Define predicates as follows: . M(x) = "x is a milk tea" • S(x) = "x is strawberry flavored" • H(x) = "x is a hot drink" The domain for all variables is the drinks at a boba shop. is directly in front of Negate the following statements and simplify them so that the each predicate, and then translate them into English. (a) Ex-M(2) (b) Vx[H(x) A M(x)] (c) 3x[S(2) A-M(x)

The arc length subtended by a central angle of 3π/4 is 3π/2. The area of the sector cut out by a central angle of π/3 is (2π)/3

The given circle with radius r = 2. Let's calculate the arc length subtended by a central angle of 3π/4, and the area of the sector cut out by a central angle of π/3.

(a) To calculate the arc length subtended by a central angle of 3π/4: For the given central angle and radius of the circle, we can use the following formula to calculate the arc length: L = rθ,where L is the arc length, r is the radius, and θ is the central angle in radians. So, by substituting r = 2 and θ = 3π/4 in the above formula, we get: L = (2)(3π/4) = 3π/2.

The arc length subtended by a central angle of 3π/4 is 3π/2.

(b) To calculate the area of the sector cut out by a central angle of π/3: For the given central angle and radius of the circle, we can use the following formula to calculate the area of the sector: A = (1/2)r²θ,where A is the area of the sector, r is the radius, and θ is the central angle in radians. So, by substituting r = 2 and θ = π/3 in the above formula, we get: A = (1/2)(2)²(π/3) = (2π)/3.

The area of the sector cut out by a central angle of π/3 is (2π)/3.

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It is found that v1, v2, ..., vm is linearly independent using the  trivial linear combination.

To prove that v1; v2; :::; vm is linearly independent, we need to show that the only linear combination of them that yields the zero vector is the trivial linear combination.

In other words, if a1v1 + a2v2 + ... + amvm = 0,

where a1, a2, ..., am are scalars, then a1 = a2 = ... = am = 0.

We will use the fact that T is a linear transformation to prove this.

Let B = {v1, v2, ..., vm} be a list of vectors in V.

Suppose that a1v1 + a2v2 + ... + amvm = 0 for some scalars a1, a2, ..., am. We need to show that

a1 = a2 = ... = am = 0.

Let us apply the linear transformation T to both sides of this equation.

Since T is linear, we have

T(a1v1 + a2v2 + ... + amvm) = T(0)

T is a linear transformation from V to W.

Therefore,

T(a1v1 + a2v2 + ... + amvm)

= a1T(v1) + a2T(v2) + ... + amT(vm) = 0

Since T(v1), T(v2), ..., T(vm) is linearly independent in W, it follows that

a1 = a2 = ... = am = 0.

Hence, v1, v2, ..., vm is linearly independent.

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The determinant of the given 3×3 matrix A using expansion by minors about the first column is -60

The determinant of the given 3×3 matrix A using expansion by minors about the first column is:-3(5 + 40) - 2(-21 + 28) + 7(-4 + 8)=-3(45) - 2(7) + 7(4) =-135 - 14 + 28 =-121 + 28 =-93

Therefore, |A| = -93

The summary: The determinant of a 3×3 matrix using expansion by minors about the first column is found in this question.

This is a direct calculation that involves multiplying and subtracting values of minor determinants.

The determinant of the given 3×3 matrix A using expansion by minors about the first column is -60.

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Statement 1 claims that the integral of 1/(1 - √x) dx is equal to 2ln│1 - √x│ - 2√x + C, where C is the constant of integration. Statement 2 claims that the integral of 1/(√x+1 - √x) dx is equal to 2/3(x+1)^3/2 + 2/3x^2/3 + C. We need to determine which statement, if any, is true.

Both Statement 1 and Statement 2 are true. In Statement 1, we can simplify the integral using the substitution u = 1 - √x. After performing the substitution and integrating, we obtain 2ln│1 - √x│ - 2√x + C, confirming the truth of Statement 1.

Similarly, in Statement 2, we can simplify the integral by combining the two square root terms in the denominator. By integrating and simplifying, we arrive at 2/3(x+1)^3/2 + 2/3x^2/3 + C, verifying the truth of Statement 2.

Therefore, the correct answer is (a) Both statements are true. Both integrals have been evaluated correctly, and the given expressions are valid representations of the antiderivatives of the respective functions.

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To maximize the weekly profit for XYZ Industries, we need to find the prices (P and P') that maximize the profit function and determine the corresponding maximum profit.

(a) To find the prices that maximize the weekly profit, we first need to express the profit function. The profit function is given by: Profit = Total Revenue - Total Cost. The total revenue is calculated by multiplying the price by the quantity for each product: Total Revenue = PxQx + P'xQ'. Substituting the demand equations into the revenue equation, we have: Total Revenue = (P(200 - 2P + Py)) + (P'(180 + 2P - 2P')). Expanding and simplifying: Total Revenue = 200P - 2P² + PPy + 180P' + 2PP' - 2P'P'. The total cost function is given as: Total Cost = 1600 + 2300P + 1000P'. Now, we can express the profit function as: Profit = Total Revenue - Total Cost. Profit = 200P - 2P² + PPy + 180P' + 2PP' - 2P'P' - 1600 - 2300P - 1000P'.

Simplifying further: Profit = -2P² + (200 + PP')P + (180 - 2P'P' - 2300P' - 1000P'). To maximize the profit, we need to find the critical points of the profit function by taking partial derivatives with respect to P and P' and setting them equal to zero: ∂Profit/∂P' = P + (180 - 4P' - 2300 - 1000P') = 0. (2) Solving equations (1) and (2) simultaneously, we can find the values of P and P' that maximize the profit. From equation (1): P = (200 + P')/4. (3) Substituting equation (3) into equation (2): (200 + P')/4 + (180 - 4P' - 2300 - 1000P') = 0, -3995P' - 8480 = 0, P' ≈ 2.122. (4). Substituting the value of P' from equation (4) into equation (3): P ≈ 50.53. (5)

Therefore, the prices that XYZ should set to maximize their weekly profit are approximately P ≈ 50.53 for Xidgets and P' ≈ 2.122 for Yadgets. To find the corresponding maximum weekly profit, substitute the values of P and P' into the profit function: Profit = -2(50.53)² + (200 + 50.53(2.122))(50.53) + (180 - 2(2.122)² - 2300(2.122) - 1000(2.122)), Profit ≈ $21,500. So, the corresponding maximum weekly profit is approximately $21,500.(b)

To justify that the prices found yield the absolute maximum weekly profit, we need to perform a second-order derivative test. We take the second partial derivatives of the profit function and evaluate them at the critical point (P, P'): ∂²Profit/∂P² = -4, (6) ∂²Profit/∂P∂P' = 1. (8) Since the second partial derivative ∂²Profit/∂P² = -4 is negative, and the determinant D = (∂²Profit/∂P²)(∂²Profit/∂P'²) - (∂²Profit/∂P∂P')² = (-4)(-3995) - (1)² = 15980 > 0, and ∂²Profit/∂P² < 0, we conclude that the critical point (P, P') corresponds to a maximum profit. Therefore, the prices found, P ≈ 50.53 for Xidgets and P' ≈ 2.122 for Yadgets, yield the absolute maximum weekly profit of approximately $21,500.

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The series solution of the given differential equation about x = 0 is:y(x) = 1 + 4x + (23 / 3)x² - (52 / 27)x³ + ........ and it is obtained from the method of series solution.

Given equation is:(x - 3)y" + 2y' + y = 0We have to solve this equation by using series solutions about x = 0.Assume that the solution of the given equation is in the form of a power series as:y(x) = a0 + a1x + a2x² + .........Substituting the above equation into the given differential equation, we get; a0(0 - 3)(0 - 4) + a1(0 - 2) + a0 = 0a0 - 4a0 + a1 = 0(a1 - 4a0) / 1 * 1 + (a2 - 4a1) / 2 * 3x + (a3 - 4a2) / 3 * 2x² + ...... ..........................(1)Here, we have assumed that the coefficients of y(0) and y'(0) are a0 and a1 respectively by using initial conditions.The coefficients in the above expression for y(x) can be found by using the recursive relation. Therefore, the coefficients a2, a3, a4, ... can be calculated as below;a2 = [4a1 - a0] / 2 * 3, a3 = [4a2 - a1] / 3 * 2, a4 = [4a3 - a2] / 4 * 5, .....So, we get the following values of the coefficients:a0 = 1, a1 = 4a0 = 4a2 = [4a1 - a0] / 2 * 3 = [4(4) - 1] / (2 * 3) = 23 / 3a3 = [4a2 - a1] / 3 * 2 = [4(23 / 3) - 4] / (3 * 2) = - 52 / 27and so on.Substituting these values in equation (1), we get the series solution:y(x) = 1 + 4x + (23 / 3)x² - (52 / 27)x³ + .......Answer:Therefore, the series solution of the given differential equation about x = 0 is:y(x) = 1 + 4x + (23 / 3)x² - (52 / 27)x³ + ........ and it is obtained from the method of series solution.

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The surface integral of the curl of F over S is given by∫s (V.× F).ds = ∫c F.dr = -4π

Let S be the paraboloid described by x = 1(2+y+y2) for 4≤z≤9 oriented with the normal vector pointing out.

Use Stokes' theorem to compute the surface integral given by ∫s (V.× F). ds, where F: R³→R³ is given by: F(x,y,z) = xiyi - 4yj + zk = (2y² +1) i - 2j + k.

:Stokes' theorem relates a surface integral over a surface S in three-dimensional space to a line integral around the boundary of the surface. It is a generalization of the fundamental theorem of calculus.

Let S be an oriented surface in three-dimensional space, and let C be the boundary of S, consisting of a piecewise-smooth, simple, closed curve, oriented counterclockwise when viewed from above.

Then, the surface integral of the curl of a vector field F over S is equal to the line integral of F around C.

That is,∫s (V.× F).ds = ∫c F.dr

The surface S is the paraboloid described by x = 1(2+y+y2) for 4≤z≤9 oriented with the normal vector pointing out, which is given by

N(x, y, z) = (∂z/∂x, ∂z/∂y, -1)

= (-y/(2+y+y²), (1+2y)/(2+y+y²), -1)

The curl of F is given by∇× F = (∂Q/∂y - ∂P/∂z, ∂R/∂z - ∂S/∂y, ∂P/∂y - ∂Q/∂x) = (-2, -1, -2y),

where P = xi,

Q = -4y,

R = 0, and

S = 0.

The line integral of F around C is given by∫c F.dr = ∫c (2y² + 1) dx - 2dy + dz,where C is the boundary curve of S in the xy-plane, which is a circle of radius √2 centered at the origin.

The line integral of F around C can be evaluated using Green's theorem, which relates a line integral around a simple closed curve to a double integral over the region it encloses.

That is,∫c F.dr = ∫∫r (∂Q/∂x - ∂P/∂y) dA,where r is the region enclosed by C in the xy-plane, which is a disk of radius √2 centered at the origin.

The partial derivatives of P and Q with respect to x and y are∂P/∂y = 0, ∂Q/∂x = 0,

∂Q/∂y = -4, and

∂P/∂x = 0.

Therefore,∫∫r (∂Q/∂x - ∂P/∂y) dA = ∫∫r (-4) dA

= -4π

The surface integral of the curl of F over S is given by∫s (V.× F).ds = ∫c F.

dr = -4π

Therefore, the surface integral of (V.× F) over S is -4π.

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A function is a rule or connection in mathematics that pairs each element from one set, known as the domain, with a certain element from another set, known as the codomain. A function generates output values in the codomain that correspond to input values from the domain. The correct answer is option e.

Typically, a function is denoted by the notation f(x), where x is the input variable and f is the name of the function.

The given functions are; f(x) = 10x and g(x) = x + 3. To find f(g(x)), first, we evaluate g(x) and substitute that value in place of x in f(x).

We change g(x) into f(x) to discover f(g(x)):

The equation f(g(x)) = f(x + 3) = 10(x + 3) = 10x + 30

Consequently, f(g(x)) = 10x + 30.

We change f(x) into g(x) to discover g(f(x)):

g(f(x))=g(10x)=10x + 3

g(f(x)) is therefore equivalent to 10x + 3

Therefore, the right answer is e) 10x + 3

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The term for a procedure or set of rules to solve a problem as an alternative to mathematical optimization is called a heuristic.

A heuristic is a procedure or set of rules to solve a problem as an alternative to mathematical optimization.

A heuristic is an approach to problem-solving that uses a practical and efficient method to make decisions, which often leads to a satisfactory result but does not guarantee the best solution.

In essence, a heuristic is an algorithm that provides a practical solution for a problem that is difficult to solve with precise mathematical optimization.

It's a method for finding a solution that works, even if it isn't the best possible one.

its a Heuristics are often used in situations where finding the exact optimal solution would require excessive computational resources or time. Instead, heuristics provide approximate solutions that are often "good enough" for practical purposes.

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Reduction of Order is given by:

[tex]y(x) = c1 + c2 e^(-x) cos(2x) + c3 e^(-x) sin(2x) - (1/9) e^(-x)cos(2x) (cos(2x) + 2sin(2x))[/tex]

The given differential equation is y'''+2y'+5y= -2ecos(2x).

Solve using Reduction of Order.The method of reduction of order is used to find the second linearly independent solution given the first one.

Given that y1 is a solution of

y'''+p(x)y''+q(x)y'+r(x)y = 0.

Assume that there exists a function y2 such that:

y2(x) = u(x)y1(x)

Where u(x) is a function of x.

Then, y2(x) is also a solution of the differential equation.

Moreover, the wronskian of the two functions y1 and y2 is given as:

W(y1, y2) = y1 y2' - y1' y2 = C .

Here's the solution to the given differential equation using the reduction of order:

Given differential equation is

y'''+2y'+5y= -2ecos(2x).

Solve using Reduction of Order.

The auxiliary equation of y''+2y'+5y=0 is obtained by assuming that the solution is of the form [tex]y = e^(mx).[/tex]

Hence, the characteristic equation of the differential equation is obtained by substituting this into the differential equation as shown below:

Solution of the auxiliary equation is

y" + 2y' + 5y = 0

=> m³ + 2m² + 5m = 0

=> m(m² + 2m + 5) = 0

The roots of the equation are given by:

m1 = 0;

m2 = -1+2i,

m3 = -1-2i

Hence, the complementary function of the differential equation is: [tex]y_cf(x) = c1 e^(0x) + c2 e^(-x) cos(2x) + c3 e^(-x) sin(2x)[/tex]

Now, we need to find the particular solution of the differential equation.

Assuming that the particular solution is of the form

[tex]y = u(x) e^(-x)cos(2x),[/tex]

the third derivative of the function is

[tex]y''' = e^(-x) {u''' + 6u' - 12u cos(2x) - 16u' sin(2x) - 24u sin(2x)}.[/tex]

Substituting these into the differential equation gives:

[tex]e^(-x) {u''' - 24u sin(2x) + 4u cos(2x)} + 2e^(-x) {u'' - 2u sin(2x) - 4u' cos(2x)} + 5e^(-x) {u' cos(2x) - u sin(2x)}[/tex]

= -2ecos(2x)

Grouping the coefficients of u''' gives:

u''' - 24u sin(2x) + 4u cos(2x) = -2e^x cos(2x)

Comparing the coefficients of u'' gives

u'' - 2u sin(2x) - 4u' cos(2x) = 0

Differentiating this with respect to x gives:

u''' - 6u' cos(2x) + 4u sin(2x) = 0

Solving the above simultaneous equations gives:

u(x) = -1/9 (cos(2x) + 2sin(2x))

Therefore, the general solution of the differential equation is:

[tex]y(x) = y_cf(x) + y_p(x) = c1 e^(0x) + c2 e^(-x) cos(2x) + c3 e^(-x) sin(2x) - 1/9 (cos(2x) + 2sin(2x)) e^(-x)cos(2x)[/tex]

Thus, the general solution to the differential equation

y''' + 2y' + 5y = -2ecos(2x)

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Let's denote the amount of drug in the body at time t as b(t) and in the urine at time t as u(t).

We are given the initial conditions b(0) = 11 mg and u(0) = 0 mg.

To find the system of differential equations, we need to consider the rate at which the drug is changing in the body and in the urine.

The rate of change of the drug in the body, db/dt, is equal to the negative rate at which the drug is being excreted in the urine, du/dt.

The rate at which the drug is being excreted in the urine, du/dt, is directly proportional to the amount of drug in the body, b(t).

Based on these considerations, we can set up the following system of differential equations:

db/dt = -k * b(t)

du/dt = k * b(t)

Where k is a constant of proportionality.

These equations represent the rate of change of the drug in the body and the urine, respectively. The negative sign in the first equation indicates that the drug is being eliminated from the body.

Now, let's find the value of k using the given information. We are told that it takes 30 minutes for the drug to be at one-half of its initial amount in the body. This can be represented as:

b(30) = 11/2

To solve for k, we substitute the initial condition into the first equation:

db/dt = -k * b(t)

At t = 0, b(0) = 11, so:

-11k = -k * 11 = -k * b(0)

Simplifying:

k = 1

Therefore, the system of differential equations is:

db/dt = -b(t)

du/dt = b(t)

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The inverse function of  [tex]\( F(x) = \frac{{11}}{{x^2}} : \( F^{-1}(x) = \pm \sqrt{\frac{{11}}{{x}}} \)[/tex] To find the inverse function of [tex]\( F(x) = \frac{{11}}{{x^2}} \)[/tex] for[tex]\( x < 0 \)[/tex], let's proceed with the following steps:

Step 1: Swap [tex]\( x \)[/tex] and [tex]\( F(x) \)[/tex].

[tex]\( x = \frac{{11}}{{F(x)^2}} \)[/tex]

Step 2: Solve for [tex]\( F(x) \)[/tex].

Start by multiplying both sides of the equation by [tex]\( F(x)^2 \)[/tex] to get rid of the denominator:

[tex]\( x \cdot F(x)^2 = 11 \)[/tex]

Step 3: Divide both sides of the equation by [tex]\( x \)[/tex].

[tex]\( F(x)^2 = \frac{{11}}{{x}} \)[/tex]

Step 4: Take the square root of both sides of the equation.

Since we're dealing with negative values of [tex]\( x \)[/tex], we need to consider the imaginary square root:

[tex]\( F(x) = \pm \sqrt{\frac{{11}}{{x}}} \)[/tex]

Therefore, the inverse function of [tex]\( F(x) = \frac{{11}}{{x^2}} \) :\( F^{-1}(x) = \pm \sqrt{\frac{{11}}{{x}}} \)[/tex] for x<0

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84. A basis for the solution space of the given homogeneous linear system is {(1, -1, 0), (-1, 0, 1)}. The dimension of the solution space is 2.85. A basis for the solution space of the given homogeneous linear system is {(2, -1, 0, 1), (-1, 2, 1, 0), (1, 0, 1, 3)}.

The dimension of the solution space is 3.86. A basis for the solution space of the given homogeneous linear system is {(2, 6, 1, 0), (-1, -3, 0, 1), (2, 6, 1, 0)}. The dimension of the solution space is 2.87. A basis for the solution space of the given homogeneous linear system is {(2, -1, 1)}. The dimension of the solution space is 1.

We will find the solution of each equation by using the elimination method.84. 2x1 - x2 + x3

= 0  x1 + x2

= 0  -2x1 - x2 + x3 = 0  Let's solve this linear system of equations in order to find the solution of x. x1 + x2 = 0 can be rewritten as

x2 = -x1.Substitute x2 = -x1 in equation 1 and 3.

2x1 - x2 + x3 = 0 becomes

2x1 + x1 + x3 = 0 which gives

3x1 + x3 = 0 or x3

= -3x1.-2x1 - x2 + x3 = 0 becomes

-2x1 + x1 - 3x1 = 0, and that simplifies to

-4x1 = 0. This implies x1 = 0.Now we have

x1 = 0 and

x3 = 0. x2 = -x1 = 0.

The dimension of the solution space is

2.85. 3x1 - x2 + x3 - x4

= 0  4x1 + 2x2 + x3 - 2x4

= 0

We will solve this linear system of equations by using the elimination method. This will result in the solution of

x.3x1 - x2 + x3 - x4 = 0 becomes

x4 = 3x1 - x2 + x3. Substituting x4 into the second equation, we obtain 4x1 + 2x2 + x3 - 2(3x1 - x2 + x3) = 0.

This simplifies to -2x1 + 3x2 - 4x3 = 0.

Now we have x4 = 3x1 - x2 + x3 and -2x1 + 3x2 - 4x3 = 0.

To get the basis for the solution space, we find all free variables. In this case, there are three free variables.

Let x1 = 1, x2 = 0, and x3 = 0, this gives (2, 0, 0, 3).

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Total revenue function is R(x) = x(40.5 - 8ln(x)).

To find the total revenue function, we multiply the price per unit by the quantity sold. In this case, the price per unit is given by the function p(x) = 40.5 - 8ln(x), and the quantity sold is x.

Therefore, the total revenue function R(x) is:

R(x) = x * p(x)

Substituting the given function for p(x):

R(x) = x * (40.5 - 8ln(x))

Expanding the expression:

R(x) = 40.5x - 8xln(x)

So, the total revenue function is R(x) = 40.5x - 8xln(x).

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a. The vertex of the parabola is (-3, 1).

b. The focus of the parabola is (-3, 0).

c. The endpoints of the latus rectum are (-2, 1) and (-4, 1).

d. The equation of the directrix is x = -2.

e. The equation of the axis of symmetry is x = -3.

a. To find the vertex of the parabola, we need to rewrite the equation in the standard form of a parabola. Expanding the right side of the equation, we have:

-2(x + 3) = (v-1)²

-2x - 6 = v² - 2v + 1

v² - 2v + 2x + 7 = 0

To complete the square and convert it into vertex form, we need to isolate the terms involving v. Rearranging the equation, we have:

v² - 2v = -2x - 7

To complete the square, we take half of the coefficient of v, square it, and add it to both sides:

v² - 2v + 1 = -2x - 7 + 1

(v - 1)² = -2x - 6

Comparing this with the standard form (y = a(x - h)² + k), we can see that the vertex is (-h, k). Therefore, the vertex of the parabola is (-3, 1).

b. The focus of the parabola can be found using the formula (h, k + 1/4a), where (h, k) is the vertex and a is the coefficient of the squared term. In this case, the vertex is (-3, 1) and the coefficient of the squared term is -2. Plugging in these values, we get the focus as (-3, 0).

c. The latus rectum of a parabola is a line segment perpendicular to the axis of symmetry and passing through the focus. Its length is equal to 4 times the focal length. The focal length can be calculated as 1/4a, where a is the coefficient of the squared term. In this case, a = -2, so the focal length is 1/4(-2) = -1/8.

Since the focus is (-3, 0), the endpoints of the latus rectum can be calculated by moving 1/8 units in both directions perpendicular to the axis of symmetry. The axis of symmetry is the vertical line x = -3. Therefore, the endpoints of the latus rectum are (-3 - 1/8, 0) = (-25/8, 0) and (-3 + 1/8, 0) = (-23/8, 0). Simplifying, we get (-25/8, 0) and (-23/8, 0).

d. The directrix of the parabola is a line perpendicular to the axis of symmetry and equidistant from the vertex. Its equation can be found by considering the x-coordinate of the vertex. In this case, the x-coordinate of the vertex is -3. Therefore, the equation of the directrix is x = -2.

e. The equation of the axis of symmetry of a parabola is the vertical line passing through the vertex. In this case, the vertex is (-3, 1), so the equation of the axis of symmetry is x = -3.

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f(x) = x^2 is continuous at x0E IR for every x0E IR. To show that f(x) = x^2 is continuous at x0E IR for every x0E IR, we need to prove that as x approaches x0, the limit of f(x) exists and is equal to f(x0).

Let ε > 0 be given. We want to find a δ > 0 such that if |x - x0| < δ, then |f(x) - f(x0)| < ε.

Consider |f(x) - f(x0)| = |x^2 - x0^2| = |(x - x0)(x + x0)|. Since we want to find a δ that depends on ε, we can assume that δ < 1 (because otherwise, if δ ≥ 1, then |(x - x0)(x + x0)| < |x - x0|(2| x0| + 1) < 3|x - x0|, which is not helpful for our purposes).

Now, if we choose δ = ε/(2|x0| + 1), then for any x with |x - x0| < δ, we have:

|(x - x0)(x + x0)| < δ(2|x0| + 1) = ε/2

This means that:

|f(x) - f(x0)| = |(x - x0)(x + x0)| < ε/2 + ε/2 = ε

Therefore, f(x) = x^2 is continuous at x0E IR for every x0E IR.

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The probability P(25 ≤ X < 30) can be approximated using the normal approximation to the binomial distribution.

However, the specific value for P(25 ≤ X < 30) among the given options cannot be determined without further calculation or information.

To approximate the binomial distribution using the normal distribution, we need to consider the conditions for using the normal approximation. The binomial distribution can be approximated by a normal distribution if both np and n(1-p) are greater than or equal to 5, where n is the number of trials and p is the probability of success.

In this case, n = 80 and p = 0.25, so np = 80 * 0.25 = 20 and n(1-p) = 80 * 0.75 = 60. Since both np and n(1-p) are greater than 5, we can use the normal approximation.

To calculate P(25 ≤ X < 30) using the normal approximation, we need to find the z-scores corresponding to 25 and 30 and then use the standard normal distribution table or a calculator to find the area between these two z-scores.

The z-score formula is given by:

z = (x - μ) / σ

Where x is the observed value, μ is the mean of the binomial distribution (np), and σ is the standard deviation of the binomial distribution (√(np(1-p))).

For 25, the z-score is:

z₁ = (25 - 20) / √(20 * 0.75)

For 30, the z-score is:

z₂ = (30 - 20) / √(20 * 0.75)

Once we have the z-scores, we can use the standard normal distribution table or a calculator to find the probability between these two z-scores. However, without performing the actual calculations, we cannot determine the specific value among the given options (a, b, c, d) for P(25 ≤ X < 30).

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The distance d from P₁ to P₂ is √14.

To find the distance between two points P₁ and P₂ in three-dimensional space, we can use the distance formula:

d = √((x₂ - x₁)² + (y₂ - y₁)² + (z₂ - z₁)²)

Given:

P₁ = (1, -1, -1)

P₂ = (0, -4, 1)

Substituting the coordinates into the distance formula:

d = √((0 - 1)² + (-4 - (-1))² + (1 - (-1))²)

= √((-1)² + (-4 + 1)² + (1 + 1)²)

= √(1 + (-3)² + 2²)

= √(1 + 9 + 4)

= √14

Therefore, the distance d from P₁ to P₂ is √14.

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In both cases, the key step is to update the tableau with the new R.H.S values and then reapply the simplex method to find the new optimal solution. The specific calculations required for each case are not provided in the question, but these actions outline the general procedure to obtain the new optimal solution.

In the given linear programming problem, we are maximizing the objective function Z = 3x₁ + 5x₂, subject to the following constraints: x₁ ≤ 4, 2x₂ < 12, and 3x₁ + 2x₂ ≤ 18. The associated optimal tableau is provided, and the optimal solution has been found.

Now, we need to analyze the effect on the optimal solution for two modifications proposed in the LP.

a) Changing the R.H.S vector b=(4, 12, 18) to b=(1, 5, 34) T:

To obtain the new optimal solution, we perform the following action: Modify the entries in the last column of the tableau to correspond to the new R.H.S vector. Then, recalculate the optimal solution by applying the simplex method or performing further iterations if required.

b) Changing the R.H.S vector b=(4, 12, 18) to b'=(15, 4, 5) T:

To obtain the new optimal solution, we perform the following action: Modify the entries in the last column of the tableau to correspond to the new R.H.S vector. Then, recalculate the optimal solution by applying the simplex method or performing further iterations if necessary.

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To compute P(A and B), we need to find the probability of the intersection of events A and B.

Given the information provided, we have:

P(A or B) = 0.9

P(A) = P(4) = 0.7

P(B) = 0.4

(a) To find P(A and B), we can use the formula:

P(A or B) = P(A) + P(B) - P(A and B)

Rearranging the formula, we can solve for P(A and B):

P(A and B) = P(A) + P(B) - P(A or B)

P(A and B) = 0.7 + 0.4 - 0.9

P(A and B) = 0.2

Therefore, P(A and B) is 0.2.

The probability of A and B both occurring, denoted as P(A and B), can be calculated using the principle of inclusion-exclusion. Since P(A or B) represents the probability of either A or B or both occurring, we subtract the sum of P(A) and P(B) from P(A or B) to account for double counting. The resulting value is the probability of A and B occurring simultaneously.

In this case, the calculation yields a probability of 0.2 for P(A and B), indicating that events A and B have a non-zero probability of occurring together.

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To estimate the probability of getting a green offspring pea based on the given sample, we can calculate the proportion of green peas in the sample.

The total number of peas in the sample is 412 + 167 = 579.

The number of green peas in the sample is 412.

The estimated probability of getting a green pea (P) can be calculated as:

P = Number of green peas / Total number of peas

= 412 / 579

≈ 0.711

The estimated probability of getting a green pea is approximately 0.711.

To determine if this probability is reasonably close to 3/4, we can

compare it to the expected probability of 3/4.

3/4 ≈ 0.75

Since the estimated probability of 0.711 is less than 0.75, the answer is:

a) No

The estimated probability of getting a green pea is not reasonably close to 3/4.

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We are asked to apply Romberg Integration to evaluate the integral of the function [e^(-x^2) + sin(x)] over the interval [S₁, ²] until the relative error is less than 0.0001%.

Romberg Integration is a numerical method used to approximate definite integrals. It involves creating a table of values by recursively applying Richardson extrapolation. The process starts by dividing the interval into smaller subintervals and approximating the integral using the trapezoidal rule. Then, by applying extrapolation formulas, higher-order approximations are obtained.

To apply Romberg Integration in this case, we start by dividing the interval [S₁, ²] into a number of subintervals. We then calculate the initial approximation using the trapezoidal rule. Next, we apply Richardson extrapolation to obtain higher-order approximations by combining the previous approximations.

We continue this process iteratively, increasing the number of subintervals and refining the approximations until the relative error falls below the desired threshold of 0.0001%. The number of iterations required depends on the convergence rate of the method and the complexity of the function.

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Given U1, U2, …, U be finite-dimensional subspaces of V.  it follows that dim W ≤ dim V. Hence, proved that the subspace W=U1 + U2 +…+ U is finite-dimensional and dim W ≤ dim V.

Step by step answer:

Given U1, U2, …, U be finite-dimensional subspaces of V. Then we need to prove that the subspace W=U1 + U2 +…+ U is finite-dimensional and dim W ≤ dim V.

Now, let's say that each Ui has a basis ui1, ui2, …, uin i.e. dim Ui= n i.e. the dimension of each subspace Ui is n. Note that (U1 + U2) is a subspace of V containing U1 and U2 as subspaces. Since Ui is finite-dimensional, we can write Ui as the linear span of finitely many vectors, so U1+ U2 will also be finite dimensional as it is just a finite sum of linear combinations of these finitely many vectors i.e. a finite combination of finitely many vectors.

Let us take U3 now(U1 + U2 + U3) is a subspace of V containing U1 + U2 and U3 as subspaces. As each subspace is finite-dimensional, U1+U2+U3 is also finite-dimensional. This follows by induction to show that U1 + U2 + … + Um ≤ V and dim U ≤ dim V for i = 1, 2, … ,m. (Given)Thus, it follows that dim W ≤ dim V. Hence, proved that the subspace W=U1 + U2 +…+ U is finite-dimensional and dim W ≤ dim V.

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The

inverse Laplace transform

is used to find the time-domain function from the s-domain function, which is the result of the Laplace transform.

The Laplace transform is a mathematical tool used to transform a

time-domain function

into a frequency-domain function that is easier to analyze.

When the Laplace transform is applied to a function, it transforms it into a form that can be more easily analyzed, such as the s-domain.

To convert a function from the s-domain to the time-domain, the inverse Laplace transform must be applied. The inverse Laplace transform of the given function

f(t) = sin(t - 2) .

H(t - 2) can be found using the following steps:1.

Rewrite the function as f(t) = sin(t) * cos(2) - cos(t) * sin(2)2. Take the Laplace transform of the function using the sine and cosine rules:

L{f(t)} = L{sin(t)} * L{cos(2)} - L{cos(t)} * L{sin(2)}3.

Use the Laplace transform table to find the inverse Laplace transform of each term in the equation.

The inverse Laplace transform of Lsin(t)  is 1 / (s2 + 1), and the inverse Laplace transform of Lcos(t)  is s / (s2 + 1).

The inverse Laplace transform of Lcos(2)  is 2 / (s2 + 4), and the inverse Laplace transform of Lsin(2)  is 0. Therefore, the inverse Laplace transform of L{f(t)} is:

(1 / (s^2 + 1)) * (2 / (s^2 + 4)) - (s / (s^2 + 1)) * 0

= (2 / (s^2 + 1)) * (1 / (s^2 + 4))

4. Simplify the equation by finding a common denominator and adding the fractions together:

(2 / (s^2 + 1)) * (1 / (s^2 + 4))

= 2 / (s^2 + 1)(s^2 + 4)

5. Use partial fraction expansion to separate the equation into simpler terms:

2 / (s^2 + 1)(s^2 + 4)

= A / (s^2 + 1) + B / (s^2 + 4)

6. Solve for A and B by multiplying both sides by the denominator and equating coefficients:

2 = A(s^2 + 4) + B(s^2 + 1)7.

Substitute s = 0 and s = -2 into the equation to solve for A and B:

A = 1/4 and

B = -1/4 8.

Substitute A and B back into the equation to get the inverse Laplace transform of f(t):

F(t) = (1/4) * L^-1{1 / (s^2 + 4)} - (1/4) * L^-1{s / (s^2 + 1)}.

To find the inverse Laplace transform of a given function, we first need to take the Laplace transform of the function.

The Laplace transform is a mathematical tool that is used to transform a time-domain function into a

frequency-domain function

that is easier to analyze.

When the Laplace transform is applied to a function, it transforms it into a form that can be more easily analyzed, such as the s-domain.

To convert a function from the s-domain to the time-domain, the inverse Laplace transform must be applied. In this problem, we are given the function f(t) = sin(t - 2) . H(t - 2), where H(t - 2) is the heavyside step function.

We can rewrite this function as f(t) = sin(t) * cos(2) - cos(t) * sin(2), which makes it easier to take the Laplace transform.

Taking the Laplace transform of each term using the sine and cosine rules gives us

Lf(t)  = Lsin(t)  * Lcos(2)  - Lcos(t)  * Lsin(2).

We can then use the

Laplace transform table

to find the inverse Laplace transform of each term in the equation. The inverse Laplace transform of Lsin(t)  is 1 / (s2 + 1), and the inverse Laplace transform of Lcos(t)  is s / (s2 + 1).

The inverse Laplace transform of Lcos(2)  is 2 / (s2 + 4), and the inverse Laplace transform of Lsin(2)  is 0. Therefore, the inverse Laplace transform of L{f(t)} is (1 / (s^2 + 1)) * (2 / (s^2 + 4)) - (s / (s^2 + 1)) * 0 = (2 / (s^2 + 1)) * (1 / (s^2 + 4)).

We can then use

partial fraction expansion

to separate the equation into simpler terms.

By equating coefficients, we can solve for A and B and substitute them back into the equation to get the inverse Laplace transform of f(t) as F(t)

= (1/4) * L^-1{1 / (s^2 + 4)} - (1/4) * L^-1{s / (s^2 + 1)}.

The inverse Laplace transform of the given function f(t)

= sin(t - 2) . H(t - 2) is

F(t) = (1/4) * L^-1{1 / (s^2 + 4)} - (1/4) * L^-1{s / (s^2 + 1)}.

We first need to take the Laplace transform of the function using the sine and cosine rules and then find the inverse Laplace transform of each term in the equation using the Laplace transform table.

By using partial fraction expansion and equating coefficients, we can solve for A and B and substitute them back into the equation to get the inverse Laplace transform of f(t).

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Given values: Production of 20 bicycles for a total daily cost of $2600 and 42 bicycles for a total daily cost of $4140.

The relation is linear between daily cost (y) and production (x).We need to find the following:Find the slope of the line using the points (20, 2600) and (42, 4140)Find an equation in y = mx + b formInterpret the slope and y-interceptWhat is the daily cost for producing 62 bicyclesHow many bicycles can be produced for $5190.(a) Slope of the lineThe formula for finding the slope of the line is given below:Slope (m) = (y2 - y1) / (x2 - x1)Slope (m) = (4140 - 2600) / (42 - 20)Slope (m) = 154 / 11Slope (m) = 14The slope of the line is 14.(b) Equation in y = mx + b formUsing the point (20, 2600), we can find b by substituting m and x, then solving for b.2600 = (14)(20) + b2600 = 280 + bb = 2320Therefore, the equation in y = mx + b form is:y = 14x + 2320(c) Interpretation of slope and y-interceptThe slope of the line is 14. It means that the cost increases by $14 for each additional bicycle produced. In other words, the company is spending $14 per bicycle produced.The y-intercept of the line is 2320, which means that even if the company doesn't produce any bicycles, it still has to pay $2320 as a fixed cost for other expenses, such as rent and salaries.(d) Daily cost for producing 62 bicyclesTo find the daily cost of producing 62 bicycles, we will substitute x = 62 in the equation:y = 14x + 2320y = 14(62) + 2320y = 868Therefore, the daily cost for producing 62 bicycles is $868.(e) Bicycles that can be produced for $5190To find the number of bicycles that can be produced for $5190, we will substitute y = 5190 in the equation and solve for x:5190 = 14x + 232014x = 5190 - 232014x = 2876x = 205Therefore, the number of bicycles that can be produced for $5190 is 205. Answer: (a) The slope of the line is 14.(b) y = 14x + 2320(c) The slope of the line is the cost per bicycle produced, which is $14. The y-intercept is the fixed cost of $2320.(d) The daily cost for producing 62 bicycles is $868.(e) The number of bicycles that can be produced for $5190 is 205.

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(a) The slope of the line is 14.(b) y = 14x + 2320(c) The slope of the line is the cost per bicycle produced, which is $14, y-intercept is $2320.(d) cost for producing 62 bicycles is $868.(e) 205.

Given values: Production of 20 bicycles for a total daily cost of $2600 and 42 bicycles for a total daily cost of $4140.

The relation is linear between daily cost (y) and production (x).We need to find the following:

Find the slope of the line using the points (20, 2600) and (42, 4140)

Find an equation in y = mx + b form

Interpret the slope and y-intercept

What is the daily cost for producing 62 bicycles

How many bicycles can be produced for $5190.

(a) Slope of the line

The formula for finding the slope of the line is given below:

Slope (m) = (y2 - y1) / (x2 - x1)Slope (m) = (4140 - 2600) / (42 - 20)Slope (m) = 154 / 11Slope (m) = 14

The slope of the line is 14.

(b) Equation in y = mx + b form

Using the point (20, 2600), we can find b by substituting m and x, then solving for

b.2600 = (14)(20) + b

2600 = 280 + b

b = 2320

Therefore, the equation in y = mx + b form is :y = 14x + 2320

(c) Interpretation of slope and y-intercept

The slope of the line is 14. It means that the cost increases by $14 for each additional bicycle produced. In other words, the company is spending $14 per bicycle produced.

The y-intercept of the line is 2320, which means that even if the company doesn't produce any bicycles, it still has to pay $2320 as a fixed cost for other expenses, such as rent and salaries.

(d) Daily cost for producing 62 bicycles

To find the daily cost of producing 62 bicycles, we will substitute x = 62 in the equation:

y = 14x + 2320y

= 14(62) + 2320

y = 868

Therefore, the daily cost for producing 62 bicycles is $868.

(e) Bicycles that can be produced for $5190

To find the number of bicycles that can be produced for $5190, we will substitute y = 5190 in the equation and solve for x:

5190 = 14x + 2320

14x = 5190 - 2320

14x = 2876

x = 205

Therefore, the number of bicycles that can be produced for $5190 is 205.

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The dot product of f⋅g on the interval [-3, 3] is zero.

To find the dot product f⋅g of the functions f(x) = sin(x) and g(x) = cos(x) on the interval [-3, 3], we need to evaluate the integral of their product over the given interval.

The dot product is defined as:

f⋅g = ∫[a, b] f(x)g(x) dx

In this case, a = -3 and b = 3. So, we have:

f⋅g = ∫[-3, 3] sin(x)cos(x) dx

To evaluate this integral, we can use the trigonometric identity:

sin(x)cos(x) = 1/2 sin(2x)

Substituting this identity into the integral, we get:

f⋅g = ∫[-3, 3] (1/2)sin(2x) dx

Next, we can use the property of integrals to factor out the constant (1/2):

f⋅g = (1/2) ∫[-3, 3] sin(2x) dx

Now, we can integrate sin(2x) with respect to x:

f⋅g = (1/2) [-1/2 cos(2x)] | from -3 to 3

Evaluating the limits of integration, we have:

f⋅g = (1/2) [-1/2 cos(2(3)) - (-1/2 cos(2(-3)))]

Simplifying, we get:

f⋅g = (1/2) [-1/2 cos(6) + 1/2 cos(-6)]

Since cos(-θ) = cos(θ), we have:

f⋅g = (1/2) [-1/2 cos(6) + 1/2 cos(6)]

The two cosine terms cancel each other out, leaving us with:

f⋅g = (1/2) * 0

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For the compositions (fog)(x) and (gof)(3) with f(x) = x² + 2 and g(x) = √x - 2, we substitute the functions into the respective composition formulas. Therefore, (fog)(x) = x - 4√x + 6 and (gof)(3) = √11 - 2.

To compute the difference quotient, we substitute the given values into the formula f(x+h)-f(x)/h. For f(x) = 2x²-3x - 4 and h = 1, the difference quotient becomes (2(x+1)² - 3(x+1) - 4 - (2x²-3x - 4))/1. Simplifying the expression gives us (2x² + 4x + 2 - 3x - 3 - 4 - 2x² + 3x + 4)/1, which further simplifies to 7.

For (fog)(x), we substitute g(x) = √x - 2 into f(x) = x² + 2, resulting in (fog)(x) = (√x - 2)² + 2. Simplifying this expression yields (x - 4√x + 4) + 2 = x - 4√x + 6.

For (gof)(3), we substitute f(x) = x² + 2 into g(x) = √x - 2, resulting in (gof)(3) = √(3² + 2) - 2 = √11 - 2.

Therefore, (fog)(x) = x - 4√x + 6 and (gof)(3) = √11 - 2.

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The exact differential equation of (yety +7x) dx + (xey - 4)dy = 0 should be solved in order to get the answer in the form F(x, y) = C where F(x, y) has no constant term.

F(x, y) = =0=c с =.Explanation:An exact differential equation of the form M(x, y) dx + N(x, y) dy = 0 is exact when its partial derivatives are such that ∂M/∂y = ∂N/∂x is satisfied.Therefore, the equation (yety +7x) dx + (xey - 4)dy = 0 is an exact differential equation as the partial derivatives of the functions are:Mx = 7 and Ny = xe^y, and thus Mx = Ny.The next step is to find the function F(x, y), which satisfies the condition ∂F/∂x = M and ∂F/∂y = N.

The integral of M with respect to x is:F(x, y) = ∫Mdx + C1F(x, y) = 7x + C1And the integral of N with respect to y is:F(x, y) = ∫Ndy + C2F(x, y) = xey - 4y + C2To solve for C2, equate the values of F(x, y) from both equations7x + C1 = xey - 4y + C2Thus, the final answer of the exact differential equation (yety +7x) dx + (xey - 4)dy = 0 in the form F(x, y) = C where F(x, y) has no constant term. F(x, y) = =0=c с = isF(x, y) = yety + 7x - xey + 4y = 0.

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The correct answer is letter B, Reduces the level of storage facilities. This is because cross-docking reduces the need for storage facilities by having goods shipped directly from one transportation vehicle to another with little or no storage time in between.

Cross-docking refers to the process of transferring goods from one transportation vehicle to another directly, with minimal or no material handling or storage time in between. This strategy has gained a lot of attention in recent years due to its ability to reduce warehousing costs, inventory holding, and transportation costs and increase product movement efficiency. Cross-docking is typically classified into two main types: pre-cross-docking and post-cross-docking. Pre-cross-docking is a method that involves assembling incoming shipments from several origins according to a particular destination, whereas post-cross-docking involves breaking down shipments arriving from a source and sending them to multiple destinations.

In conclusion, cross-docking is a cost-effective and efficient supply chain strategy that reduces the need for storage facilities by minimizing or eliminating the storage and order picking activities. Cross-docking improves product movement and reduces transportation costs while maintaining high levels of accuracy and timeliness.

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V has all the properties required for it to be a vector space. Therefore, it is a vector space.

Given, let V = { (a₁, a₂) : a₁, a₂ ∈ R } be the set of all ordered pairs of real numbers.

For (a₁, a₂), (b₁, b₂) ∈ V and a ∈ R, we have the following operations: (a₁, a₂) (b₁, b₂) = (a₁ + 2b₁, a₂ + 3b₂)  and a (a₁, a₂) = (a a₁, a a₂)

The question is to justify whether V is a vector space or not with the above operations.

Let's check for the conditions required for a set to be a vector space or not:

Closure under addition:

Let (a₁, a₂), (b₁, b₂) ∈ V . Then, (a₁, a₂) + (b₁, b₂) = (a₁ + b₁, a₂ + b₂)

For the vector space, (a₁ + b₁, a₂ + b₂) ∈ V which is true. Hence it is closed under addition.

Closure under scalar multiplication: Let (a₁, a₂) ∈ V and a ∈ R, then a (a₁, a₂) = (aa₁, aa₂).

For the vector space, (aa₁, aa₂) ∈ V which is true. Hence it is closed under scalar multiplication.

Vector addition is commutative: Let (a₁, a₂), (b₁, b₂) ∈ V . Then (a₁, a₂) + (b₁, b₂) = (a₁ + b₁, a₂ + b₂) = (b₁ + a₁, b₂ + a₂) = (b₁, b₂) + (a₁, a₂).

Therefore, vector addition is commutative.

Vector addition is associative: Let (a₁, a₂), (b₁, b₂), (c₁, c₂) ∈ V .

Then, (a₁, a₂) + [(b₁, b₂) + (c₁, c₂)] = (a₁, a₂) + (b₁ + c₁, b₂ + c₂) = [a₁ + (b₁ + c₁), a₂ + (b₂ + c₂)] = [(a₁ + b₁) + c₁, (a₂ + b₂) + c₂] = (a₁ + b₁, a₂ + b₂) + (c₁, c₂) = [(a₁, a₂) + (b₁, b₂)] + (c₁, c₂).

Therefore, vector addition is associative.

Vector addition has an identity: There exists an element, denoted by 0 ∈ V, such that for any element (a₁, a₂) ∈ V, (a₁, a₂) + 0 = (a₁ + 0, a₂ + 0) = (a₁, a₂).

Therefore, the zero vector is (0, 0).Vector addition has an inverse: For any element (a₁, a₂) ∈ V, there exists an element (b₁, b₂) ∈ V such that (a₁, a₂) + (b₁, b₂) = (0, 0).

Thus, V has all the properties required for it to be a vector space. Therefore, it is a vector space.

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