¹ exists.

B. ABA⁻¹ = B⁻¹: This statement is not always true. While it is true that (A⁻¹)⁻¹ = A, it does not necessarily imply that ABA⁻¹ = B⁻¹. Multiplication of matrices is not commutative, so ABA⁻¹ may not be equal to B⁻¹.

C. (Iₙ + A)(Iₙ + A⁻¹) = 2Iₙ + A + A⁻¹: This statement is true. It can be proven by expanding the expression using the distributive property of matrix multiplication and the fact that A and A⁻¹ commute with the identity matrix Iₙ.

D. (A + A⁻¹)⁵ = A⁵ + A⁻⁵: This statement is not always true. The power of a sum of matrices does not generally distribute across the terms. Therefore, (A + A⁻¹)⁵ is not equal to A⁵ + A⁻⁵.

E. (A + B)(A - B) = A² - B²: This statement is true. It can be proven by expanding the expression using the distributive property of matrix multiplication and the fact that A and B commute with each other.

F. A + A⁻¹ is invertible: This statement is not always true. A matrix is invertible if and only if its determinant is non-zero. The determinant of A + A⁻¹ can be zero in certain cases, making it non-invertible.

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The solution to the equation 4x + [3 -7 9] = [-3 11 5 -7] is x = [-3/2 9/2 -1 -7/4].

To solve the equation 4x + [3 -7 9] = [-3 11 5 -7], we need to isolate the variable x.

Given:

4x + [3 -7 9] = [-3 11 5 -7]

First, let's subtract [3 -7 9] from both sides of the equation:

4x + [3 -7 9] - [3 -7 9] = [-3 11 5 -7] - [3 -7 9]

This simplifies to:

4x = [-3 11 5 -7] - [3 -7 9]

Subtracting the corresponding elements, we have:

4x = [-3-3 11-(-7) 5-9 -7]

Simplifying further:

4x = [-6 18 -4 -7]

Now, divide both sides of the equation by 4 to solve for x:

4x/4 = [-6 18 -4 -7]/4

This gives us:

x = [-6/4 18/4 -4/4 -7/4]

Simplifying the fractions:

x = [-3/2 9/2 -1 -7/4]

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Answer:

SSS, because a segment is congruent to itself.

The first 4 terms of the expansion for (1 + x)¹⁵ is

The expansion of (1 + x)¹⁵ can be found using the binomial theorem. According to the binomial theorem, the expansion of (1 + x)¹⁵ can be expressed as

(1 + x)¹⁵= ¹⁵C₀x⁰ + ¹⁵C₁x¹ + ¹⁵C₂x² + ¹⁵C₃x³

the coefficients are solved using combination as follows

¹⁵C₀ = 1

¹⁵C₁ = 15

¹⁵C₂ = 105

¹⁵C₃ = 455

plugging in the values

(1 + x)¹⁵= 1 * x⁰ + 15 * x¹ + 105 * x² + 455 * x³

(1 + x)¹⁵= 1 + 15x + 105x² + 455x³

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The unit vector normal to the surface is (√3/3, √3/3, √3/3)

a unit vector normal to the surface defined by the parametric equations x = 7cos(θ)sin(4), y = 5sin(θ)sin(4), and z = cos(4), we need to calculate the gradient vector of the surface and then normalize it to obtain a unit vector.

The gradient vector of a surface is given by (∂f/∂x, ∂f/∂y, ∂f/∂z), where f(x, y, z) is an implicit equation of the surface. In this case, we can consider the equation f(x, y, z) = x - 7cos(θ)sin(4) + y - 5sin(θ)sin(4) + z - cos(4) = 0, as it represents the equation of the surface.

Taking the partial derivatives, we have:

∂f/∂x = 1

∂f/∂y = 1

∂f/∂z = 1

Therefore, the gradient vector is (1, 1, 1).

To obtain a unit vector, we need to normalize the gradient vector. The magnitude of the gradient vector is given by:

|∇f| = √(1^2 + 1^2 + 1^2) = √3.

Dividing the gradient vector by its magnitude, we have:

n = (1/√3, 1/√3, 1/√3).

Simplifying the expression, we get:

n = (√3/3, √3/3, √3/3).

Therefore, the unit vector normal to the surface is (√3/3, √3/3, √3/3).

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Answer:

2

Step-by-step explanation:

if that is not it please let me know i like feedback

The eigenvalues of the matrix A = [ 3 0 1 2 2 2 -2 1 2 ] are:

λ₁ = (5 - √17)/2 and λ₂ = (5 + √17)/2

To find the eigenvalues (A) of the matrix A = [ 3 0 1 2 2 2 -2 1 2 ], we use the following formula:

Eigenvalues (A) = |A - λI

|where λ represents the eigenvalue, I represents the identity matrix and |.| represents the determinant.

So, we have to find the determinant of the matrix A - λI.

Thus, we will substitute A = [ 3 0 1 2 2 2 -2 1 2 ] and I = [1 0 0 0 1 0 0 0 1] to get:

| A - λI | = | 3 - λ 0 1 2 2 - λ 2 -2 1 2 - λ |

To find the determinant of the matrix, we use the cofactor expansion along the first row:

| 3 - λ 0 1 2 2 - λ 2 -2 1 2 - λ | = (3 - λ) | 2 - λ 2 1 2 - λ | + 0 | 2 - λ 2 1 2 - λ | - 1 | 2 2 1 2 |

Therefore,| A - λI | = (3 - λ) [(2 - λ)(2 - λ) - 2(1)] - [(2 - λ)(2 - λ) - 2(1)] = (3 - λ) [(λ - 2)² - 2] - [(λ - 2)² - 2] = (λ - 2) [(3 - λ)(λ - 2) + λ - 4]

Now, we find the roots of the equation, which will give the eigenvalues:

λ - 2 = 0 ⇒ λ = 2λ² - 5λ + 2 = 0

The two roots of the equation λ² - 5λ + 2 = 0 are:

λ₁ = (5 - √17)/2 and λ₂ = (5 + √17)/2

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The total amount accumulated at the end of 10 years is approximately $1268.76. Hence, the amount accumulated is $1268.76.

Principal deposited (P): $600

Annual interest rate (r): 5.6%

Number of times interest compounded per year (n): 4

Time in years (t): 10

To find: The total amount accumulated at the end of 10 years.

Solution:

We will use the compound interest formula:

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

Substituting the given values:

A = 600 * (1 + 0.056/4)^(4 * 10)

Simplifying the expression:

A = 600 * (1.014)^40

Calculating the value:

A ≈ 600 * 2.1146

A ≈ 1268.76

Therefore, , the total money amassed after ten years is around $1268.76.

As a result, the total sum accumulated is $1268.76.

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The vectors related to given points are AB <6, 4> and BC <4, 6>, respectively.

In this problem we must determine the equations of two vectors represented by a figure, each vector is between two consecutive points set on Cartesian plane. The definition of a vector is introduced below:

AB <x, y> = B(x, y) - A(x, y)

Where:

Now we proceed to determine each vector:

AB <x, y> = (6, 4) - (0, 0)

AB <x, y> = (6, 4)

AB <6, 4>

BC <x, y> = (10, 10) - (6, 4)

BC <x, y> = (4, 6)

BC <4, 6>

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The output for t = 1.25 for the given differential equation 2y"(t) + 214y(t) = et + et with conditions is equal to y(1.25) = 0.

To solve the given differential equation 2y"(t) + 214y(t) = et + et, with initial conditions y(0) = 0 and y'(0) = 0,

find the particular solution and then apply the initial conditions to determine the specific solution.

The right-hand side of the equation consists of two terms, et and et.

Since they have the same form, assume a particular solution of the form yp(t) = At[tex]e^t[/tex], where A is a constant to be determined.

Now, let's find the first and second derivatives of yp(t),

yp'(t) = A([tex]e^t[/tex] + t[tex]e^t[/tex])

yp''(t) = A(2[tex]e^t[/tex] + 2t[tex]e^t[/tex])

Substituting these derivatives into the differential equation,

2(A(2[tex]e^t[/tex] + 2t[tex]e^t[/tex])) + 214(At[tex]e^t[/tex]) = et + et

Simplifying the equation,

4A[tex]e^t[/tex] + 4At[tex]e^t[/tex] + 214At[tex]e^t[/tex]= 2et

Now, equating the coefficients of et on both sides,

4A + 4At + 214At = 2t

Matching the coefficients of t on both sides,

4A + 4A + 214A = 0

Solving this equation, we find A = 0.

The particular solution is yp(t) = 0.

Now, the general solution is given by the sum of the particular solution and the complementary solution:

y(t) = yp(t) + y c(t)

Since yp(t) = 0, the general solution simplifies to,

y(t) = y c(t)

To find y c(t),

solve the homogeneous differential equation obtained by setting the right-hand side of the original equation to zero,

2y"(t) + 214y(t) = 0

The characteristic equation is obtained by assuming a solution of the form yc(t) = [tex]e^{(rt)[/tex]

2r² + 214 = 0

Solving this quadratic equation,

find two distinct complex roots: r₁ = i√107 and r₂ = -i√107.

The general solution of the homogeneous equation is then,

yc(t) = C₁[tex]e^{(i\sqrt{107t} )[/tex] + C₂e^(-i√107t)

Applying the initial conditions y(0) = 0 and y'(0) = 0:

y(0) = C₁ + C₂ = 0

y'(0) = C₁(i√107) - C₂(i√107) = 0

From the first equation, C₂ = -C₁.

Substituting this into the second equation, we get,

C₁(i√107) + C₁(i√107) = 0

2C₁(i√107) = 0

This implies C₁ = 0.

Therefore, the specific solution satisfying the initial conditions is y(t) = 0.

Now, to obtain the output for t = 1.25, we substitute t = 1.25 into the specific solution:

y(1.25) = 0

Hence, the output for t = 1.25 for the differential equation is y(1.25) = 0.

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Answer:

The phrase that is usually associated with addition is:

d. the total of two numbers

Step-by-step explanation:

Addition is the mathematical operation of combining two or more numbers to find their total or sum. When we add two numbers together, we are determining the total value or amount resulting from their combination. Therefore, "the total of two numbers" is the phrase commonly associated with addition.

Answer:

D. The total of two numbers

Step-by-step explanation:

We are left with D, addition is essentially taking 2 or more numbers and adding them, the result is usually called "sum" or total.

________________________________________________________

(a) The simultaneous equations representing the given information can be expressed in matrix form as:

3y - x = -6

x + y = 74

In matrix form, this can be written as:

[ 1   1 ] [ x ]   [ 74 ]

(b) To verify that the simultaneous equations have a unique solution, we can check the determinant of the coefficient matrix [ 3 -1 ; 1 1 ]. If the determinant is non-zero, then a unique solution exists.

(c) To solve for x and y using the inverse matrix method, we can represent the system of equations in matrix form:

where A is the coefficient matrix, X is the column vector [ x ; y ], and B is the column vector of constants [ -6 ; 74 ]. By multiplying both sides of the equation by the inverse of matrix A, we can isolate X:

[tex]A^(-1) * (A * X) = A^(-1) * B[/tex]

X = [tex]A^(-1) * B[/tex]

By calculating the inverse of matrix A and multiplying it by matrix B, we can find the values of x and y.

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The area of the parallelogram with vertices at (0, -3), (-9, 9), (5, -6), and (-4, 6) is 0.

To find the area of a parallelogram with the given vertices, we can use the formula for the area of a parallelogram:

Area = |(x1y2 + x2y3 + x3y4 + x4y1) - (y1x2 + y2x3 + y3x4 + y4x1)| / 2

Given the vertices:

A = (0, -3)

B = (-9, 9)

C = (5, -6)

D = (-4, 6)

We can substitute the coordinates into the formula:

Area = |(0 * 9 + (-9) * (-6) + 5 * 6 + (-4) * (-3)) - (-3 * (-9) + 9 * 5 + (-6) * (-4) + 6 * 0)| / 2

Simplifying the expression:

Area = |(0 + 54 + 30 + 12) - (27 + 45 + 24 + 0)| / 2

= |96 - 96| / 2

= 0 / 2

= 0

Therefore, the area of the parallelogram with vertices at (0, -3), (-9, 9), (5, -6), and (-4, 6) is 0.

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The final result of long division is: 9x - 11 with the remainder -12.

To divide (9x² - 21x - 20) by (x - 1) using long division:

To divide using long division, follow these steps:

Step 1: Write the problem in long division format. Place the dividend, which is 9x² - 21x - 20, inside the long division symbol. Place the divisor, which is x - 1, on the left side.

        _______________________
x - 1  |   9x² - 21x - 20

Step 2: Divide the first term of the dividend (9x²) by the first term of the divisor (x). Write the quotient above the long division symbol.

        _______________________
x - 1  |   9x² - 21x - 20
         9x

Step 3: Multiply the quotient (9x) by the divisor (x - 1) and write the result below the dividend. Subtract this result from the dividend.

        _______________________
x - 1  |   9x² - 21x - 20
         9x² - 9x

                - (9x² - 9x)
        _______________________
x - 1  |   9x² - 21x - 20
         9x² - 9x
        ________________
                    -12x - 20

Step 4: Bring down the next term of the dividend (-20) and continue the process.

        _______________________
x - 1  |   9x² - 21x - 20
         9x² - 9x
        ________________
                    -12x - 20
                    -12x + 12
        ________________
                           -32

Step 5: Divide the new term (-32) by the first term of the divisor (x). Write the new quotient above the long division symbol.

        _______________________
x - 1  |   9x² - 21x - 20
         9x² - 9x
        ________________
                    -12x - 20
                    -12x + 12
        ________________
                           -32
                           -32

Step 6: Multiply the new quotient (-32) by the divisor (x - 1) and write the result below. Subtract this result from the previous result.

        _______________________
x - 1  |   9x² - 21x - 20
         9x² - 9x
        ________________
                    -12x - 20
                    -12x + 12
        ________________
                           -32
                           -32
         _________________
                              0

Step 7: The division is complete when the remainder is zero. The final quotient is 9x - 12.

Therefore, (9x² - 21x - 20) / (x - 1) = 9x - 12.

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