Calculate the perimeter of this right- angled triangle. Give your answer in metres (m) to 1 d.p. 7m 16 m​

The actual length of the ship in centimeter and meter are 9000 and 90 respectively.

Scale of drawing = 1:1000

This means that 1cm on paper represents 1000cm of the actual object .

with a length of 9cm on paper :

a.)

Real length in centimeter = (9 × 1000) = 9000 cm

Hence, actual length in centimeters = 9000 cm

b.)

Real length in meters

Recall :

Actual length in meters would be :

Actual length in centimeter/ 100

9000/100 = 90

Hence, actual length in meters is 90.

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The values of the directional derivatives of the determinant in the E and A directions are 3 and 2, respectively.

The determinant can be defined as a numerical value obtained from the matrix. A directional derivative of the determinant in the E and A directions can be computed as follows:

1. Compute limo det (12+tE)-det (12) t det (12+1A)-det(12), where A a=2.

Now, we need to compute the directional derivative of the determinant in the E and A directions, respectively, to obtain their corresponding values—the directional Derivative of the determinant in the E-direction.

The directional derivative of the determinant in the E-direction can be computed as follows:

detE = lim h→0 [det (12+hE)-det (12)] / h

Put E= [3 -1;1 2] and 12 = [1 0;0 1].

Then, the value of det (12+hE) can be computed as follows:

det (12+hE) = |(1+3h) (-1+h)| - |(3h) (-h)|

= (1+3h)(-1+h)(-3h) + 3h2(-h)

= -3h3 - 6h2 + 3h.

The det (12) value can be computed as follows: det (12) = |1 0| - |0 1|= 1.

Then, substituting the values of det (12+hE) and det (12) in the above expression, we get:

detE = lim h→0 [-3h3 - 6h2 + 3h] /h

       = lim h→0 [-3h2 - 6h + 3]

       = 3

2. Directional Derivative of the determinant in the A-direction. The directional derivative of the determinant in the A-direction can be computed as follows:

detA = lim h→0 [det (12+hA)-det (12)] / h

Put A = [2 1;4 3] and 12 = [1 0;0 1]. Then, the value of det (12+hA) can be computed as follows:

det (12+hA) = |(1+2h) h| - |(2h) (1+3h)|

                = (1+2h)(3+4h) - 2h(2+6h)

               = 7h2 + 10h + 3.

The det (12) value can be computed as follows:

det (12) = |1 0| - |0 1|

= 1.

Then, substituting the values of det (12+hA) and det (12) in the above expression, we get:

detA = lim h→0 [7h2 + 10h + 3 - 1] / h

= lim h→0 [7h2 + 10h + 2]

= 2

Therefore, the values of the directional derivatives of the determinant in the E and A directions are 3 and 2, respectively.

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The implicit second derivative, dÿ/dx², of the equation xỷ - 2x = 5(dy/dx²) in terms of x and y is given by dy/dx² = (y(x³) + 4xy'(x²) + 2x²y'' + 2y'(x³) - 2x) / 5.

We start by differentiating the given equation with respect to x. Using the product rule, the left side becomes y(xẍ) + xyỵ + y'(x²) - 2. Since we are looking for dy/dx², we differentiate this equation again with respect to x. Applying the product rule and simplifying, we obtain y(x³) + 2xy'(x²) + 2xy'(x²) + 2x²y'' + 2y'(x³) - 2x.

Setting this equal to 5(dy/dx²), we have y(x³) + 4xy'(x²) + 2x²y'' + 2y'(x³) - 2x = 5(dy/dx²). Finally, we can rearrange this equation to isolate dy/dx² and express it implicitly in terms of x and y: dy/dx² = (y(x³) + 4xy'(x²) + 2x²y'' + 2y'(x³) - 2x) / 5.

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The shortest distance between the given line and plane is 11 units. For the skydiver's differential equation, the constant k is found to be 0.025. The solution to the differential equation, with the initial condition v(0) = 0, is v(t) = 20√(3 - [tex]e^{-0.025t}[/tex]) m/s. The graph of the solution shows the skydiver's speed increasing and eventually approaching the terminal velocity of 70 m/s.

(a) To find the distance between the line l and the plane P, we can use the formula for the shortest distance between a point and a plane. Let's take a point Q on the line l and find its coordinates in terms of t: Q(t) = (5 - 9t, 2 + 4t, 3 + t). The distance between Q(t) and the plane P is given by the formula:

d = |2(5 - 9t) + 3(2 + 4t) + 6(3 + t) - 33| / √(2² + 3² + 6²)

Simplifying this expression, we get d = 11 units as the shortest distance between the line and the plane.

(b)(i) The given differential equation is dv/dt = (600 - kv²) / 60. Since the skydiver reaches a terminal velocity of 70 m/s, we have dv/dt = 0 when v = 70. Plugging these values into the differential equation, we get 0 = 600 - k(70)². Solving for k, we find k = 0.025.

(ii) To solve the differential equation dv/dt = (600 - 0.025v²) / 60, we can separate variables and integrate both sides. Rearranging the equation, we have:

60 dv / (600 - 0.025v²) = dt

Integrating both sides gives us:

∫60 dv / (600 - 0.025v²) = ∫dt

Using a trigonometric substitution or partial fractions, the integral on the left side can be evaluated, resulting in:

-2arctan(0.05v/√3) = t + C

Simplifying further and applying the initial condition v(0) = 0, we find:

v(t) = 20√(3 - [tex]e^{-0.025t}[/tex]) m/s.

(iii) The graph of the solution shows that initially, the skydiver's speed increases rapidly, but as time goes on, the rate of increase slows down. Eventually, the speed approaches the terminal velocity of 70 m/s, indicated by the horizontal asymptote in the graph. This behavior is expected as the air resistance force becomes equal in magnitude to the gravitational force, resulting in a constant net force and a terminal velocity.

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Maclaurin's series can be represented as f(x) = √2x. The general formula for the Maclaurin series is:

f(x) = f(0) + (f'(0)/1!)x + (f''(0)/2!)x^2 + ... + (fⁿ(0)/n!)xⁿ

We will need to take a few derivatives of the function to find Maclaurin's series of the given function. Firstly, let's take the first derivative of the given function:

f(x) = √2xThus, we can write the derivative as:

f'(x) = (1/2) * (2x)^(-1/2) * 2

f'(x) = (1/√2x)

Next, we will take the second derivative of the function. We know that

f(x) = √2x and f'(x) = (1/√2x)

Thus, the second derivative of the function can be written as:

f''(x) = d/dx (f'(x))

= d/dx (1/√2x)

= (-1/2) * (2x)^(-3/2) * 2

= (-1/√8x³)

Now, we will take the third derivative of the function:

f'''(x) = d/dx (f''(x))

= d/dx (-1/√8x³)

= (3/2) * (2x)^(-5/2) * 2

= (3/√32x⁵)

We can see that there is a pattern forming here. Thus, the nth derivative of the function can be written as:

fⁿ(x) = [(-1)^(n-1) * (2n-3) * (2n-5) * ... * 3 * 1] / [2^(3n-2) * x^(3n/2)]

Now, let's substitute the values in the general formula for the Maclaurin series:

f(x) = f(0) + (f'(0)/1!)x + (f''(0)/2!)x^2 + ... + (fⁿ(0)/n!)xⁿ, When x = 0, all the terms of the Maclaurin series will be zero except for the first term which will be:

f(0) = √2(0)

= 0

Thus, we can write the Maclaurin series as:

f(x) = 0 + [f'(0)/1!]x + [f''(0)/2!]x^2 + ... + [fⁿ(0)/n!]xⁿ

When n = 1, f'(0) can be written as:

(f'(0)) = (1/√2(0)) = undefined

However, when n = 2, f''(0) can be written as:

f''(0) = (-1/√8(0)) = undefined.

Similarly, when n = 3, f'''(0) can be written as:

f'''(0) = (3/√32(0)) = undefined

Thus, we can see that all the higher derivatives of the function are undefined at x = 0.

Hence, the Maclaurin series of the given function can be represented as f(x) = 0

The Maclaurin series is an important mathematical concept used to represent functions in terms of a sum of powers of x. It is a powerful tool that is used in a variety of mathematical and scientific fields.

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The correct statement for the function is d. f(x) = x² and g(x) = 2x - 9.

Given that h(x) = f(g(x)), we can deduce the functions f(x) and g(x) by examining the expression for h(x), which is h(x) = (2x - 9)².

In order for h(x) to be equal to f(g(x)), f(x) must be a function that squares its input and g(x) must be a function that subtracts 9 from twice its input.

Looking at the given options:

a. f(x) = g(x) is not possible since f(x) and g(x) are distinct functions in the given equation.

b. g(x) = 2x - 9 is correct because it matches the requirement for g(x) stated above.

c. f(x) = 2x - 9; g(x) = x² is incorrect since f(x) is a linear function and g(x) is a quadratic function, not matching the given h(x) expression.

d. f(x) = x²; g(x) = 2x - 9 is correct because f(x) is a quadratic function that squares its input and g(x) subtracts 9 from twice its input, both matching the expression for h(x).

Therefore, the correct statement is d. f(x) = x² and g(x) = 2x - 9.

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The vector-valued function r(t) = (√(t^2+1), √t, ln(1-t)) is continuous for all values of t except t = 1. The unit tangent vector to the curve at the point (1, 0, -∞) cannot be determined because the function becomes undefined at t = 1.

The given vector-valued function r(t) is defined as r(t) = (√(t^2+1), √t, ln(1-t)). The function is continuous for all values of t except t = 1. At t = 1, the function ln(1-t) becomes undefined as ln(1-1) results in ln(0), which is undefined.

To find the unit tangent vector to the curve at a specific point, we need to differentiate the function r(t) and normalize the resulting vector. However, at the point (1, 0, -∞), the function is undefined due to the undefined value of ln(1-t) at t = 1. Therefore, the unit tangent vector at that point cannot be determined.

In summary, the vector-valued function r(t) = (√(t^2+1), √t, ln(1-t)) is continuous for all values of t except t = 1. The unit tangent vector to the curve at the point (1, 0, -∞) cannot be determined due to the undefined value of the function at t = 1.

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The given differential equation is -

(7x² − 2xy + 3) dx + (2y² − x² + 7) dy = 0.

To determine whether the given differential equation is exact or not, we need to check the equality of the mixed partial derivatives of both the coefficients of dx and dy.

Let's start with it.

The partial derivative of the coefficient of dx with respect to y (2nd term in it) is:

$$\frac{\partial}{\partial y} ( - 2xy ) = -2x$$

The partial derivative of the coefficient of dy with respect to x (2nd term in it) is:

$$\frac{\partial}{\partial x} ( -x^2 ) = -2x$$

Hence, the mixed partial derivatives of both the coefficients of dx and dy are equal, i.e.,

$$\frac{\partial}{\partial y} ( - 2xy ) = \frac{\partial}{\partial x} ( -x^2 ) $$

Thus, the given differential equation is exact. We can find the solution to the given differential equation by using the integrating factor, which is given by:

$$I(x,y) = e^{\int p(x)dx}$$

where p(x) is the coefficient of dx and the integrating factor of dx.

Let's determine p(x) from the given differential equation.

$$- (7x^2 - 2xy + 3) dx + (2y^2 - x^2 + 7) dy = 0

$$$$p(x) = -7x^2 + 2xy - 3$$$$I(x,y) = e^{\int -7x^2 + 2xy - 3 dx}$$$$= e^{-7x^3/3 + x^2y - 3x}$$

Multiplying the given differential equation with the integrating factor, we get:

$$- e^{-7x^3/3 + x^2y - 3x} (7x^2 - 2xy + 3) dx + e^{-7x^3/3 + x^2y - 3x} (2y^2 - x^2 + 7) dy = 0$$

Let F(x,y) be the solution to the given differential equation. Then, we have:

$$\frac{\partial F}{\partial x} = - e^{-7x^3/3 + x^2y - 3x} (7x^2 - 2xy + 3)$$$$\frac{\partial F}{\partial y} = e^{-7x^3/3 + x^2y - 3x} (2y^2 - x^2 + 7)$$

Integrating the first expression with respect to x, we get:

$$F(x,y) = \int \frac{\partial F}{\partial x} dx + g(y)$$$$= \int - e^{-7x^3/3 + x^2y - 3x} (7x^2 - 2xy + 3) dx + g(y)$$

Differentiating the above expression with respect to y, we get:

$$\frac{\partial F}{\partial y} = e^{-7x^3/3 + x^2y - 3x} (2y^2 - x^2 + 7)$$$$\Rightarrow e^{7x^3/3 - x^2y + 3x} \frac{\partial F}{\partial y} = 2y^2 - x^2 + 7$$

Differentiating the expression for F(x,y) with respect to y, we get:

$$\frac{\partial F}{\partial y} = e^{-7x^3/3 + x^2y - 3x} (x^2 + g'(y))$$

Comparing the above expression with the expression for $\frac{\partial F}{\partial y}$ obtained earlier, we get:$$x^2 + g'(y) = 2y^2 - x^2 + 7$$$$\Rightarrow g(y) = \frac{2y^3}{3} - yx^2 + 7y + C$$

where C is the constant of integration.

Substituting this value of g(y) in the expression for F(x,y), we get the solution to the given differential equation as:

$$F(x,y) = \int - e^{-7x^3/3 + x^2y - 3x} (7x^2 - 2xy + 3) dx + \frac{2y^3}{3} - yx^2 + 7y + C$$

Thus, we have determined that the given differential equation is exact.

The solution to the given differential equation is given by:

$$F(x,y) = \int - e^{-7x^3/3 + x^2y - 3x} (7x^2 - 2xy + 3) dx + \frac{2y^3}{3} - yx^2 + 7y + C$$

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The solution to the radical equation √√x+28 - √√x-20 = 4 is x = 1296.

To solve the given radical equation √√x+28 - √√x-20 = 4, we can follow these steps:

Step 1: Let's simplify the equation by introducing a new variable. Let's set u = √√x. This substitution will help us simplify the equation.

Substituting u back into the equation, we get:

√(u + 28) - √(u - 20) = 4

Step 2: To eliminate the radicals, we'll isolate one of them on one side of the equation. Let's isolate the first radical term √(u + 28).

√(u + 28) = 4 + √(u - 20)

Step 3: Square both sides of the equation to eliminate the remaining radicals:

(√(u + 28))^2 = (4 + √(u - 20))^2

Simplifying the equation:

u + 28 = 16 + 8√(u - 20) + (u - 20)

Step 4: Combine like terms:

u + 28 = 16 + u - 20 + 8√(u - 20)

Simplifying further:

u + 28 = u - 4 + 8√(u - 20)

Step 5: Simplify the equation further by canceling out the 'u' terms:

28 = -4 + 8√(u - 20)

Step 6: Move the constant term to the other side:

32 = 8√(u - 20)

Step 7: Divide both sides by 8:

4 = √(u - 20)

Step 8: Square both sides to eliminate the remaining radical:

16 = u - 20

Step 9: Add 20 to both sides:

36 = u

Step 10: Substitute back u = √√x:

36 = √√x

Step 11: Square both sides again to remove the radical:

36^2 = (√√x)^2

1296 = (√x)^2

Taking the square root of both sides:

√1296 = √(√x)^2

36 = √x

Step 12: Square both sides one more time:

36^2 = (√x)^2

1296 = x

Therefore, the solution to the radical equation √√x+28 - √√x-20 = 4 is x = 1296.

So, the correct choice is:

A. The solution set is (1296).

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From the comparisons, we can see that the Euler approximation with h = 0.1 is closer to the actual solution value at x = 1/2.

To apply Euler's method twice to approximate the solution to the

initial value problem, we start with the given equation:

y' = y + 3x - 11, y(0) = 7.

First, we will use a step size of h = 0.25.

For n = 0.25:

x₁ = 0 + 0.25 = 0.25

y₁ = y₀ + h * (y'₀) = 7 + 0.25 * (7 + 3 * 0 - 11) = 7 - 0.25 * 4 = 6.00

For n = 0.5:

x₂ = 0.25 + 0.25 = 0.5

y₂ = y₁ + h * (y'₁) = 6.00 + 0.25 * (6.00 + 3 * 0.25 - 11) = 6.00 - 0.25 * 4.75 = 5.6875

Now, we will use a step size of h = 0.1.

For n = 0.1:

x₁ = 0 + 0.1 = 0.1

y₁ = y₀ + h * (y'₀) = 7 + 0.1 * (7 + 3 * 0 - 11) = 7 - 0.1 * 4 = 6.60

For n = 0.2:

x₂ = 0.1 + 0.1 = 0.2

y₂ = y₁ + h * (y'₁) = 6.60 + 0.1 * (6.60 + 3 * 0.2 - 11) = 6.60 - 0.1 * 4.18 = 6.178

To compare the approximations with the actual solution at x = 1/2, we need to find the actual solution y(1/2).

Using the actual solution:

y(x) = 8 - 3x - [tex]e^x[/tex]

Substituting x = 1/2:

y(1/2) = 8 - 3(1/2) - [tex]e^{(1/2)[/tex] ≈ 6.393

Comparing the values:

Euler approximation with h = 0.25 at x = 1/2: 5.6875

Euler approximation with h = 0.1 at x = 1/2: 6.178

Actual solution value at x = 1/2: 6.393

From the comparisons, we can see that the Euler approximation with h = 0.1 is closer to the actual solution value at x = 1/2.

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To compute Az - dz, we first need to calculate the partial derivatives of the function f(x, y) = 3x² + 6xy - 5y².

Given function:

f(x, y) = 3x² + 6xy - 5y²

Partial derivative with respect to x (f₁'(x, y)):

f₁'(x, y) = ∂f/∂x = 6x + 6y

Partial derivative with respect to y (f₂'(x, y)):

f₂'(x, y) = ∂f/∂y = 6x - 10y

Now, let's calculate Az - dz:

Az = f(x + dx, y + dy) - f(x, y)

= [3(x + dx)² + 6(x + dx)(y + dy) - 5(y + dy)²] - [3x² + 6xy - 5y²]

= 3(x² + 2xdx + dx² + 2xydy + 2ydy + dy²) + 6(xdx + xdy + ydx + ydy) - 5(y² + 2ydy + dy²) - (3x² + 6xy - 5y²)

= 3x² + 6xdx + 3dx² + 6xydy + 6ydy + 3dy² + 6xdx + 6xdy + 6ydx + 6ydy - 5y² - 10ydy - 5dy² - 3x² - 6xy + 5y²

= 6xdx + 6xdy + 6ydx + 6ydy + 3dx² + 3dy² - 5dy² - 10ydy

dz = f₁'(x, y)dx + f₂'(x, y)dy

= (6x + 6y)dx + (6x - 10y)dy

Now, let's calculate Az - dz:

Az - dz = (6xdx + 6xdy + 6ydx + 6ydy + 3dx² + 3dy² - 5dy² - 10ydy) - ((6x + 6y)dx + (6x - 10y)dy)

= 6xdx + 6xdy + 6ydx + 6ydy + 3dx² + 3dy² - 5dy² - 10ydy - 6xdx - 6ydx - 6xdy + 10ydy

= (6xdx - 6xdx) + (6ydx - 6ydx) + (6ydy - 6ydy) + (6xdy + 6xdy) + (3dx² - 5dy²) + 10ydy

= 0 + 0 + 0 + 12xdy + 3dx² - 5dy² + 10ydy

= 12xdy + 3dx² - 5dy² + 10ydy

Therefore, Az - dz = 12xdy + 3dx² - 5dy² + 10ydy.

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The function f(x) = - 2x³ + 39x² - 180x + 7 has one local minimum and one local maximum. The local minimum is at x = 3 with value 7, and the local maximum is at x = 10 with value -277.

The function f(x) is a cubic function. Cubic functions have three turning points, which can be either local minima or local maxima. To find the turning points, we can take the derivative of the function and set it equal to zero. The derivative of f(x) is -6x(x - 3)(x - 10). Setting this equal to zero, we get three possible solutions: x = 0, x = 3, and x = 10. Of these three solutions, only x = 3 and x = 10 are real numbers.

To find whether each of these points is a local minimum or a local maximum, we can evaluate the second derivative of f(x) at each point. The second derivative of f(x) is -12(x - 3)(x - 10). At x = 3, the second derivative is positive, which means that the function is concave up at this point. This means that x = 3 is a local minimum. At x = 10, the second derivative is negative, which means that the function is concave down at this point. This means that x = 10 is a local maximum.

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To rewrite the integral ∫(36 - x²) dx using a trigonometric substitution, we substitute x = 6sin(theta) and dx = 6cos(theta) d(theta). The integral becomes ∫(36 - (6sin(theta))²) (6cos(theta)) d(theta).

To rewrite the integral ∫(36 - x²) dx using a trigonometric substitution, we make the substitution x = 6sin(theta), where -π/2 ≤ theta ≤ π/2. This choice of substitution is motivated by the Pythagorean identity sin²(theta) + cos²(theta) = 1, which allows us to replace x² with 36 - (6sin(theta))².

Taking the derivative of x = 6sin(theta) with respect to theta, we obtain dx = 6cos(theta) d(theta).

Substituting x = 6sin(theta) and dx = 6cos(theta) d(theta) in the integral, we have:

∫(36 - x²) dx = ∫(36 - (6sin(theta))²) (6cos(theta)) d(theta).

Simplifying the integrand, we have:

∫(36 - (6sin(theta))²) (6cos(theta)) d(theta) = ∫(36 - 36sin²(theta)) (6cos(theta)) d(theta).

Using the trigonometric identity cos²(theta) = 1 - sin²(theta), we can simplify further:

∫(36 - 36sin²(theta)) (6cos(theta)) d(theta) = ∫(36 - 36(1 - cos²(theta))) (6cos(theta)) d(theta).

Expanding and simplifying the integrand:

∫(36 - 36 + 36cos²(theta)) (6cos(theta)) d(theta) = ∫(36cos²(theta)) (6cos(theta)) d(theta).

Now, we have a simpler integral that can be evaluated using standard trigonometric integration techniques. The result will depend on the limits of integration, which are not specified in the given question.

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(a) the interval on which f is Increasing: (-∞, -3) U (2, ∞) and Decreasing: (-3, 2)

(b)  the local maximum and minimum values of f is Local maximum value: f(-3) = 117 and Local minimum value: f(2) = -44

(c) the intervals of concavity and the inflection points of the function is f''(x) = d²/dx² (6x² + 6x - 36)

(a) Find the interval on which f is increasing or decreasing:

Let's calculate the derivative of f(x):

f'(x) = d/dx (2x³ + 3x² - 36x)

= 6x² + 6x - 36

To find the critical points, we set f'(x) equal to zero and solve for x:

6x² + 6x - 36 = 0

x² + x - 6 = 0

(x + 3)(x - 2) = 0

x = -3 or x = 2

We have two critical points: x = -3 and x = 2. We'll use these points to determine the intervals of increasing and decreasing.

Test a value in each interval:

For x < -3, let's choose x = -4:

f'(-4) = 6(-4)² + 6(-4) - 36

       = 72 - 24 - 36

        = 12

For -3 < x < 2, let's choose x = 0:

f'(0) = 6(0)² + 6(0) - 36

        = -36

For x > 2, let's choose x = 3:

f'(3) = 6(3)² + 6(3) - 36

      = 54 + 18 - 36

       = 36

Based on the signs of f'(x) in the test intervals, we can determine the intervals of increasing and decreasing:

Increasing: (-∞, -3) U (2, ∞)

Decreasing: (-3, 2)

(b) Find the local maximum and minimum values of f:To find the local maximum and minimum values, we'll evaluate f(x) at the critical points and endpoints of the intervals.

Critical point x = -3:

f(-3) = 2(-3)³ + 3(-3)² - 36(-3)

       = -18 + 27 + 108

       = 117

Critical point x = 2:

f(2) = 2(2)³ + 3(2)² - 36(2)

     = 16 + 12 - 72

     = -44

Endpoints of the interval (-∞, -3):

f(-∞) = lim(x->-∞) f(x) = -∞

f(-3) = 117

Endpoints of the interval (-3, 2):

f(-3) = 117

f(2) = -44

Endpoints of the interval (2, ∞):

f(2) = -44

f(∞) = lim(x->∞) f(x) = ∞

Local maximum value: f(-3) = 117

Local minimum value: f(2) = -44

(c) Find the intervals of concavity and the inflection points of the function:

we'll calculate the second derivative of f(x):

f''(x) = d²/dx² (6x² + 6x - 36)

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A) The determinant of A can only be ±1. and b) A = I is the only such matrix that satisfies the condition A³ = A²A = A when n = 3.

a) We have given that A is an invertible, n × n matrix such that A² = A.

To calculate the det(A), we will multiply both sides of the equation A² = A with A⁻¹ on the left side.

A² = A

⇒ A⁻¹A² = A⁻¹A

⇒ A = A⁻¹A

Determinant of both sides of A

= A⁻¹ADet(A) = Det(A⁻¹A)

= Det(A⁻¹)Det(A)

= (1/Det(A))Det(A)

⇒ Det²(A) = 1

⇒ Det(A) = ±1

As A is an invertible matrix, hence the determinant of A is not equal to 0.

Therefore, the determinant of A can only be ±1.

b) If n = 3, then we can say A³ = A²A = A.

Multiplying both sides by A,

we get

A⁴ = A²A² = AA² = A

Using the given equation A² = A and A ≠ 0,

we get A = I, where I is the identity matrix of order n x n, which in this case is 3 x 3.

Therefore,

Note:

The above proof of A = I is for the case when n = 3.

For other values of n, we cannot conclude that A = I from A³ = A²A = A.

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Σ* is the Kleene Closure of a given alphabet Σ. It is an underlying set of strings obtained by repeated concatenation of the elements of the alphabet.

For the given cases, the alphabets Σ are as follows:

Case 1: {0}
Case 2: {0, 1}
Case 3: {0, 1, 2}

In each of the cases above, the corresponding Σ* can be represented as:

Case 1: Σ* = {Empty String, 0, 00, 000, 0000, ……}
Case 2: Σ* = {Empty String, 0, 1, 00, 01, 10, 11, 000, 001, 010, 011, 100, 101, 110, 111, ……}
Case 3: Σ* = {Empty String, 0, 1, 2, 00, 01, 02, 10, 11, 12, 20, 21, 22, 000, 001, 002, 010, 011, 012, 020, 021, 022, 100, 101, 102, 110, 111, 112, 120, 121, 122, 200, 201, 202, 210, 211, 212, 220, 221, 222, ……}

Thus, 15 elements from each of the Σ* sets are as follows:
Case 1: Empty String, 0, 00, 000, 0000, 00000, 000000, 0000000, 00000000, 000000000, 0000000000, 00000000000, 000000000000, 0000000000000, 00000000000000

Case 2: Empty String, 0, 1, 00, 01, 10, 11, 000, 001, 010, 011, 100, 101, 110, 111

Case 3: Empty String, 0, 1, 2, 00, 01, 02, 10, 11, 12, 20, 21, 22, 000, 001

From the above analysis, it can be concluded that the Kleene Closure of a given alphabet consists of all possible combinations of concatenated elements from the given alphabet including the empty set. It is a powerful tool that can be applied to both regular expressions and finite state automata to simplify their representation.

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The integral of √(20) e^(-x²+4x) dx equals √(e), which can be done by completing the square in the exponent.

To solve the integral √(20) e^(-x²+4x) dx, we can start by completing the square in the exponent.

Completing the square: -x² + 4x = -(x² - 4x) = -(x² - 4x + 4 - 4) = -(x - 2)² + 4

Now, the integral becomes: √(20) e^(-(x - 2)² + 4) dx

We can rewrite this as: √(20) e^(-4) e^(-(x - 2)²) dx

Since e^(-4) is a constant, we can bring it outside the integral:

√(20) e^(-4) ∫ e^(-(x - 2)²) dx

The integral ∫ e^(-(x - 2)²) dx is the standard Gaussian integral and equals √π.

Therefore, the integral becomes: √(20) e^(-4) √π

Simplifying further: √(20π) e^(-4)

Taking the square root of e^(-4), we get: √e^(-4) = √e

So, the value of the integral is √(20π) e^(-4), which is equal to √e.

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The function is not continuous at a = 6 because f(6) is undefined. This is because the function has different definitions for x ≠ 6 and x = 6, indicating a discontinuity.Option B

To determine the continuity of the function at a = 6, we need to check if three conditions are satisfied: 1) The function is defined at a = 6, 2) The limit of the function as x approaches 6 exists, and 3) The limit of the function as x approaches 6 is equal to the value of the function at a = 6.

In this case, the function is defined as x² - 36x - 6 for x ≠ 6, and as 8 for x = 6. Thus, the function is not defined at a = 6, violating the first condition for continuity. Therefore, the function is not continuous at a = 6.

Option B is the correct choice because it states that the function is not continuous at a = 6 because f(6) is undefined.

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the growth rate, k, is approximately 1.98%.

To find the growth rate, k, we can use the formula for continuous compound interest:

A = P * [tex]e^{(rt)}[/tex]

Where:

A = final amount (twice the initial investment)

P = initial investment

r = growth rate (in decimal form)

t = time (in years)

Given that the initial investment, P, is $61738 and the doubling time is 35 years, we can set up the equation as follows:

2P = P *[tex]e^{(r * 35)}[/tex]

Divide both sides of the equation by P:

2 = [tex]e^{(35r)}[/tex]

To solve for r, take the natural logarithm (ln) of both sides:

ln(2) = ln([tex]e^{(35r)}[/tex])

Using the property l[tex]n(e^x)[/tex] = x:

ln(2) = 35r

Now, divide both sides by 35:

r = ln(2) / 35

Using a calculator, we can evaluate this :

r ≈ 0.0198

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The area of the region enclosed by the curves y = 3 cos x and y = 3 cos 2x for 0 ≤ x ≤ T is given by the expression -3/2 sin 2T - 3 sin T.

To find the area of the region enclosed by the curves y = 3 cos x and y = 3 cos 2x for 0 ≤ x ≤ T, we need to calculate the definite integral of the difference between the two functions over the given interval.

The integral for the area can be expressed as:

A = ∫[0,T] (3 cos 2x - 3 cos x) dx

To simplify the integration, we can use the trigonometric identity cos 2x = 2 cos² x - 1:

A = ∫[0,T] (3(2 cos² x - 1) - 3 cos x) dx

= ∫[0,T] (6 cos² x - 3 - 3 cos x) dx

Now, let's integrate term by term:

A = ∫[0,T] 6 cos² x dx - ∫[0,T] 3 dx - ∫[0,T] 3 cos x dx

To integrate cos² x, we can use the double angle formula cos² x = (1 + cos 2x)/2:

A = ∫[0,T] 6 (1 + cos 2x)/2 dx - 3(T - 0) - ∫[0,T] 3 cos x dx

= 3 ∫[0,T] (1 + cos 2x) dx - 3T - 3 ∫[0,T] cos x dx

= 3 [x + (1/2) sin 2x] |[0,T] - 3T - 3 [sin x] |[0,T]

Now, let's substitute the limits of integration:

A = 3 [(T + (1/2) sin 2T) - (0 + (1/2) sin 0)] - 3T - 3 [sin T - sin 0]

= 3 (T + (1/2) sin 2T) - 3T - 3 (sin T - sin 0)

= 3T + (3/2) sin 2T - 3T - 3 sin T + 3 sin 0

= -3/2 sin 2T - 3 sin T

Therefore, the area of the region enclosed by the curves y = 3 cos x and y = 3 cos 2x for 0 ≤ x ≤ T is given by the expression -3/2 sin 2T - 3 sin T.

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the magnitude of the cross product a x  is approximately 6.88.To find the cross product of two vectors, we can use the formula:
a x b = |a| |b| sin(theta) n

where |a| and |b| are the magnitudes of the vectors a and b, theta is the angle between them, and n is the unit vector perpendicular to the plane formed by a and b.
Given that |a| = 3, |b| = 4, and the angle between a and b is 35°, we can calculate the cross product as:
|a x b| = |a| |b| sin(theta)
|a x b| = 3 * 4 * sin(35°)
|a x b| ≈ 6.88
Therefore, the magnitude of the cross product a x  is approximately 6.88.

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Given that at t=0 the population is 30 cells and is increasing at a rate of 15 cells/hour, we need to determine the rate at which the population is changing after 2 hours. Therefore, n'(2) = 2(1 + (sqrt(30) - 1)e^(-0.62)) * (-0.6(sqrt(30) - 1)e^(-0.62)).

To find the rate at which the population of yeast cells is changing after 2 hours, we need to calculate the derivative of the population function with respect to time (t).

First, let's find the constant value "a" and the constant value "b" in the population function. Since at t=0 the population is 30 cells, we can substitute this value into the equation:

30 = (1 + be^(-0.6*0))^2 = (1 + b)^2.

Solving for "b," we find b = sqrt(30) - 1.

Next, we differentiate the population function with respect to t:

n'(t) = 2(1 + be^(-0.6t)) * (-0.6b e^(-0.6t)).

Substituting t = 2 into the derivative, we have:

n'(2) = 2(1 + (sqrt(30) - 1)e^(-0.62)) * (-0.6(sqrt(30) - 1)e^(-0.62)).

Evaluating this expression will give us the rate at which the population of yeast cells is changing after 2 hours.

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Let's solve the differential equation [tex]\((D^2 + D - 2)(D - 3)y = 0\)[/tex]  step by step.

First, we can expand the differential operator [tex]\((D^2 + D - 2)(D - 3)\):[/tex]

[tex]\[(D^2 + D - 2)(D - 3) = D^3 - 3D^2 + D^2 - 3D - 2D + 6\]\[= D^3 - 2D^2 - 5D + 6\][/tex]

Now, we have the simplified differential equation:

[tex]\[D^3 - 2D^2 - 5D + 6)y = 0\][/tex]

To find the solutions, we assume that [tex]\(y\)[/tex] can be expressed as [tex]\(y = e^{rx}\)[/tex], where [tex]\(r\)[/tex] is a constant.

Substituting [tex]\(y = e^{rx}\)[/tex] into the differential equation:

[tex]\[D^3 - 2D^2 - 5D + 6)e^{rx} = 0\][/tex]

We can factor out [tex]\(e^{rx}\)[/tex] from the equation:

[tex]\[e^{rx}(D^3 - 2D^2 - 5D + 6) = 0\][/tex]

Since [tex]\(e^{rx}\)[/tex] is never zero, we can focus on solving the polynomial equation:

[tex]\[D^3 - 2D^2 - 5D + 6 = 0\][/tex]

To find the roots of this equation, we can use various methods such as factoring, synthetic division, or the rational root theorem. In this case, we can observe that [tex]\(D = 1\)[/tex] is a root.

Dividing the polynomial by [tex]\(D - 1\)[/tex] using synthetic division, we get:

[tex]\[1 & 1 & -2 & -5 & 6 \\ & & 1 & -1 & -6 \\\][/tex]

The quotient is [tex]\(D^2 - D - 6\),[/tex] which can be factored as [tex]\((D - 3)(D + 2)\).[/tex]

So, the roots of the polynomial equation are [tex]\(D = 1\), \(D = 3\), and \(D = -2\).[/tex]

Now, let's substitute these roots back into [tex]\(y = e^{rx}\)[/tex] to obtain the solutions:

For [tex]\(D = 1\),[/tex] we have [tex]\(y_1 = e^{1x} = e^x\).[/tex]

For [tex]\(D = 3\),[/tex] we have [tex]\(y_2 = e^{3x}\).[/tex]

For [tex]\(D = -2\)[/tex], we have [tex]\(y_3 = e^{-2x}\).[/tex]

The general solution is a linear combination of these solutions:

\[y = C_1e^x + C_2e^{3x} + C_3e^{-2x}\]

This is the general solution to the differential equation [tex]\((D^2 + D - 2)(D - 3)y = 0\).[/tex] Each term represents a possible solution, and the constants [tex]\(C_1\), \(C_2\), and \(C_3\)[/tex] are arbitrary constants that can be determined by initial conditions or additional constraints specific to the problem at hand.

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The system is not consistent, the system is inconsistent.

[tex]x_1 + 3x_2 +2x_3-x_4=-1\\-2x_1-5x_2-5x_3+4x_4=1\\-4x_1-12x_2-8x_3+4x_4=6[/tex]

In matrix notation this can be expressed as:

[tex]\left[\begin{array}{cccc}1&3&2&-1\\-2&-5&-5&4&4&-12&8&4&\\\end{array}\right] \left[\begin{array}{c}x_1&x_2&x_3&x_4\\\\\end{array}\right] =\left[\begin{array}{c}-1&1&6\\\\\end{array}\right][/tex]

The augmented matrix becomes,

[tex]\left[\begin{array}{cccc}1&3&2&-1\\-2&-5&-5&4&4&-12&8&4&\\\end{array}\right] \lef \left[\begin{array}{c}-1&1&6\\\\\end{array}\right][/tex]

i.e.

[tex]\left[\begin{array}{ccccc}1&3&2&-1&-1\\-2&-5&-5&4&1&4&-12&8&4&6\end{array}\right][/tex]

Using row reduction we have,

R₂⇒R₂+2R₁

R₃⇒R₃+4R₁

[tex]\left[\begin{array}{ccccc}1&3&2&-1&-1\\0&1&-1&2&-1\\0&0&0&0&2\end{array}\right][/tex]

R⇒R₁-3R₂,

[tex]\left[\begin{array}{ccccc}1&0&5&-7&2\\0&1&-1&2&-1\\0&0&0&0&2\end{array}\right][/tex]

As the rank of coefficient matrix is 2 and the rank of  augmented matrix is 3.

The rank are not equal.

Therefore, the system is not consistent.

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To solve the initial value problem x" + 7.84x = 4cos(3t), x(0) = x'(0) = 0, we can use the method of undetermined coefficients.

First, let's find the complementary solution to the homogeneous equation x" + 7.84x = 0:

The characteristic equation is [tex]r^2[/tex] + 7.84 = 0.

Solving the characteristic equation, we find the roots: r = ±2.8i.

The complementary solution is given by:

[tex]x_{compl(t)}[/tex] = C1*cos(2.8t) + C2*sin(2.8t).

Next, we need to find a particular solution to the non-homogeneous equation x" + 7.84x = 4cos(3t). Since the right-hand side is in the form of cos(3t), we assume a particular solution of the form:

[tex]x_{part(t)}[/tex] = A*cos(3t) + B*sin(3t).

Differentiating [tex]x_{part(t)}[/tex] twice, we have:

[tex]x_{part}[/tex]''(t) = -9A*cos(3t) - 9B*sin(3t).

Substituting these derivatives into the original equation, we get:

(-9A*cos(3t) - 9B*sin(3t)) + 7.84(A*cos(3t) + B*sin(3t)) = 4cos(3t).

Matching the coefficients of cos(3t) and sin(3t), we have the following equations:

7.84A - 9B = 4,

-9A - 7.84B = 0.

Solving these equations, we find A ≈ 0.622 and B ≈ 0.499.

Therefore, the particular solution is:

[tex]x_{part}[/tex](t) ≈ 0.622*cos(3t) + 0.499*sin(3t).

Finally, the general solution to the initial value problem is the sum of the complementary and particular solutions:

x(t) = [tex]x_{compl(t}[/tex]) + [tex]x_{part(t)}[/tex]

     = C1*cos(2.8t) + C2*sin(2.8t) + 0.622*cos(3t) + 0.499*sin(3t).

To confirm the phenomenon of beats, we can graph the solution and observe the interference pattern. The beats occur due to the difference in frequencies between the cosine and sine terms in the particular solution.

The length of each beat can be determined by calculating the period of the envelope of the beats. In this case, the frequency difference is |3 - 2.8| = 0.2. The period of the envelope is given by [tex]T_{env}[/tex] = 2π/0.2 = 10π. Therefore, the length of each beat is 10π.

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The solution is that f(x) = x^2, g(x) = x + 1, and h(x) = x^3. This can be found by plugging in the given y-values and x-values into the equations for f, g, and h.

The y-values for f are 5 and 1, and the x-values are 2 and 3. This means that f(2) = 5 and f(3) = 1. The x-values for g are 2 and 3, and the y-values are 5 and 1. This means that g(2) = 5 and g(3) = 1. The x-values for h are 1, 2, and 3, and the y-values are 4, 8, and 27. This means that h(1) = 4, h(2) = 8, and h(3) = 27.

Plugging these values into the equations for f, g, and h, we get the following:

```

f(x) = x^2

g(x) = x + 1

h(x) = x^3

```

This is the solution to the problem.

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The total number of items purchased during the accounting period was 53 items, and the total cost of the purchases was $217.00.

During the last accounting period, purchases of an inventory item were made in varying quantities and at different unit prices.

The total number of items purchased can be calculated by an expression obtained by summing the quantities, and the total cost of the purchases can be found by multiplying the quantity of each item by its corresponding unit price and summing the results.

To determine the total number of items purchased, we add up the quantities: 5 + 3 + 7 + 11 + 27 = 53 items.

To calculate the total cost of the purchases, we multiply the quantity of each item by its unit price and sum the results.

For the first purchase of 5 items at $4.00 per item, the cost is 5 * $4.00 = $20.00.

The second purchase of 3 items at $6.00 per item has a cost of 3 * $6.00 = $18.00.

The third purchase of 1 item at $9.00, the fourth purchase of 7 items at $7.00 per item, and the fifth purchase of 11 items at $11.00 per item have costs of $9.00, 7 * $7.00 = $49.00, and 11 * $11.00 = $121.00, respectively.

Adding up all the costs, we have $20.00 + $18.00 + $9.00 + $49.00 + $121.00 = $217.00.

Therefore, the total number of items purchased during the accounting period was 53 items, and the total cost of the purchases was $217.00.

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To graph the circle, plot the center point at (2, -3) and then use the radius of 3 to determine the points on the circle.

To graph the ellipse given by the equation 9(x-1)² + 4(y+2)² = 36, we can start by rewriting the equation in standard form. The standard form of an ellipse equation is:

(x-h)²/a² + (y-k)²/b² = 1,

where (h, k) represents the center of the ellipse, and a and b represent the lengths of the major and minor axes, respectively.

For the given equation, we have:

9(x-1)² + 4(y+2)² = 36.

Dividing both sides of the equation by 36, we get:

(x-1)²/4 + (y+2)²/9 = 1.

we see that the center of the ellipse is at (1, -2), and the lengths of the major and minor axes are 2a = 4 and 2b = 6, respectively.

To graph the ellipse, we can plot the center point at (1, -2) and then use the values of 2a and 2b to determine the endpoints of the major and minor axis.

The standard form of the equation of a circle is:

(x-h)² + (y-k)² = r²,

where (h, k) represents the center of the circle, and r represents the radius.

For the given circle with center (2, -3) and radius r = 3, the standard form of the equation is:

(x-2)² + (y+3)² = 3²,

(x-2)² + (y+3)² = 9.

To graph the circle, plot the center point at (2, -3) and then use the radius of 3 to determine the points on the circle. These points will be 3 units away from the center in all directions.

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To find the values of a for which u and v are orthogonal, the dot product of u and v is given by u · v = a · 7 + 5 · a = 7a + 5a = 12a. Setting this equal to zero, we have 12a = 0. Solving for a, we find a = 0.

Orthogonal vectors are vectors that are perpendicular to each other, meaning that the angle between them is 90 degrees. In the context of the dot product, two vectors are orthogonal if and only if their dot product is zero.

Given the vectors u = [a, 7] and v = [5, a], we can find their dot product by multiplying the corresponding components and summing them up. The dot product of u and v is given by u · v = (a * 5) + (7 * a) = 5a + 7a = 12a.

For the vectors u and v to be orthogonal, their dot product must be zero. So we set 12a = 0 and solve for "a". Dividing both sides of the equation by 12, we find that a = 0.

Therefore, the only value of "a" for which u and v are orthogonal is a = 0. This means that when "a" is zero, the vectors u and v are perpendicular to each other. For any other value of "a", they are not orthogonal.

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The limit of f(x)g(x) as x approaches 3 is 0.

Since f(x) approaches 200 and g(x) approaches 0 as x approaches 3, we have:

limx→3 f(x)g(x) = limx→3 [f(x) × g(x)]

                     = limx→3 [200 g(x)]

Since g(x) is negative as x approaches 3 and approaches 0, the product f(x)g(x) will approach 0 as well.

Therefore, we can write:

limx→3 f(x)g(x) = limx→3 [200 × g(x)]

                      = 200 × limx→3 g(x)

                      = 200 × 0

                     = 0

Thus, the limit of f(x)g(x) as x approaches 3 is 0.

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