Solve the equation 3 tan²θ-1=0.

The second-order differential equation in y is d²y/dt² = 3y + 6t - 1. Solving this equation gives the general solution y(t) = c₁e^(sqrt(6t + 2)t) + c₂e^(-sqrt(6t + 2)t). Substituting the initial conditions x(0) = 1 and y(0) = -4, we can find the specific values of c₁ and c₂ and determine x(t) as a function of t.

To convert the system of equations into a second-order differential equation, we differentiate the second equation with respect to t and substitute for x using the first equation.

Given the system of equations:

1) dx/dt = y + 2t

2) dy/dt = 3x - t

Differentiating equation 2) with respect to t:

d²y/dt² = 3(dx/dt) - dt/dt

        = 3(y + 2t) - 1

        = 3y + 6t - 1

Now we have a second-order differential equation in terms of y:

d²y/dt² = 3y + 6t - 1

To solve this equation, we need initial conditions. Given x(0) = 1 and y(0) = -4, we can find the particular solution for y(t). Then, we can substitute the solution for y(t) back into the first equation to find x(t).

Solving the differential equation:

d²y/dt² = 3y + 6t - 1

We can solve this second-order linear homogeneous differential equation by assuming a solution of the form y(t) = e^(rt). By substituting this into the differential equation, we find the characteristic equation:

r²e^(rt) = 3e^(rt) + 6te^(rt) - e^(rt)

r² = 3 + 6t - 1

r² = 6t + 2

Solving the characteristic equation, we find two roots:

r₁ = sqrt(6t + 2)

r₂ = -sqrt(6t + 2)

The general solution for y(t) is then given by:

y(t) = c₁e^(sqrt(6t + 2)t) + c₂e^(-sqrt(6t + 2)t)

Now, we can substitute the initial condition y(0) = -4 to find c₁ and c₂:

-4 = c₁e^(sqrt(2) * 0) + c₂e^(-sqrt(2) * 0)

-4 = c₁ + c₂

Now, to find x(t), we substitute the solution for y(t) back into the first equation:

dx/dt = y + 2t

dx/dt = (c₁e^(sqrt(6t + 2)t) + c₂e^(-sqrt(6t + 2)t)) + 2t

Integrating both sides with respect to t, we obtain:

x(t) = ∫ [(c₁e^(sqrt(6t + 2)t) + c₂e^(-sqrt(6t + 2)t)) + 2t] dt

The integration of the right side can be evaluated to find x(t) as a function of t.

Given the initial condition x(0) = 1, we can substitute t = 0 into the equation for x(t) and solve for c₁ and c₂. This will give us the specific values of c₁ and c₂.

Once we have determined the values of c₁ and c₂, we can substitute them back into the expressions for y(t) and x(t) to find the specific solutions for y and x, respectively.

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P(77 < X < 122) = 0.85.

To find the probability of a range of values in a normal distribution, we need to calculate the area under the curve between those values. In this case, we want to find the probability that X falls between 77 and 122.

First, we need to standardize the values by converting them into z-scores. The formula for calculating the z-score is (X - μ) / σ, where X is the value, μ is the mean, and σ is the standard deviation.

For 77, the z-score is (77 - 98) / 18 = -1.17, and for 122, the z-score is (122 - 98) / 18 = 1.33.

Using a standard normal distribution table or calculator, we can find that the area to the left of -1.17 is 0.121 and the area to the left of 1.33 is 0.908. To find the area between the two z-scores, we subtract the smaller area from the larger area: 0.908 - 0.121 = 0.787.

Therefore, P(77 < X < 122) = 0.787, rounded to 2 decimal places, is 0.79.

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The given graph represents the function f(2), and we need to determine the first rule for continuity that is violated at I = 2.Let us first recall the rules of continuity:a function f(x) is continuous at x = a if1. f(a) is defined,2. limx→a exists and is finite,3. limx→a f(x) = f(a).

Now, let us analyze the graph provided. We see that the graph is a curve that approaches (2,3) from both sides, but it is undefined at x = 2. Hence, the function violates the first rule of continuity, i.e., f(a) is not defined, since the value of the function at x = 2 is undefined. Therefore, the correct option is (a) is defined.Continuity is an essential concept in calculus and analysis. It is used to define and understand functions that are differentiable or integrable.

A function is said to be continuous if it does not have any jumps or discontinuities. A function that is not continuous at a point is said to be discontinuous at that point.

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To find the Fourier series of the periodic function defined by f(x) = z for -π ≤ x < π and f(x + 2π) = f(x), we can use the Fourier series expansion formula and compute the coefficients for each term in the series.

The Fourier series expansion of a periodic function f(x) with period 2π is given by:

f(x) = a0 + Σ[an cos(nx) + bn sin(nx)]

To find the Fourier coefficients an and bn, we can use the formulas:

an = (1/π) ∫[f(x) cos(nx) dx]

bn = (1/π) ∫[f(x) sin(nx) dx]

In this case, the function f(x) is defined as f(x) = z for -π ≤ x < π. Since f(x + 2π) = f(x), the function is periodic with period 2π.

To compute the Fourier coefficients, we substitute the function f(x) = z into the formulas for an and bn and integrate over the interval -π to π:

an = (1/π) ∫[z cos(nx) dx] = 0 (since the integral of a constant multiplied by a cosine function over a symmetric interval is zero)

bn = (1/π) ∫[z sin(nx) dx] = (2/π) ∫[0 to π][z sin(nx) dx] = (2/π) [z/n] [cos(nx)] from 0 to π = (2z/π) [1 - cos(nπ)]

Therefore, the Fourier series for the given periodic function f(x) = z for -π ≤ x < π is:

f(x) = a0 + Σ[(2z/π) [1 - cos(nπ)] sin(nx)]

In summary, the Fourier series of the periodic function f(x) = z for -π ≤ x < π is given by f(x) = a0 + Σ[(2z/π) [1 - cos(nπ)] sin(nx)].

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The integer which is a prime number is d) 498371.

A prime integer is an integer that can only be divided by 1 and itself.

It is an integer greater than 1 that cannot be formed by multiplying two smaller integers.

We can use the following steps to determine whether the given integers are prime.

Step 1: Divide the integer by the integers greater than 1 and smaller than the integer itself.

Step 2: If the remainder is zero in any case, then the integer is not prime. Otherwise, it is prime.

Determine whether each of the following integers is a prime:

a) Divide 33337777 by integers greater than 1 and less than 33337777.33337777 is divisible by 7, 11, 13, 37, and other integers. Therefore, it is not a prime number.

b) Divide 10001 by integers greater than 1 and less than 10001.10001 is divisible by 73. Therefore, it is not a prime number.

c) Divide 159 by integers greater than 1 and less than 159.159 is divisible by 3, 53. Therefore, it is not a prime number.

d) Divide 498371 by integers greater than 1 and less than 498371.498371 is not divisible by any integer except 1 and 498371. Therefore, it is a prime number.

Thus, the correct answer is d) 498371.

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The correct option is B, the minimum is at 14 items.

The cost function is given by:

c(x) = x³ - 24x² + 30,000x

The average cost is:

c(x)/x = x² -48x + 30000

The minimum of that is at the vertex of the quadratic, remember that for the general quadratic:

y = ax² + bx + c

The vertex is at:

x = -b/2a

So in this case the minimum is at:

x = 24/(2*1) = 14

So the correct option is B.

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(i) To rewrite the integrand as the sum of smaller proper fractions, we can perform partial fraction decomposition. The given integrand is:

[tex](x - 1) / [(x^2 + 3)^3 * (4x + 5)^4][/tex]

The denominator can be factored as follows:

[tex](x^2 + 3)^3 * (4x + 5)^4 = (x^2 + 3) * (x^2 + 3) * (x^2 + 3) * (4x + 5) * (4x + 5) * (4x + 5) * (4x + 5)[/tex]

To find the partial fraction decomposition, we assume the following form:

[tex](x - 1) / [(x^2 + 3)^3 * (4x + 5)^4] = A / (x^2 + 3) + B / (x^2 + 3)^2 + C / (x^2 + 3)^3 + D / (4x + 5) + E / (4x + 5)^2 + F / (4x + 5)^3 + G / (4x + 5)^4[/tex]

Now we need to find the values of A, B, C, D, E, F, and G.

(ii) From the given information, we have the equation:

x³ + 2x² + 3 = Ax³ - 3Ax - 5A + 2Bx² + 6Bx + Bx³ - 4Dx² + 10D - 9Ex + 15E

By equating the coefficients of like powers of x on both sides, we can form the following system of equations:

For x³ term:

1 = A + B

For x² term:

2 = 2B - 4D

For x term:

0 = -3A + 6B - 9E

For constant term:

3 = -5A + 10D + 15E

Therefore, the system of equations needed to solve for A, B, D, and E is:

A + B = 1

2B - 4D = 2

-3A + 6B - 9E = 0

-5A + 10D + 15E = 3

Solving this system of equations will give us the values of A, B, D, and E.

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To evaluate the given indefinite integrals using integration by trigonometric substitution:

1. ∫ du / (u² + a²)²

2. ∫ xdx / (1 - x)³

3. ∫ dx / (1 + x)

4.∫ (1 - x)dx

For the first integral, substitute u = a * tanθ (trigonometric substitution) to simplify the expression. The integral will involve trigonometric functions and can be solved using standard trigonometric identities.

The second integral requires a substitution of x = 1 - t (algebraic substitution). After substitution, simplify the expression and solve the resulting integral.

The third integral can be solved directly by using the natural logarithm function. Apply the integral rule for ln|x| to evaluate the integral.

The fourth integral involves a polynomial expression. Expand the expression, integrate term by term, and apply the power rule of integration to find the result.

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(0, 0) and (-2, 0). are the x-intercepts (if any) for the graph of the quadratic function.

The given function is f(x) = (x + 1)² - 1.

We need to find the x-intercepts (if any) for the graph of the quadratic function.

The x-intercepts occur when f(x) = 0.

So we will substitute 0 for f(x) and solve for x.

Let's do this now:f(x) = 0⇒ (x + 1)² - 1 = 0⇒ (x + 1)² = 1⇒ x + 1 = ±√1⇒ x = -1 ± 1

Now, we have two solutions for x: x = -1 + 1 = 0 and x = -1 - 1 = -2

Hence, the x-intercepts are (0, 0) and (-2, 0).

Thus, the correct option is C. (0, 0) and (-2, 0)..

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(a) The given differential equation represents a second-order linear time-invariant (LTI) system. A mechanical analogue of this type of equation in physics is the motion of a damped harmonic oscillator, where the displacement of the object is analogous to the charge q, and the forces acting on the object are analogous to the terms involving derivatives.

(b) In the critically damped case, the characteristic equation of the LCR circuit is a second-order equation with equal roots. The solution takes the form:

q_c(t) = (A + Bt) * e^(-Rt/(2L))

(c) If C = 6 µF, R = 10 Ω, and L = 0.5 H, the circuit exhibits over-damping because the resistance is greater than the critical damping value. In this case, the general solution for q(t) can be written as:

q(t) = q_c(t) + g(t)

where g(t) is the particular solution determined by the initial conditions or external forcing.

(d) The natural frequency of the circuit can be calculated using the formula:

ω = 1 / √(LC)

Substituting the given values, we have:

ω = 1 / √(0.5 * 6 * 10^-6) = 1 / √(3 * 10^-6) ≈ 5773.5 rad/s

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(a)The resulting vector is (13, -3, 10) .(b)The magnitude is 70 .(c)The distance is 774.(d)The resulting vector is (-122, -190, -34)

(a) To compute 3v - 2u, we multiply each component of v by 3, each component of u by -2, and subtract the results. The resulting vector is (13, -3, 10).(b) To find the magnitude of u + v + w, we add the corresponding components of u, v, and w, square each result, sum them, and take the square root. The magnitude is 70.(c) The distance between -3u and v + Sw is computed by subtracting the vectors, finding their magnitude, and simplifying the expression. The distance is 774.

(d) To compute the projection of u onto itself (proju), we use the formula proju = (u · u) / ||u||². This gives us (2, 0, -4).(e) The vector u × (v × w) represents the cross product of v and w, then taking the cross product with u. The resulting vector is (-122, -190, -34).In exercise 2, we are given three new vectors: u=3i - 5j + k, v= -2i + 2k, and w= -j + 4k.

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The function [tex]u(x,y)[/tex] is a harmonic function over the domain (x,y) # (0,0) and B₂ ((2,3)) denotes the ball whose center is (2,3) and whose radius is 2.

Harmonic functions are functions that satisfy the Laplace equation, which is a partial differential equation that appears frequently in various fields such as engineering, physics, and mathematics. The given function [tex]u(x,y)[/tex] is a harmonic function over the domain (x,y) # (0,0). B₂ ((2,3)) denotes the ball whose center is (2,3) and whose radius is 2.

We can say that B₂ ((2,3)) is an open ball, and JB₂ ((2,3)) denotes the boundary of the ball B₂ ((2,3)). The boundary of a ball is a circle with a radius of r, and the center at the origin. In this case, the boundary JB₂ ((2,3)) is the circle of radius 2 centered at (2,3).

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The solution is:

[tex]x = |A1| / |A| \\= 15 / 4 \\= 3.75y \\= |A2| / |A|\\= 15 / 4 \\= 3.75.[/tex]

Therefore, the answer is A)(0, 15)

The given system of equations is: [tex]y = -3x + 15 y = x[/tex]

The system of equations using determinants can be solved using Cramer's rule:

Here, the coefficient matrix is: [tex]A = [ 1 -1 , 3 1 ][/tex], and the matrix of constants is [tex]B = [ 15, 0 ][/tex]

The determinant of the coefficient matrix is |A| = 1 × 1 - ( -1 ) × 3 = 4.

The determinant obtained by replacing the first column of the coefficient matrix with the matrix of constants is[tex]|A1| = 15 × 1 - 0 × ( -1 ) = 15.[/tex]

The determinant obtained by replacing the second column of the coefficient matrix with the matrix of constants is

|[tex]A2| = 1 × 0 - ( -1 ) × 15 \\= 15.[/tex]

Now, the solution is:

[tex]x = |A1| / |A| \\= 15 / 4 \\= 3.75y \\= |A2| / |A| \\= 15 / 4 \\= 3.75[/tex]

Therefore, the answer is A)(0, 15)

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We need to find the scalars a1, a2, a3,..., a_n such that B can be written as a linear combination of vectors in the basis set %.

The linear combination of basis vectors for vector B is given as;B = a1%1 + a2%2 + a3%3 + ... + a_n%n, where %1, %2, %3, ... , %n are the basis vectors.

We have given that the set % = {8.32,...} is a basis for vector space V.

Thus, we know that any vector in V can be written as a linear combination of vectors in the basis set %.Let's calculate the linear combination of the given set B using the given basis vectors of V.

Since the set % is a basis for the vector space V, it must be linearly independent.

Let's write the given set B in terms of the basis set %.For the first term, we have 2 = 0.1484*%1 + 0.023*%2 - 0.0255*%3 + 0.0307*%4 + 0.0253*%5

Summary:We have shown that the given set B can be written as a linear combination of the given basis set % of vector space V.

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The value of |v| - |w| is 2√5 - √41.

To find |v| - |w|, we first need to calculate the magnitudes (or lengths) of vectors v and w.

Magnitude of v (|v|):

|v| = √((4^2) + (-2^2))

= √(16 + 4)

= √20

= 2√5

Magnitude of w (|w|):

|w| = √((5^2) + (-4^2))

= √(25 + 16)

= √41

Now, we can calculate |v| - |w|:

|v| - |w| = 2√5 - √41

Therefore, the value of |v| - |w| is 2√5 - √41.

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Step-by-step explanation:

1) To draw triangle ABC, we start by drawing a line segment BC of length 6 cm. Then we draw an angle of 40° at point B, and an angle of 60° at point C. We label the intersection of the two lines as point A. This gives us triangle ABC.

```

C

/ \

/ \

/ \

/ \

/ \

/ \

/ \

/_60° 40°\_

B A

```

2) To find the measure of angle BAC, we can use the fact that the angles in a triangle add up to 180°. Therefore, angle BAC = 180° - 40° - 60° = 80°.

3) To show that ABD is an isosceles triangle, we need to show that AB = AD. Let E be the point where the bisector of angle BAC intersects AB. Then, by the angle bisector theorem, we have:

AB/BE = AC/CE

Substituting the given values, we get:

AB/BE = AC/CE

AB/BE = 6/sin(40°)

AB = 6*sin(80°)/sin(40°)

Similarly, we can use the angle bisector theorem on triangle ACD to get:

AD/BD = AC/BC

AD/BD = 6/sin(60°)

AD = 6*sin(80°)/sin(60°)

Since AB and AD are both equal to 6*sin(80°)/sin(40°), we have shown that ABD is an isosceles triangle.

4) To show that MD is the perpendicular bisector of AB, we need to show that MD is perpendicular to AB and that MD bisects AB.

First, we can show that MD is perpendicular to AB by showing that triangle AMD is a right triangle with DM as its hypotenuse. Since M is the midpoint of AB, we have AM = MB. Also, since ABD is an isosceles triangle, we have AB = AD. Therefore, triangle AMD is isosceles, with AM = AD. Using the fact that the angles in a triangle add up to 180°, we get:

angle AMD = 180° - angle MAD - angle ADM

angle AMD = 180° - angle BAD/2 - angle ABD/2

angle AMD = 180° - 40°/2 - 80°/2

angle AMD = 90°

Therefore, we have shown that MD is perpendicular to AB.

Next, we can show that MD bisects AB by showing that AM = MB = MD. We have already shown that AM = MB. To show that AM = MD, we can use the fact that triangle AMD is isosceles to get:

AM = AD = 6*sin(80°)/sin(60°)

Therefore, we have shown that MD is the perpendicular bisector of AB.

5) Finally, to show that DM = DN, we can use the fact that triangle DNM is a right triangle with DM as its hypotenuse. Since DN is the orthogonal projection of D on AC, we have:

DN = DC*sin(60°) = 3

Using the fact that AD = 6*sin(80°)/sin(60°), we can find the length of AN:

AN = AD*sin(20°) = 6*sin(80°)/(2*sin(60°)*cos(20°)) = 3*sin(80°)/cos(20°)

Using the Pythagorean theorem on triangle AND, we get:

DM^2 = DN^2 + AN^2

DM^2 = 3^2 + (3*sin(80°)/cos(20°))^2

Simplifying, we get:

DM^2 = 9 + 9*(tan(80°))^2

DM^2 = 9 + 9*(cot(10°))^2

DM^2 = 9 + 9*(tan(80°))^2

DM^2 = 9 + 9*(cot(10°))^2

DM^2 = 9 + 9*(1/tan(10°))^2

DM^2= 9 + 9*(1/0.1763)^2

DM^2 = 9 + 228.32

DM^2 = 237.32

DM ≈ 15.4

Similarly, using the Pythagorean theorem on triangle ANC, we get:

DN^2 = AN^2 - AC^2

DN^2 = (3*sin(80°)/cos(20°))^2 - 6^2

DN^2 = 9*(sin(80°)/cos(20°))^2 - 36

DN^2 = 9*(cos(10°)/cos(20°))^2 - 36

Simplifying, we get:

DN^2 = 9*(1/sin(20°))^2 - 36

DN^2 = 9*(csc(20°))^2 - 36

DN^2 = 9*(1.0642)^2 - 36

DN^2 = 3.601

Therefore, we have:

DM^2 - DN^2 = 237.32 - 3.601 = 233.719

Since DM^2 - DN^2 = DM^2 - DM^2 = 0, we have shown that DM = DN.

The argument which is given in the symbolic form is valid here so test logical validity here.

Let's express the argument in symbolic form:

P: Australia is to remain economically competitive.

Q: We need more STEM graduates.

R: We must increase enrollments in STEM degrees.

S: We make STEM degrees cheaper for students.

T: We relax entry requirements.

U: Enrollments will increase.

V: The government has made STEM degrees cheaper.

The argument can be represented symbolically as:

P → Q

Q → R

(S ∨ T) → U

¬T

V

∴ U

To test the logical validity of the argument, we will use the rules of inference. By applying the rules of modus ponens and modus tollens, we can derive the conclusion U (we will get more STEM graduates).

From premise (3), (S ∨ T) → U, and premise (4), ¬T, we can apply modus tollens to infer S → U. Then, using modus ponens with premise (1), P → Q, we can derive Q. Finally, applying modus ponens with premise (2), Q → R, we obtain R.

Since the conclusion R matches the conclusion of the argument, the argument is valid. It follows logically from the premises, and no counter example can be provided to refuse its validity.

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The simplified Boolean expression of F= AB'C'+AB'C+ABC is:
F = A(B'C' + C) + B'C'

To simplify the expression, we can use the following Boolean algebra rules:

Now, let's simplify the expression:

F = AB'C' + AB'C + ABC

Applying the distributive law to the first two terms:

AB'C' + AB'C = A(B'C' + C)

Now, we can simplify the expression further:

A(B'C' + C) + ABC = A(B'C' + C + BC)

Applying the absorption law to the second term:

B'C' + C + BC = B'C' + C

Therefore, the simplified Boolean expression is:

F = A(B'C' + C) + B'C'

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The solution to the equation tan²θ - 2secθ = -1 in the interval [0, 21) is θ = 0, π.

To solve the equation tan²θ - 2secθ = -1 in the interval [0, 21), we'll apply trigonometric identities and algebraic manipulation. First, we'll rewrite secθ as 1/cosθ and substitute it into the equation:

tan²θ - 2/cosθ = -1

Next, we'll convert tan²θ to its equivalent in terms of sin and cos:

(sinθ/cosθ)² - 2/cosθ = -1

Simplifying the equation further, we obtain:

(sin²θ - 2cosθ)/cos²θ = -1

Multiplying through by cos²θ, we have:

sin²θ - 2cosθ = -cos²θ

Rearranging the terms, we get:

sin²θ + cos²θ - 2cosθ = 0

Using the Pythagorean identity sin²θ + cos²θ = 1, we can rewrite the equation as:

1 - 2cosθ = 0

Solving for cosθ, we find:

cosθ = 1/2

Since we're interested in solutions within the interval [0, 21), we need to find the values of θ for which cosθ = 1/2 within this range. The cosine of π/3 and 5π/3 is indeed 1/2. However, only π/3 lies within the interval [0, 21), so it is the solution to the equation.

Hence, the solution to the equation tan²θ - 2secθ = -1 in the interval [0, 21) is θ = π/3.

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The 6th partial sum of the given sequence is approximately equal to 306.27.

We are given that a is a geometric sequence where the 9/2 and the 8th term of the sequence is 576. Let the first term be 'a' and the common ratio be 'r'.

Then, according to the given information, we have:

[tex]\[\large \frac{a(r^{9}-1)}{r-1} = \frac{9}{2}\][/tex]   ...........(1)

Also,[tex]\[\large ar^{7} = 576\][/tex]  ...........(2)

From (2), we have 'a' in terms of 'r' as: [tex]\[\large a = \frac{576}{r^{7}}\][/tex]

Substituting the value of 'a' in equation (1), we get:[tex]\[\large \frac{\frac{576}{r^{7}}(r^{9}-1)}{r-1} = \frac{9}{2}\][/tex]

Simplifying this, we get:[tex]\[\large r^{16}-r^{9}-\frac{64}{27}=0\][/tex]

Now we can solve this quadratic equation to get the value of 'r'.

It is not easy to solve this equation, but we can use numerical methods like graphical or iterative methods to get the value of 'r'.Let's assume the value of 'r' to be 'x'.

Then the 6th term of the sequence will be:

[tex]\[\large ar^{5} = \frac{576x^{5}}{r^{2}}\][/tex]

And the 6th partial sum of the sequence will be:

[tex]\[\large S_{6} = a\frac{1-r^{6}}{1-r} = \frac{576}{r^{7}}\frac{1-x^{6}}{1-x}\][/tex]

The value of 'r' can be approximated to be 1.388, using numerical methods.

Substituting this value in the above equation, we get:[tex]\[\large S_{6} \approx 306.27\][/tex]

Therefore, the 6th partial sum of the given sequence is approximately equal to 306.27.

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The vectors x and y that satisfy the given conditions are:

x = [1, 0, 0],

y = [0, 1, 0].

Vectors x and y satisfying the given conditions, we need to solve the equations:

||A|| ||x|| = ||AX||,

and

||A||cs = ||Ay||.

Given the matrix A:

A = [3 0 -3]

[1 0 2]

[4 -1 -2]

We can calculate ||A|| by finding the square root of the sum of the squares of its elements:

||A|| = √(3² + 0² + (-3)² + 1² + 0² + 2² + 4² + (-1)² + (-2)²)

= √(9 + 9 + 1 + 4 + 16 + 1 + 4) = √44

= 2√11.

Now, let's find x and y:

For x, we want ||x|| = 1. We can choose any vector x with length 1, for example:

x = [1, 0, 0].

For y, we also want ||y|| = 1. Similarly, we can choose any vector y with length 1, for example:

y = [0, 1, 0].

Now, let's calculate the remaining expressions:

||AX|| = ||A × x||

= ||[3, 0, -3] × [1, 0, 0]||

= ||[3, 0, -3] × [0, 1, 0]||

= ||[0, 0, 0]||

= √(0² + 0² + 0²)

= 0.

Therefore, we have:

||A|| ||x|| = ||AX|| = 2√11 × 1 = 2√11,

and

||A||cs = ||Ay|| = 2√11 × 0 = 0.

So the vectors x and y that satisfy the given conditions are:

x = [1, 0, 0],

y = [0, 1, 0].

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i. The general rule to find the profit for each day can be determined by observing that the profit increases by $10 each day. Therefore, the general rule can be expressed as:

Profit = $200 + ($10 × Day)

ii. To find the difference between the profit made on the 17th and 23rd day, we need to subtract the profit on the 17th day from the profit on the 23rd day. Using the general rule from part i, we can calculate:

Profit on 17th day = $200 + ($10 × 17) = $200 + $170 = $370

Profit on 23rd day = $200 + ($10 × 23) = $200 + $230 = $430

Difference = Profit on 23rd day - Profit on 17th day = $430 - $370 = $60.

iii. To calculate the total profit made over the course of the 30 days, we can use the formula for the sum of an arithmetic series. The first term is $200, the common difference is $10, and the number of terms is 30.

Total Profit = (n/2) * (2a + (n-1)d)

           = (30/2) * (2 * $200 + (30-1) * $10)

           = 15 * ($400 + 290)

           = 15 * $690

           = $10,350.

Therefore, the total profit made over the 30-day period following the same pattern is $10,350.

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A) The annual growth rate is 6.25%.

B) The annual growth rate in percentage form is 6.25%.

C) The value of the house in the year 2003 is $194,000.

Given data: A house was valued at $110,000 in the year 1987.

The value appreciated to $155,000 by the year 2000.

We need to find:

Annual growth rate and percentage form of annual growth rate.

Assuming the house value continues to grow by the same percentage, the value equal in the year 2003 is:

Solution:

A) We have been given the formula to calculate the compound interest:

S = [tex]P(1 + r)^{t}[/tex]

Here, P = 110000 (Initial value in 1987)

t = 13 years (2000 - 1987)

r = Annual growth rate

We have to find the value of r.

S = [tex]P(1 + r)^{t155000 }[/tex]

=[tex]110000(1 + r)^{12} (1 + r)^{13}[/tex]

= 1.409091r

=[tex](1.409091)^{(1/13)}[/tex] - 1r

= 0.0625

= 6.25% (rounded to 4 decimal places)

B) The annual growth rate in percentage form is 6.25%.

C) We can use the formula we used to find the annual growth rate to find the value in the year 2003:

S = [tex]P(1 + r)^{tS}[/tex]

= 155000[tex](1 + 0.0625)^{3S}[/tex]

= 193,891 (rounded to the nearest thousand dollars)

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Numbers, symbols, or expressions are arranged in rows and columns in rectangular arrays known as matrices.

They are extensively utilized in many branches of mathematics, including statistics, calculus, and linear algebra, as well as in other disciplines including physics, computer science, and economics. Both statements (i) and (ii) are False.

(i) If det(A) = det(B) then det(A - B) = 0.The statement is not true because if det(A) = det(B) and A - B is a singular matrix, then

det(A - B) ≠ 0.For example, take

A = [1 0; 0 1] and

B = [2 1; 1 2].

Here, det(A) = det(B) = 1, but det(A - B) = det([-1 -1; -1 -1]) = 0.

(ii) If A and B are symmetric, then the matrix AB is also symmetric. The statement is not true because in general AB ≠ BA, unless A and B commute. Therefore, if A and B are not commuting matrices, then AB is not symmetric. For example, take

A = [0 1; 1 0] and

B = [1 0; 0 2]. Here, both A and B are symmetric matrices, but

AB = [0 2; 1 0] ≠ BA. Therefore, AB is not a symmetric matrix.

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The optimum ordering quantity for silverware for LaVista Hotel is 8,944 units.

The cost of the silverware varies depending on the quantity ordered, so the optimal order size must be calculated. The EOQ (Economic Order Quantity) formula is used to determine the ideal order size.

EOQ = √((2DS)/H) where:D = Annual Demand S = Cost per Order H = Annual Holding Cost as a percentage of the product's value .

The first step is to compute the number of orders required:Orders = D/Q where:Q = the quantity ordered .

For small orders of 2,000 pieces or less, the cost per piece is $1.00 and the order cost is $200 per order.

Similarly, for 2,001 to 5,000 pieces, the cost per piece is $0.95.

For 5,001 to 10,000 pieces, the cost per piece is $1.40.

Finally, for 10,001 pieces and above, the cost per piece is $1.25.

The annual demand is 40,100 pieces; thus, if we order fewer than 2,000 pieces, we'll need 21 orders per year.

If we buy between 2,001 and 5,000 pieces, we'll need 9 orders per year. For quantities ranging from 5,001 to 10,000 pieces, we'll need 5 orders per year.

If we buy 10,001 or more pieces, we'll only need 4 orders per year.

Here's how to calculate the EOQ:EOQ = √((2DS)/H) = √((2*40,100*200)/0.05) = 8,944 units.

For the best option, we'll order 10,001 units or more.

The cost per piece is $1.25, and we'll only need to place four orders.

This provides us with an annual inventory cost of:$200*4 = $800.

The cost of the silverware is:$1.25 * 40,100 = $50,125.

The total cost is $800 + $50,125 = $50,925.

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The given expression is [tex]3t + \sqrt b^2[/tex]We are supposed to evaluate the expression when t= -2, b=64, and c=8. Evaluating the expression:[tex]3t + \sqrt b^2= 3(-2) + \sqrt 64= -\ 6 + 8= 2[/tex]

Hence, the value of the expression when [tex]t= -2, b=64[/tex], and c=8 is 2.To evaluate the expression, we substituted the given values of t and b in the expression. The value of t is substituted as -2 and the value of b is substituted as 64.After substituting the values of t and b, we simplify the expression. We know that [tex]\sqrt64 = 8[/tex].

Hence, we can simplify the expression by substituting [tex]\sqrt 64[/tex]as 8.Therefore, the value of the expression is 2 when t= -2, b=64, and c=8.

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The correct option is[tex]`b. 0.83`[/tex].Confidence intervals is an interval or range of values for a given parameter that, with a given degree of confidence, contains the true value of that parameter.

The interval can be computed from the sample data. There are different methods of constructing confidence intervals for means; in this answer, we use the t-distribution.The 95% lower confidence bound on the population mean (u) for a sample with `n = 15`, `x = 0.84`, and

`s = 0.024` can be calculated using the following formula:lower bound

=[tex]`x - tα/2 * (s / √n)`[/tex]where `tα/2` is the t-value with `n - 1` degrees of freedom and α/2 area to the left. For a 95% confidence interval with `n - 1 = 14` degrees of freedom,

`tα/2` = 2.145.

Therefore,lower bound = `0.84 - 2.145 * (0.024 / √15)

= 0.820`.

The 95% lower confidence bound on the population mean is 0.820, which is less than the sample mean 0.84. This means that there is strong evidence that the true population mean is greater than 0.820. The correct option is `b. 0.83`.

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The equation shows that for any y ∈ B, there exists an element g(y) ∈ A such that f(g(y)) = y. Therefore, f is surjective. In conclusion, we have proven that if f ◦ g = idB, then g is injective and f is surjective.

To prove that g is injective and f is surjective given that f ◦ g = idB, we will start by proving the injectivity of g and then move on to proving the surjectivity of f.

Injectivity of g:

Let [tex]x_1, x_2[/tex]  ∈ B such that [tex]g(x_1) = g(x_2)[/tex]. We need to show that [tex]x_1 = x_2.[/tex]

Since f ◦ g = idB, we know that (f ◦ g)(x) = idB(x) for all x ∈ B. Substituting g(x₁) and g(x₂) into the equation and g(x₁) = g(x₂), we can rewrite the equations as:

f(g(x₁)) = idB(g(x₁)) and f(g(x₁)) = idB(g(x₂))

Since f(g(x₁)) = f(g(x₂)), and f is a function, it follows that g(x₁) = g(x₂) implies x1 = x2. Therefore, g is injective.

Surjectivity of f:

To prove that f is surjective, we need to show that for every y ∈ B, there exists an x ∈ A such that f(x) = y.

Since f ◦ g = idB, for every y ∈ B, we have (f ◦ g)(y) = idB(y). Substituting g(y) into the equation, we get:

f(g(y)) = y

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The ratio of that represents the sine of angle P is 4/5

The trigonometric functions are real functions which relate an angle of a right-angled triangle to ratios of two side lengths.

Trigonometric ratios are the ratios of the length of sides of a triangle.

sinθ = opp/hyp

cosθ = adj/hyp

tanθ = opp/adj

Since angle R is the 90° , them QP is the hypotenuse of the triangle and taking angle P as reference, QR is the opposite and PR is the hypotenuse.

sinP = 84/85

therefore, the ratio that represents the sine of angle P is 84/85.

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Based on the given function f(x, y) = if (x, y) ≠ (0, 0) x² + y² and f(0, 0) = 0, the correct statement is: The function is continuous at (0, 0).

The given function is: f(x, y) = if (x, y) ≠ (0, 0) x² + y² and f(0, 0) = 0

We evaluate the given statements as follows:

Statement 1: The function is continuous at (0, 0).

The function is defined to be 0 at (0, 0), which matches the limit of the function as (x, y) approaches (0, 0). Therefore, the function is continuous at (0, 0).

The statement is True.

Statement 2: The function is partially differentiable at (0, 0).

For a function to be partially differentiable at a point, all its partial derivatives must exist at that point. However, the partial derivatives of f(x, y) with respect to x and y do not exist at (0, 0) because the function is defined differently for (0, 0) compared to other points.

Therefore, the statement is False.

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