The expression for linear approximation is:
[tex]L(4.27, 8.14) \sim 10 + 0.14 * 51c(2^{75})[/tex]
What is function?A relation between a collection of inputs and outputs is known as a function. A function is, to put it simply, a relationship between inputs in which each input is connected to precisely one output.
To find the linear approximation to the function [tex]f(x, y) = cy^{51}[/tex] at the point (4, 8, 10), we need to compute the partial derivatives of f with respect to x and y and evaluate them at the given point. Then we can use the linear approximation formula:
[tex]L(x, y) \sim f(a, b) + f_x(a, b)(x - a) + f_y(a, b)(y - b)[/tex],
where (a, b) is the point of approximation.
First, let's compute the partial derivatives of f(x, y) with respect to x and y:
[tex]f_x(x, y) = 0[/tex] (since the derivative of a constant with respect to x is 0)
[tex]f_y(x, y) = 51cy^{50[/tex]
Now, we can evaluate the partial derivatives at the point (4, 8, 10):
[tex]f_x(4, 8) = 0[/tex]
[tex]f_y(4, 8) = 51c(8)^{50} = 51c(2^3)^{50} = 51c(2^{150}) = 51c(2^{75})[/tex]
The linear approximation becomes:
L(x, y) ≈ [tex]f(4, 8) + f_x(4, 8)(x - 4) + f_y(4, 8)(y - 8)[/tex]
≈ [tex]10 + 0(x - 4) + 51c(2^{75})(y - 8)[/tex]
≈ [tex]10 + 51c(2^{75})(y - 8)[/tex]
To approximate f(4.27, 8.14), we substitute x = 4.27 and y = 8.14 into the linear approximation:
[tex]L(4.27, 8.14) \sim 10 + 51c(2^{75})(8.14 - 8)[/tex]
≈ [tex]10 + 51c(2^{75})(0.14)[/tex]
We don't have the specific value of c, so we can't compute the exact approximation. However, we can leave the expression as:
[tex]L(4.27, 8.14) \sim 10 + 0.14 * 51c(2^{75})[/tex]
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Determine an interval for the sum of the alternating series Σ(-1)- ng by using the first three terms. Round your answer to five decimal places. (-19-1001 n=1 A.-0.06761
The interval for the sum of the series is approximately (-538.5, -223.83). The alternating series is given by Σ(-1)^n * g, where g is a sequence of numbers.
To determine an interval for the sum of the series, we can use the first few terms and examine the pattern.
In this case, we are given the series Σ(-1)^n * (-19 - 1001/n) with n starting from 1. Let's evaluate the first three terms:
Term 1: (-1)^1 * (-19 - 1001/1) = -19 - 1001 = -1020
Term 2: (-1)^2 * (-19 - 1001/2) = -19 + 1001/2 = -19 + 500.5 = 481.5
Term 3: (-1)^3 * (-19 - 1001/3) = -19 + 1001/3 ≈ -19 + 333.67 ≈ 314.67
From these three terms, we can observe that the series alternates between negative and positive values. The magnitude of the terms seems to decrease as n increases.
To find an interval for the sum of the series, we can consider the partial sums. The sum of the first term is -1020, the sum of the first two terms is -1020 + 481.5 = -538.5, and the sum of the first three terms is -538.5 + 314.67 = -223.83.
Since the series is alternating, the interval for the sum lies between two consecutive partial sums. Therefore, the interval for the sum of the series is approximately (-538.5, -223.83). Note that these values are rounded to five decimal places.
In this solution, we consider the given alternating series Σ(-1)^n * (-19 - 1001/n) with n starting from 1. We evaluate the first three terms and observe the pattern of alternating signs and decreasing magnitudes.
To find an interval for the sum of the series, we compute the partial sums by adding the terms one by one. We determine that the sum lies between two consecutive partial sums based on the alternating nature of the series.
Finally, we provide the interval for the sum of the series as (-538.5, -223.83), rounded to five decimal places. This interval represents the range of possible values for the sum based on the given information.
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For which type of level(s) of measurement is it appropriate to use range as a measure of Variability/dispersion? A) Nominal and ordinal B) None C) Ordinal and interval/ratio D) Nominal For which type
The appropriate level(s) of measurement to use range as a measure of variability/dispersion are interval/ratio (option C).
Range is a simple measure of variability that represents the difference between the largest and smallest values in a dataset. It provides a basic understanding of the spread or dispersion of the data. However, the range only takes into account the extreme values and does not consider the entire distribution of the data.
In nominal and ordinal levels of measurement, the data are categorized or ranked, respectively. Nominal data represents categories or labels with no inherent numerical order, while ordinal data represents categories that can be ranked but do not have consistent numerical differences between them. Since the range requires numerical values to compute the difference between the largest and smallest values, it is not appropriate to use range as a measure of variability for nominal or ordinal data.
On the other hand, in interval/ratio levels of measurement, the data have consistent numerical differences and a meaningful zero point. Interval data represents values with consistent intervals between them but does not have a true zero, while ratio data has a true zero point. Range can be used to measure the spread of interval/ratio data as it considers the numerical differences between the values.
Therefore, the appropriate level(s) of measurement to use range as a measure of variability/dispersion are interval/ratio (option C).
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Find the positive value of x that satisfies x=3.7cos(x).
Give the answer to six places of accuracy.
x≈
and to calculate the trig functions in radian mode.
The positive value of x that satisfies the equation x = 3.7cos(x) can be found using numerical methods such as the Newton-Raphson method. The approximate value of x to six decimal places is x ≈ 2.258819.
To solve the equation x = 3.7cos(x), we can rewrite it as a root-finding problem by subtracting the cosine term from both sides: x - 3.7cos(x) = 0. The objective is to find the value of x for which this equation equals zero.
Using the Newton-Raphson method, we start with an initial guess for x and iterate using the formula xᵢ₊₁ = xᵢ - f(xᵢ)/f'(xᵢ), where f(x) = x - 3.7cos(x) and f'(x) is the derivative of f(x) with respect to x.
By performing successive iterations, we converge to the value of x where f(x) approaches zero. In this case, starting with an initial guess of x₀ = 2.25, the approximate value of x to six decimal places is x ≈ 2.258819.
It's important to note that trigonometric functions are typically evaluated in radian mode, so the value of x in the equation x = 3.7cos(x) is also expected to be in radians.
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. Find the volume of the solid generated by revolving the region bounded by y Vx and the lines y 2 and x = O about (a) the x-axis. (b) the y-axis. (c) the line y = 2. (d) the line x = 4. monerated by revolving the triangu-
The volumes of the solids generated by revolving the region about different axes/lines are as follows:
(a) Revolving about the x-axis: 8π/3 cubic units
(b) Revolving about the y-axis: 40π/3 cubic units
(c) Revolving about the line y = 2: 16π/3 cubic units
(d) Revolving about the line x = 4: -24π cubic units
To find the volume of the solid generated by revolving the region bounded by y = x, y = 2, and x = 0, we can use the method of cylindrical shells.
(a) Revolving about the x-axis:
The height of each cylindrical shell will be the difference between the upper and lower functions, which is 2 - x. The radius of each shell will be x. The thickness of each shell will be dx.
The volume of each shell is given by dV = 2πx(2 - x) dx.
To find the total volume, we integrate this expression over the interval where x ranges from 0 to 2:
V = ∫[0,2] 2πx(2 - x) dx
Evaluating this integral, we find:
V = 2π ∫[0,2] (2x - x^2) dx
= 2π [x^2 - (x^3/3)] |[0,2]
= 2π [(2^2 - (2^3/3)) - (0^2 - (0^3/3))]
= 2π [(4 - 8/3) - (0 - 0)]
= 2π [(12/3 - 8/3)]
= 2π (4/3)
= 8π/3
Therefore, the volume of the solid generated by revolving the region about the x-axis is 8π/3 cubic units.
(b) Revolving about the y-axis:
In this case, the height of each cylindrical shell will be the difference between the upper and lower functions, which is y - 2. The radius of each shell will be y. The thickness of each shell will be dy.
The volume of each shell is given by dV = 2πy(y - 2) dy.
To find the total volume, we integrate this expression over the interval where y ranges from 2 to 4:
V = ∫[2,4] 2πy(y - 2) dy
Evaluating this integral, we find:
V = 2π ∫[2,4] (y^2 - 2y) dy
= 2π [y^3/3 - y^2] |[2,4]
= 2π [(4^3/3 - 4^2) - (2^3/3 - 2^2)]
= 2π [(64/3 - 16) - (8/3 - 4)]
= 2π [(64/3 - 48/3) - (8/3 - 12/3)]
= 2π [(16/3) - (-4/3)]
= 2π (20/3)
= 40π/3
Therefore, the volume of the solid generated by revolving the region about the y-axis is 40π/3 cubic units.
(c) Revolving about the line y = 2:
In this case, the height of each cylindrical shell will be the difference between the upper and lower functions, which is y - 2. The radius of each shell will be the distance from the line y = 2 to the y-coordinate, which is 2 - y. The thickness of each shell will be dy.
The volume of each shell is given by dV = 2π(2 - y)(y - 2) dy.
To find the total volume, we integrate this expression over the interval where y ranges from 2 to 4:
V = ∫[2,4] 2π(2 - y)(y - 2) dy
Note that the integrand is negative in this case, so we need to take the absolute value of the integral.
V = ∫[2,4] 2π|2 - y||y - 2| dy
Since the absolute values cancel each other out, the integral simplifies to:
V = 2π ∫[2,4] (y - 2)^2 dy
Evaluating this integral, we find:
V = 2π [y^3/3 - 4y^2 + 4y] |[2,4]
= 2π [(4^3/3 - 4(4)^2 + 4(4)) - (2^3/3 - 4(2)^2 + 4(2))]
= 2π [(64/3 - 64 + 16) - (8/3 - 16 + 8)]
= 2π [(64/3 - 48) - (8/3 - 8)]
= 2π [(16/3) - (8/3)]
= 2π (8/3)
= 16π/3
Therefore, the volume of the solid generated by revolving the region about the line y = 2 is 16π/3 cubic units.
(d) Revolving about the line x = 4:
In this case, the height of each cylindrical shell will be the difference between the upper and lower functions, which is 2 - x. The radius of each shell will be the distance from the line x = 4 to the x-coordinate, which is 4 - x. The thickness of each shell will be dx.
The volume of each shell is given by dV = 2π(4 - x)(2 - x) dx.
To find the total volume, we integrate this expression over the interval where x ranges from 0 to 2:
V = ∫[0,2] 2π(4 - x)(2 - x) dx
Expanding and simplifying the integrand, we have:
V = 2π ∫[0,2] (4x - x^2 - 8 + 2x) dx
= 2π [2x^2 - (1/3)x^3 - 8x + x^2] |[0,2]
= 2π [(2(2)^2 - (1/3)(2)^3 - 8(2) + (2)^2) - (2(0)^2 - (1/3)(0)^3 - 8(0) + (0)^2)]
= 2π [(8 - (8/3) - 16 + 4) - (0 - 0 - 0 + 0)]
= 2π [(24/3 - 8 - 16 + 4) - 0]
= 2π [(8 - 20) - 0]
= 2π (-12)
= -24π
Therefore, the volume of the solid generated by revolving the region about the line x = 4 is -24π cubic units. Note that the negative sign indicates that the resulting solid is "inside" the region.
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7a)
, 7b) , 7c) and 7d) please
7. Let F= (45,1 - 6y,2-2) (a) (4 points) Use curl F to determine if F is conservativo. (b) (2 points) Find div F. (0) (6 points) Use the Divergence Theorem to evaluate the flux ITF ds, where S is the
(a) The vector field F is not conservative because the curl of F is non-zero. (b) The divergence of F is 0. (c) The flux of F through the surface S cannot be evaluated without knowing the specific surface S.
To determine if the vector field F is conservative, we calculate the curl of F. The curl of F is given by ∇ × F, where ∇ is the del operator. If the curl is zero, the vector field is conservative.
Calculating the curl of F:
∇ × F = (d/dy)(2 - 2) - (d/dz)(1 - 6y) + (d/dx)(2 - 2)
= 0 - (-6) + 0
= 6
Since the curl of F is non-zero (6), the vector field F is not conservative.
The divergence of F, ∇ · F, is found by taking the dot product of the del operator and F. In this case, the divergence is:
∇ · F = (d/dx)(45) + (d/dy)(1 - 6y) + (d/dz)(2 - 2)
= 0 + (-6) + 0
= -6
Therefore, the divergence of F is -6.
To evaluate the flux of F through a surface S using the Divergence Theorem, we need more information about the specific surface S. Without that information, it is not possible to determine the value of the flux ITF ds.
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Let
the region R be the area enclosed by the function f(x)=x^3 and
g(x)=2x. If the region R is the base of a solid such that each
cross section perpendicular to the x-axis is a square, find the
volume
g(x) - Let the region R be the area enclosed by the function f(x) = x³ and 2x. If the region R is the base of a solid such that each cross section perpendicular to the x-axis is a square, find the vo
To find the volume of the solid with a square cross section, we need to integrate the area of each cross section along the x-axis. Since each cross section is a square, the area of each cross section is equal to the square of its side length.
The base of the solid is the region R enclosed by the functions f(x) = x^3 and g(x) = 2x. To find the limits of integration, we set the two functions equal to each other and solve for x:
x^3 = 2x
Simplifying the equation, we have:
x^3 - 2x = 0
Factoring out an x, we get:
x(x^2 - 2) = 0
This equation has two solutions: x = 0 and x = √2. Thus, the limits of integration are 0 and √2.
Now, for each value of x between 0 and √2, the side length of the square cross section is given by g(x) - f(x) = 2x - x^3. Therefore, the volume of each cross section is (2x - x^3)^2.
To find the total volume of the solid, we integrate the expression for the cross-sectional area with respect to x over the interval [0, √2]:
V = ∫[0,√2] (2x - x^3)^2 dx
Evaluating this integral will give us the volume of the solid.
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The sequence (2-2,-2) . n2 2n 1 sin () n=1 1 - converges to 2
The sequence (2-2,-2) . n^2 2^n 1 sin () n=1 1 - converges to 2. The convergence is explained by the dominant term, 2^n, which grows exponentially.
In the given sequence, the terms are expressed as (2-2,-2) . n^2 2^n 1 sin (), with n starting from 1. To understand the convergence of this sequence, we need to analyze its behavior as n approaches infinity. The dominant term in the sequence is 2^n, which grows exponentially as n increases. Exponential growth is significantly faster than polynomial growth (n^2), so the effect of the other terms becomes negligible in the long run.
As n gets larger and larger, the contribution of the terms 2^n and n^2 becomes increasingly more significant compared to the constant terms (-2, -2). The presence of the sine term, sin(), does not affect the convergence of the sequence since the sine function oscillates between -1 and 1, remaining bounded. Therefore, it does not significantly impact the overall behavior of the sequence as n approaches infinity.
Consequently, due to the exponential growth of the dominant term 2^n, the sequence converges to 2 as n tends to infinity. The constant terms and the other polynomial terms become insignificant in comparison to the exponential growth, leading to the eventual convergence to the value of 2.
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= Use the property of the cross product that |u x vl = \u| |v| sin to derive a formula for the distance d from a point P to a line 1. Use this formula to find the distance from the origin to the line
The distance from the origin to the line is 0.
To derive the formula for the distance from a point P to a line using the cross product property, let's consider a line represented by a vector equation as L: r = a + t * b, where r is a position vector on the line, a is a known point on the line, b is the direction vector of the line, and t is a parameter.
Now, let's consider a vector connecting a point P to a point Q on the line, given by the vector PQ: PQ = r - P.
The distance between the point P and the line L can be represented as the length of the perpendicular line segment from P to the line. This line segment is orthogonal (perpendicular) to the direction vector b of the line.
Using the cross product property |u x v| = |u| |v| sinθ, where u and v are vectors, θ is the angle between them, and |u x v| represents the magnitude of their cross product, we can determine the distance d as follows:
d = |PQ x b| / |b|
Now, let's compute the cross product PQ x b:
PQ = r - P = (a + t * b) - P
PQ x b = [(a + t * b) - P] x b
= (a + t * b) x b - P x b
= a x b + t * (b x b) - P x b
= a x b - P x b (since b x b = 0)
Taking the magnitude of both sides:
|PQ x b| = |a x b - P x b|
Finally, substituting this result into the formula for d:
d = |a x b - P x b| / |b|
This gives us the formula for the distance from a point P to a line.
To find the distance from the origin to the line, we can choose a point on the line (a) and the direction vector of the line (b) to substitute into the formula. Let's assume the origin O (0, 0, 0) as the point P, and let a = (x₁, y₁, z₁) be a point on the line. We also need to determine the direction vector b.
Using the given information, we can find the direction vector b by subtracting the coordinates of the origin from the coordinates of point a:
b = a - O = (x₁, y₁, z₁) - (0, 0, 0) = (x₁, y₁, z₁)
Now, we can substitute the values into the formula:
d = |a x b - P x b| / |b|
= |(x₁, y₁, z₁) x (x₁, y₁, z₁) - (0, 0, 0) x (x₁, y₁, z₁)| / |(x₁, y₁, z₁)|
= |0 - (0, 0, 0)| / |(x₁, y₁, z₁)|
= |0| / |(x₁, y₁, z₁)|
= 0 / |(x₁, y₁, z₁)|
= 0
Therefore, the distance from the origin to the line is 0. This implies that the origin lies on the line itself.
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8. (6 pts) Let f(x) = x² +3x+2. Find the average value of fon [1,4]. Find c such that fave = f(c).
The average value of f(x) on the interval [1, 4] is 473/18, and the values of c that satisfy fave = f(c) are approximately c = -4.326 and c = 3.992.
To find the average value of f(x) on the interval [1, 4], we need to calculate the definite integral of f(x) over that interval and divide it by the width of the interval.
First, let's find the integral of f(x) over [1, 4]:
∫[1, 4] (x² + 3x + 2) dx = [(1/3)x³ + (3/2)x² + 2x] |[1, 4]
= [(1/3)(4)³ + (3/2)(4)² + 2(4)] - [(1/3)(1)³ + (3/2)(1)² + 2(1)]
= [64/3 + 24 + 8] - [1/3 + 3/2 + 2]
= [64/3 + 24 + 8] - [2/6 + 9/6 + 12/6]
= [64/3 + 24 + 8] - [23/6]
= 248/3 - 23/6
= (496 - 23) / 6
= 473/6
Next, we calculate the width of the interval [1, 4], which is 4 - 1 = 3.
Now, we can find the average value of f(x) on [1, 4]:
fave = (1/3) * ∫[1, 4] (x² + 3x + 2) dx
= (1/3) * (473/6)
= 473/18
To find c such that fave = f(c), we set f(c) equal to the average value:
x² + 3x + 2 = 473/18
Simplifying and rearranging, we have:
18x² + 54x + 36 = 473
18x² + 54x - 437 = 0
Now we can solve this quadratic equation to find the value(s) of c.
Using the quadratic form the average value of f(x) on the interval [1, 4] is 473/18, and the values of c that satisfy fave = f(c) are approximately c = -4.326 and c = 3.992.ula, we have:
x = (-54 ± √(54² - 4(18)(-437))) / (2(18))
Calculating this expression, we find two solutions for x:
x ≈ -4.326 or x ≈ 3.992
Therefore, the value of c that satisfies fave = f(c) is approximately c = -4.326 or c = 3.992.
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Create an equation in the form y = asin(x - d) + c given the transformations below.
The function has a maximum value of 8 and a minimum value of 2. The function has also been vertically translated 1 unit up, and horizontally translated 10 degrees to the right.
The equation representing the given transformations is y = 3sin(x - 10°) + 3.
To create an equation in the form y = asin(x - d) + c given the transformations, we can start with the standard sine function and apply the given transformations step by step:
Vertical translation 1 unit up:
The standard sine function has a maximum value of 1 and a minimum value of -1.
To vertically translate it 1 unit up, we add 1 to the function.
This gives us a maximum value of 1 + 1 = 2 and a minimum value of -1 + 1 = 0.
Horizontal translation 10 degrees to the right:
The standard sine function completes one full period (i.e., goes from 0 to 2π) in 360 degrees.
To shift it 10 degrees to the right, we subtract 10 degrees from the angle inside the sine function.
This accounts for the horizontal translation.
Adjusting the amplitude:
To achieve a maximum value of 8, we need to adjust the amplitude of the function.
The amplitude represents the vertical stretch or compression of the graph.
In this case, the amplitude needs to be 8/2 = 4 since the original sine function has an amplitude of 1.
Putting it all together, the equation for the given transformations is:
y = 4sin(x - 10°) + 2
This equation represents a sine function that has been vertically translated 1 unit up, horizontally translated 10 degrees to the right, and has a maximum value of 8 and a minimum value of 2.
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Find the area of the triangle depicted. and Find the area of a triangle with a = 15, b = 19, and C = 54º. 7 cm 4 cm A B 6 cm
The area of the triangle with side lengths a = 15 cm, b = 19 cm, and angle C = 54º is approximately 142.76 cm².
To find the area of a triangle, we can use the formula A = (1/2) * base * height. In the given triangle, we need to determine the base and height in order to calculate the area.
The triangle has sides of lengths 4 cm, 6 cm, and 7 cm. Let’s label the vertex opposite the side of length 7 cm as vertex C, the vertex opposite the side of length 6 cm as vertex A, and the vertex opposite the side of length 4 cm as vertex B.
To find the height of the triangle, we draw a perpendicular line from vertex C to side AB. Let’s label the point of intersection as point D.
Since triangle ABC is not a right triangle, we need to use trigonometry to find the height. We have angle C = 54º and side AC = 4 cm. Using the trigonometric ratio, we can write:
Sin C = height / AC
Sin 54º = height / 4 cm
Solving for the height, we find:
Height = 4 cm * sin 54º ≈ 3.07 cm
Now we can calculate the area of the triangle:
A = (1/2) * base * height
A = (1/2) * 7 cm * 3.07 cm
A ≈ 10.78 cm²
Therefore, the area of the triangle is approximately 10.78 cm².
For the second part of the question, we are given side lengths a = 15 cm, b = 19 cm, and angle C = 54º. To find the area of this triangle, we can use the formula A = (1/2) * a * b * sin C.
Substituting the given values, we have:
A = (1/2) * 15 cm * 19 cm * sin 54º
A ≈ 142.76 cm²
Therefore, the area of the triangle with side lengths a = 15 cm, b = 19 cm, and angle C = 54º is approximately 142.76 cm².
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Use integration by parts to evaluate the integral. S7xe 4x dx If Su dv=S7xe 4x dx, what would be good choices for u and dv? A. u = 7x and dv = e 4x dx B. u= e 4x and dv=7xdx O C. u = 7x and dv = 4xdx O D. u= 4x and dv = 7xdx S7xe 4x dx =
A good choice for u is 7x, and a good choice for dv is e^(4x)dx.To determine the best choices for u and dv, we can apply the integration by parts formula, which states ∫u dv = uv - ∫v du.
In this case, we want to integrate S7xe^(4x)dx.
Let's consider the options provided:
A. u = 7x and dv = e^(4x)dx: This choice is appropriate because the derivative of 7x with respect to x is 7, and integrating e^(4x)dx is relatively straightforward.
B. u = e^(4x) and dv = 7xdx: This choice is not ideal because the derivative of e^(4x) with respect to x is 4e^(4x), making it more complicated to evaluate the integral of 7xdx.
C. u = 7x and dv = 4xdx: This choice is not optimal since the integral of 4xdx requires integration by the power rule, which is not as straightforward as integrating e^(4x)dx.
D. u = 4x and dv = 7xdx: This choice is also not ideal because integrating 7xdx leads to a quadratic expression, which is more complex to handle.
Therefore, the best choices for u and dv are u = 7x and dv = e^(4x)dx.
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(1 point) let y be the solution of the initial value problem y′′ y=−sin(2x),y(0)=0,y′(0)=0. the maximum value of y is
The solution must be concise, the maximum value of y can be found by following the above steps. To find the maximum value, you'll need to analyze the resulting function for any critical points or turning points. The maximum value of y will occur at the highest turning point in the given interval.
To find the maximum value of y in the given initial value problem y'' + y = -sin(2x) with the conditions y(0) = 0 and y'(0) = 0, we can follow these steps:
1. Identify that the given problem is a second-order homogeneous linear differential equation with constant coefficients.
2. Find the complementary function by solving the homogeneous equation y'' + y = 0.
3. Apply the method of variation of parameters to find the particular solution for the non-homogeneous equation.
4. Combine the complementary function and the particular solution to obtain the general solution of the given problem.
5. Apply the initial conditions y(0) = 0 and y'(0) = 0 to find the constants in the general solution.
6. Analyze the solution to determine the maximum value of y.
Since the solution must be concise, the maximum value of y can be found by following the above steps. To find the maximum value, you'll need to analyze the resulting function for any critical points or turning points. The maximum value of y will occur at the highest turning point in the given interval.
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3.2 The velocity of a bullet from a rifle can be approximated by v(t) = 6400t2 – 6505t + 2686 where t is seconds after the shot and v is the velocity measured in feet per second. This equation only models the velocity for the first half-second after the shot. What is the average velocity of the first half second?
The average velocity of the first half-second. Calculate the change in displacement and divide it by the change in time to obtain .
By integrating the supplied velocity function throughout the range [0, 0.5], the displacement can be calculated. Now let's figure out the displacement:
∫(6400t^2 - 6505t + 2686) dt
When we combine each term independently, we obtain:
[tex](6400/3)t3 - (6505/2)t2 + 2686t = (6400t2) dt - (6505t) dt + (2686t)[/tex]
The displacement function will now be assessed at t = 0.5 and t = 0:
Moving at time[tex]t = 0.5: (6400/3)(0.5)^3 - (6505/2)(0.5)^2 + 2686(0.5)[/tex]
Displacement at time zero: (6505/2)(0) + 2686(0) - (6400/3)(0)
We only need to determine the displacement at t = 0.5 because the displacement at t = 0 is 0 (assuming the bullet is launched from the origin):
Moving at time [tex]t = 0.5: (6400/3)(0.5)^3 - (6505/2)(0.5)^2 + 2686(0.5)[/tex]
Streamlining .
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Find all inflection points for f(x) = x4 - 10x3 +24x2 + 3x + 5. O Inflection points at x=0, x= 1,* = 4 O Inflection points at x - 1,x=4 O Inflection points at x =-0.06, X = 2.43 x 25.13 O This function does not have any inflection points.
The solutions to this equation are x = 1 and x = 4. Therefore, the inflection points occur at x = 1 and x = 4.
To find the inflection points of a function, we need to examine the behavior of its second derivative. In this case, let's first calculate the second derivative of f(x):
f''(x) = (x^4 - 10x^3 + 24x^2 + 3x + 5)''.
Taking the derivative twice, we get:
f''(x) = 12x^2 - 60x + 48.
To find the inflection points, we need to solve the equation f''(x) = 0. Let's solve this quadratic equation:
12x^2 - 60x + 48 = 0.
Simplifying, we divide the equation by 12:
x^2 - 5x + 4 = 0.
Factoring, we get:
(x - 1)(x - 4) = 0.
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christina would like to put a fence around her yard. the length of her yard measures (x+1) cm and the width measures (2x+3) cm the perimeter is 26 cm. find the length and width of christina's yard?
The length of Christina's yard is 4 cm, and the width is 9 cm.
To find the length and width of Christina's yard, we'll solve the given problem step by step.
Let's assume that the length of Christina's yard is represented by 'L' and the width is represented by 'W'. According to the problem, we have the following information:
Length of the yard = (x+1) cm
Width of the yard = (2x+3) cm
Perimeter of the yard = 26 cm
Perimeter of a rectangle is given by the formula:
Perimeter = 2(L + W)
Substituting the given values into the formula, we get:
26 = 2[(x+1) + (2x+3)]
Now, let's simplify the equation:
26 = 2(x + 1 + 2x + 3)
26 = 2(3x + 4) [Combine like terms]
26 = 6x + 8 [Distribute 2 to each term inside parentheses]
18 = 6x [Subtract 8 from both sides]
3 = x [Divide both sides by 6]
We have found the value of 'x' to be 3.
Now, substitute the value of 'x' back into the expressions for the length and width:
Length of the yard = (x+1) cm
Length = (3+1) cm
Length = 4 cm
Width of the yard = (2x+3) cm
Width = (2*3+3) cm
Width = 9 cm
Therefore, the length of Christina's yard is 4 cm, and the width is 9 cm.
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I need A And B please do not do just 1
thanks
6. Find the following integrals. a) | 화 bj2 b)
Therefore, the integral of the function of b squared is (1/3) b³ + C. Given integral to find is : (a) | 화 bj2 (b) Here is the detailed explanation to find both the integrals.
(a) Let us evaluate the integral of the absolute value of the cube of the function of b where b is a constant as follows:
Integral of f(x) dx = Integral of x^n dx = [tex]x^{n+1}[/tex]/ (n+1) + C
Where C is a constant of integration
Let f(b) = | b³ |
f(b) = b³ for b >= 0 and f(b) = -b³ for b < 0
Now, we need to find the integral of f(b) as follows:
Integral of f(b) db = Integral of | b³ | db = Integral of b³ db for b >= 0
Now, apply the integration formula as follows:
Integral of b^n db = [tex]b^{n+1}[/tex]/ (n+1) + CSo, Integral of b³ db = b⁴ / 4 + C = (1/4)b⁴ + C for b >= 0
Similarly, we can write for b < 0, and the function f(b) is -b^3.
Therefore, Integral of f(b) db = Integral of - b³ db = - (b⁴ / 4) + C = - (1/4)b⁴ + C for b < 0
Therefore, the integral of the absolute value of the cube of the function of b where b is a constant is | b⁴ | / 4 + C.
(b) Let us evaluate the integral of the function of b squared as follows:
Integral of f(x) dx = Integral of x^n dx = [tex]x^{n+1}[/tex] / (n+1) + CWhere C is a constant of integration
Let f(b) = b²Now, we need to find the integral of f(b) as follows:
The integral of f(b) db = Integral of b² dbNow, apply the integration formula as follows:
The integral of b^n db = [tex]b^{n+1}[/tex] / (n+1) + CSo, Integral of b² db = b³ / 3 + C = (1/3)b³ + C
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Find the probability of selecting none of the correct six integers in a lottery, where the order in which these integers are selected does not matter, from the positive integers not exceeding the given integers. (Enter the value of probability in decimals. Round the answer to two decimal places.)
Discrete Probability with Lottery
The probability of selecting none of the correct six integers is given by:
Probability = (number of unfavorable outcomes) / (total number of possible outcomes)
= C(n - 6, 6) / C(n, 6)
The probability of selecting none of the correct six integers in a lottery can be calculated by dividing the number of unfavorable outcomes by the total number of possible outcomes. Since the order in which the integers are selected does not matter, we can use the concept of combinations.
Let's assume there are n positive integers not exceeding the given integers. The total number of possible outcomes is given by the number of ways to select any 6 integers out of the n integers, which is represented by the combination C(n, 6).
The number of unfavorable outcomes is the number of ways to select 6 integers from the remaining (n - 6) integers, which is represented by the combination C(n - 6, 6).
Therefore, the probability of selecting none of the correct six integers is given by:
Probability = (number of unfavorable outcomes) / (total number of possible outcomes)
= C(n - 6, 6) / C(n, 6)
To obtain the value of probability in decimals, we can evaluate this expression using the given value of n and round the answer to two decimal places.
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Solve the following linear system by Gaussian elimination. X1 + 4x2 + 4x3 = 24 -X1 - 5x2 + 5x3 = -19 X1 - 3x2 + 6x3 = -2 X1 = i X2 = i X3 = i
To solve the linear system using Gaussian elimination, let's start by writing down the augmented matrix for the system:
1 4 4 | 24
-1 -5 5 | -19
1 -3 6 | -2
Now, we'll perform row operations to transform the matrix into row-echelon form:
Replace R2 with R2 + R1:
1 4 4 | 24
0 -1 9 | 5
1 -3 6 | -2
Replace R3 with R3 - R1:
1 4 4 | 24
0 -1 9 | 5
0 -7 2 | -26
Multiply R2 by -1:
1 4 4 | 24
0 1 -9 | -5
0 -7 2 | -26
Replace R3 with R3 + 7R2:
1 4 4 | 24
0 1 -9 | -5
0 0 -59 | -61
Now, the matrix is in row-echelon form. Let's solve it by back substitution:
From the last row, we have:
-59x3 = -61, so x3 = -61 / -59 = 61 / 59.
Substituting x3 back into the second row, we get:
x2 - 9(61 / 59) = -5.
Multiplying through by 59, we have:
59x2 - 9(61) = -295,
59x2 = -295 + 9(61),
59x2 = -295 + 549,
59x2 = 254,
x2 = 254 / 59.
Substituting x2 and x3 into the first row, we get:
x1 + 4(254 / 59) + 4(61 / 59) = 24,
59x1 + 1016 + 244 = 1416,
59x1 = 1416 - 1016 - 244,
59x1 = 156,
x1 = 156 / 59.
Therefore, the solution to the linear system is:
x1 = 156 / 59,
x2 = 254 / 59,
x3 = 61 / 59.
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Consider the curve defined by the equation y= 3x2 + 10x. Set up an integral that represents the length of curve from the point (0,0) to the point (3,57). o dx. Note: In order to get credit for this problem all answers must be correct.
The integral that represents the length of the curve from point (0,0) to point (3,57) is ∫[0 to 3] √(1 + (6x + 10)²) dx.
To find the length of the curve, we use the arc length formula:
L = ∫[a to b] √(1 + (dy/dx)²) dx
In this case, the given equation is y = 3x² + 10x. We need to find dy/dx, which is the derivative of y concerning x. Taking the derivative, we have:
dy/dx = 6x + 10
Now we substitute this into the arc length formula:
L = ∫[0 to 3] √(1 + (6x + 10)²) dx
To evaluate this integral, we simplify the expression inside the square root:
1 + (6x + 10)² = 1 + 36x² + 120x + 100 = 36x² + 120x + 101
Now, we have:
L = ∫[0 to 3] √(36x² + 120x + 101) dx
Evaluating this integral will give us the length of the curve from (0,0) to (3,57).
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if we know the level of confidence (1.98 for 95 percent), variability estimates, and the size of a sample, there is a formula that allows us to determine: a. the costs of the sample. b. the accuracy (sample error) c. the representativeness of the sample. d. p or q.
The level of confidence, variability estimates, and sample size can help determine the accuracy (sample error) and estimate the costs of the sample.
Explanation: The level of confidence (e.g., 95%) indicates the probability that the sample accurately represents the population. It determines the range within which the population parameter is estimated. The variability estimates, such as the standard deviation or variance, provide information about the spread of the data. By combining the level of confidence, variability estimates, and sample size, one can estimate the accuracy or sample error, which represents how closely the sample statistics reflect the population parameters.
Determining the costs of the sample involves factors beyond the provided information, such as data collection methods, analysis procedures, and logistical considerations. The representativeness of the sample depends on the sampling method used and how well it captures the characteristics of the target population.
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Solve the initial value problem for r as a vector function of t. d²r Differential equation: 38k dt² Initial conditions: r(0) =90k and = 3i+ 3j - r(t)=i+Di+Ok dr dt t=0
The position vector function r(t) is given by:r(t) = -19D/2t² i - 19O/2t² j + (3i + 3j)t + 90k.
The given differential equation is d²r/dt² = 38k with initial conditions:
r(0) = 90k and r'(0) = 3i + 3j - Di - Ok.
To solve this initial value problem, we can proceed as follows:
First, we find the first derivative of r(t) by integrating the given initial condition for r'(0):
∫r'(0)dt = ∫(3i + 3j - Di - Ok)dt => r(t) = 3ti + 3tj - (D/2)t²i - (O/2)t²j + C1
where C1 is an arbitrary constant of integration.Next, we find the second derivative of r(t) by differentiating the above equation with respect to time:
t = 3i + 3j - Di - Ok => r'(t) = 3i + 3j - (D/2)2ti - (O/2)2tj => r''(t) = -D/2 i - O/2 j
Hence, the given differential equation can be written as:-
D/2 i - O/2 j = 38kr''(t) = 38k (-D/2 i - O/2 j) => r''(t) = -19Dk i - 19Ok j
Next, we integrate the above equation twice with respect to time to obtain the position vector function r(t):
∫∫r''(t)dt² = ∫∫(-19Dk i - 19Ok j)dt² => r(t) = -19D/2t² i - 19O/2t² j + C2t + C3
where C2 and C3 are arbitrary constants of integration.
Substituting the initial condition r(0) = 90k in the above equation, we get:
C3 = 90kSubstituting the initial condition r'(0) = 3i + 3j - Di - Ok in the above equation, we get:
C2 = 3i + 3j - (D/2)0²i - (O/2)0²j = 3i + 3j
Hence, the position vector function r(t) is:
r(t) = -19D/2t² i - 19O/2t² j + (3i + 3j)t + 90k
Answer: The position vector function r(t) is given by:r(t) = -19D/2t² i - 19O/2t² j + (3i + 3j)t + 90k.
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An open-top rectangular box is being constructed to hold a volume of 250 in3. The base the box is made from a material costing 5 cents/in2. The front of the box must be decorated, and will cost 9 cents/in2. The remainder of the sides will cost 2 cents/in2. Find the dimensions that will minimize the cost of constructing this box. Round your answers to two decimal places as needed. Front width: in. Depth: in. Height: in.
The dimensions that will minimize the cost of constructing the box are Front width: 7.21 inches, Depth: 7.21 inches and Height: 4.81 inches
Finding the dimensions that will minimize the cost of constructing the boxFrom the question, we have the following parameters that can be used in our computation:
Volume = 250in³Cost of material = 5 cent/in² of base, 9 cent/in² of front and 2 cent/in² of the sidesThe volume is calculated as
V = b²h
So, we have
b²h = 250
Make h the subject
h = 250/b²
The surface area is then calculated as
SA = b² + bh + 3bh
This means that the cost is
Cost = 5b² + 9bh + 2 * 3bh
This gives
Cost = 5b² + 15bh
So, we have
Cost = 5(b² + 3bh)
Recall that
h = 250/b²
So, we have
Cost = 5(b² + 3b * 250/b²)
Evaluate
Cost = 5(b² + 750/b)
Differentiate and set to 0
10b - 3750/b² = 0
This gives
10b = 3750/b²
Cross multiply
10b³ = 3750
Divide by 10
b³ = 375
Take the cube root of both sides
b = 7.21
Next, we have
h = 250/(7.21)²
Evaluate
h = 4.81
Hence, the dimensions are Front width: 7.21 inches, Depth: 7.21 inches and Height: 4.81 inches
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1. Determine the derivative of the following. Leave your final answer in a simplified factored form with positive exponents. b. y = 4e-5x a. y = 45x C. y = xe* d. y = sin(sin(x2)) e. y = sinx - 3x f.
b. dy/dx = [tex]-20e^(-5x)[/tex] a. dy/dx = 45 c. dy/dx = [tex]e^x + xe^x[/tex]
d. dy/dx = [tex]2x*cos(sin(x^2))*cos(x^2)[/tex] e. dy/dx = cos(x) - 3
f. dy/dx = [tex]e^(0.5x)sin(4x) + 4e^(0.5x)cos(4x)[/tex]
b. To find the derivative of [tex]y = 4e^(-5x)[/tex], we can use the chain rule. The derivative is:
dy/dx = [tex]4(-5)e^(-5x)[/tex]
=[tex]-20e^(-5x)[/tex]
a. The derivative of y = 45x is:
dy/dx = 45
c. To find the derivative of [tex]y = xe^x[/tex], we can use the product rule. The derivative is:
dy/dx = [tex](1)(e^x) + (x)(e^x)[/tex]
=[tex]e^x + xe^x[/tex]
d. To find the derivative of [tex]y = sin(sin(x^2))[/tex], we can use the chain rule. The derivative is:
[tex]dy/dx = cos(sin(x^2))(2x)cos(x^2)[/tex]
[tex]= 2x*cos(sin(x^2))*cos(x^2)[/tex]
e. To find the derivative of y = sin(x) - 3x, we can use the sum/difference rule. The derivative is:
dy/dx = cos(x) - 3
f. To find the derivative of [tex]y = 2e^(0.5x)sin(4x) + 4[/tex], we can use the product and chain rules. The derivative is:
[tex]dy/dx = (2)(0.5e^(0.5x))(sin(4x)) + (2e^(0.5x))(4cos(4x))[/tex]
[tex]= e^(0.5x)sin(4x) + 4e^(0.5x)cos(4x)[/tex]
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The complete question is:
1. Determine the derivative of the following. Leave your final answer in a simplified factored form with positive exponents.
b. y = 4e-5x
a. y = 45x
c. y = xe*
d. y = sin(sin(x2))
e. y = sinx - 3x
f. y = 2e0.5x sin(4x) + 4
Find the present value of an ordinary annuity with deposits of $8,701 quarterly for 3 years at 4.4% compounded quarterly. What is the present value? (Round to the nearest cent.)
We can use the following formula to get the present value of an ordinary annuity:
PV is equal to A * (1 - (1 + r)(-n)) / r.
Where n is the number of periods, r is the interest rate per period, A is the periodic payment, and PV is the present value.
In this instance, the periodic payment is $8,701, the interest rate is 4.4% (or 0.044) per period, and there are 3 periods totaling 12 quarters due to the quarterly nature of the deposits.
Using the formula's given values as substitutes, we obtain:
[tex]PV = 8701 * (1 - (1 + 0.044)^(-12)) / 0.044[/tex]
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Determine if the following series are absolutely convergent, conditionally convergent, or divergent. LE 4+ sin(n) 1/2 +3 TR=1
the series ∑(4 + sin(n))/(2n + 3) is divergent but conditionally convergent. To determine the convergence of the series ∑(4 + sin(n))/(2n + 3), we need to analyze its absolute convergence, conditional convergence, or divergence.
Absolute Convergence:
We start by considering the absolute value of each term in the series. Taking the absolute value of (4 + sin(n))/(2n + 3), we have |(4 + sin(n))/(2n + 3)|. Now, let's apply the limit comparison test to determine if the series is absolutely convergent. We compare it to a known convergent series with positive terms, such as the harmonic series ∑(1/n). Taking the limit as n approaches infinity of the ratio of the two series: lim(n->∞) |(4 + sin(n))/(2n + 3)| / (1/n) = lim(n->∞) n(4 + sin(n))/(2n + 3). Since the limit evaluates to a nonzero finite value, the series ∑(4 + sin(n))/(2n + 3) diverges.
Conditional Convergence:
To determine if the series ∑(4 + sin(n))/(2n + 3) is conditionally convergent, we need to check if the series converges when we remove the absolute value.
By removing the absolute value, we have ∑(4 + sin(n))/(2n + 3). To analyze the convergence of this series, we can use the alternating series test since the terms alternate in sign (positive and negative) due to the sin(n) component. We need to check two conditions: The terms approach zero: lim(n->∞) (4 + sin(n))/(2n + 3) = 0 (which it does). The terms are monotonically decreasing: |(4 + sin(n))/(2n + 3)| ≥ |(4 + sin(n + 1))/(2(n + 1) + 3)|.
Since both conditions are satisfied, the series ∑(4 + sin(n))/(2n + 3) is conditionally convergent.
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Find a power series representation for the function. (Give your power series representation centered at x = 0.) = 8 f(x) = 0 9 X 00 f(x) = Σ n = 0 Determine the interval of convergence. (Enter your answer using interval notation.)
The given function is: f(x) = Σn=0 ∞xⁿ, which is a geometric series. Here a = 1 and r = x, so we have:$$\sum_{n=0}^{\infty}x^n = \frac{1}{1-x}$$Now we will find a power series representation for the function
By expressing it as a sum of powers of x:$$\frac{1}{1-x} = 1 + x + x^2 + x^3 + \cdots = \sum_{n=0}^{\infty}x^n$$Therefore, the power series representation for the given function centered at x = 0 is:$$f(x) = \sum_{n=0}^{\infty}x^n$$The interval of convergence of this power series is (-1, 1), which we can find by using the ratio test:$$\lim_{n\to\infty} \left|\frac{a_{n+1}}{a_n}\right| = \lim_{n\to\infty} \left|\frac{x^{n+1}}{x^n}\right| = \lim_{n\to\infty} |x| = |x|$$The series converges if $|x| < 1$ and diverges if $|x| > 1$. Therefore, the interval of convergence is (-1, 1).
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write 36 as a product of its prime factor writethe factor in order from smalest to largest
The factors of 36 are 2×2×3×3
Order from smallest to largest: 2×2×3×3
Write an expression to represent: 5 55 times the sum of � xx and 3 33.
The expression to represent the statement 5 times the sum of x and 3 is 5 * (x + 3)
Writing an expression to represent the statementfrom the question, we have the following parameters that can be used in our computation:
5 times the sum of x and 3
times as used here means product
So, we have
5 * the sum of x and 3
the sum of as used here means addition
So, we have
5 * (x + 3)
Hence, the expression to represent the statement is 5 * (x + 3)
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Question
Write an expression to represent: 5 times the sum of x and 3
If the derivative of a function f() is f'(x) er it is impossible to find f(x) without writing it as an infinito sur first and then integrating the Infinite sum. Find the function f(x) by (a) First finding f'(x) as a MacClaurin series by substituting -x into the Maclaurin series for e: (b) Second, simplying the MacClaurin series you got for f'(x) completely. It should look like: (= عی sm n! 0 ORION trom simplified (c) Evaluating the indefinite integral of the series simplified in (b): 00 ſeda = 5(2) - Sr() der = der TO (d) Using that f(0) = 6 + 1 to determine the constant of integration for the power series representation for f(x) that should now look like: 00 Integral of f(α) = Σ the Simplified dur + Expression from a no
The required function is f(x) =[tex]-x^2/2 + x^3/6 - x^4/24 + x^5/120 - x^6/720[/tex]+ .... + 7 for maclaurin series.
Given that the derivative of a function f() is f'(x) er it is impossible to find f(x) without writing it as an infinite sum first and then integrating the Infinite sum. We have to find the function f(x) by:
The infinite power series known as the Maclaurin series, which bears the name of the Scottish mathematician Colin Maclaurin, depicts a function as being centred on the value x = 0. It is a particular instance of the Taylor series expansion, and the coefficients are established by the derivatives of the function at x = 0.
(a) First finding f'(x) as a Maclaurin series by substituting -x into the Maclaurin series for e:(b) Second, simplifying the Maclaurin series you got for f'(x) completely. It should look like: (= عی sm n! 0 ORION trom simplified)(c) Evaluating the indefinite integral of the series simplified in (b):
(d) Using that f(0) = 6 + 1 to determine the constant of integration for the power series representation for f(x) that should now look like: 00 Integral of f(α) = Σ the Simplified dur + Expression from a no(a) First finding f'(x) as a MacLaurin series by substituting -x into the MacLaurin series for e:
[tex]e^-x = ∑ (-1)^n (x^n/n!)f(x) = f'(x) = e^-x f(x) = -e^-x[/tex]
(b) Second, simplifying the Maclaurin series you got for f'(x) completely. It should look like:[tex]f'(x) = -e^-x = -∑(x^n/n!) = ∑(-1)^(n+1)(x^n/n!) = -x - x^2/2 - x^3/6 - x^4/24 - x^5/120 - ....f'(x) = ∑(-1)^(n+1) (x^n/n!)[/tex]
(c) Evaluating the indefinite integral of the series simplified in (b):[tex]∫f'(x)dx = f(x) = ∫(-x - x^2/2 - x^3/6 - x^4/24 - x^5/120 - ....)dx = -x^2/2 + x^3/6 - x^4/24 + x^5/120 - x^6/720 + ....+ C(f(0) = 6 + 1) = -0/2 + 0/6 - 0/24 + 0/120 - 0/720 + .....+ C= 7+ C[/tex]
Therefore, the constant of integration is C = -7f(x) = [tex]-x^2/2 + x^3/6 - x^4/24 + x^5/120 - x^6/720[/tex] + .... + 7
Hence, the required function is f(x) = [tex]-x^2/2 + x^3/6 - x^4/24 + x^5/120 - x^6/720[/tex]+ .... + 7.
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