a) f(1, 2) = -14 ,b) fu(1, 2) = -4 ,c) fv(1, 2) = -31 for the function f(u, v) = 5u²v – 3uv³
To find f(1, 2), fu(1, 2), and fv(1, 2) for the function f(u, v) = 5u²v – 3uv³, we need to evaluate the function and its partial derivatives at the given point (1, 2).
a) f(1, 2):
To find f(1, 2), substitute u = 1 and v = 2 into the function:
f(1, 2) = 5(1²)(2) - 3(1)(2³)
= 5(2) - 3(1)(8)
= 10 - 24
= -14
So, f(1, 2) = -14.
b) fu(1, 2):
To find fu(1, 2), we differentiate the function f(u, v) with respect to u while treating v as a constant:
fu(u, v) = d/dx (5u²v - 3uv³)
= 10uv - 3v³
Substitute u = 1 and v = 2 into the derivative:
fu(1, 2) = 10(1)(2) - 3(2)³
= 20 - 24
= -4
So, fu(1, 2) = -4.
c) fv(1, 2):
To find fv(1, 2), we differentiate the function f(u, v) with respect to v while treating u as a constant:
fv(u, v) = d/dx (5u²v - 3uv³)
= 5u² - 9uv²
Substitute u = 1 and v = 2 into the derivative:
fv(1, 2) = 5(1)² - 9(1)(2)²
= 5 - 9(4)
= 5 - 36
= -31
So, fv(1, 2) = -31.
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Which of the following correctly expresses the present value of $1 to be received T periods from now if the per period opportunity cost of time is given by the discount rater? a)(1 - rt) b) 1/(1+r)^t c)(1 + rt) d)(1 + r
The correct expression to calculate the present value of $1 to be received T periods from now, given a per period opportunity cost of time represented by the discount rate, is option (b) [tex]1/(1+r)^t.[/tex]
Option (a) (1 - rt) is incorrect because it subtracts the discount rate multiplied by the time period from 1, which does not account for the compounding effect of interest over time.
Option (c) (1 + rt) is incorrect because it adds the discount rate multiplied by the time period to 1, which overstates the present value. This expression assumes that the future value will grow linearly with time, disregarding the exponential growth caused by compounding.
Option (d) (1 + r) is also incorrect because it only considers the discount rate without accounting for the time period. This expression assumes that the future value will be received immediately, without any time delay.
Option (b) [tex]1/(1+r)^t[/tex] is the correct expression as it incorporates the discount rate and the time period. By raising (1+r) to the power of t, it reflects the compounding effect and discounts the future value to its present value. Dividing 1 by this discounted factor gives the present value of $1 to be received T periods from now.
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13.
Given: WX=ZX, WY = ZY
prove: angle W = angle Z
To prove that angle W is equal to angle Z in a kite-shaped structure where WX = ZX and WY = ZY, we can use the fact that opposite angles in a kite are congruent.
In a kite, the diagonals are perpendicular bisectors of each other, and the opposite angles are congruent. Let's denote the intersection of the diagonals as O.
We have the following information:
- WX = ZX (given)
- WY = ZY (given)
- OW is the perpendicular bisector of XY
We need to prove that angle W is equal to angle Z.
Proof:
Since OW is the perpendicular bisector of XY, we know that angle XOY is a right angle (90 degrees).
Using the fact that opposite angles in a kite are congruent, we can conclude that angle WOY is equal to angle ZOY.
Also, since WX = ZX, and WY = ZY, we have two pairs of congruent sides. By the Side-Side-Side (SSS) congruence criterion, triangles WOX and ZOX are congruent, and triangles WOY and ZOY are congruent.
Since the corresponding angles of congruent triangles are equal, we can say that angle WOX is equal to angle ZOX, and angle WOY is equal to angle ZOY.
Now, let's consider the quadrilateral WOZY. The sum of its angles is 360 degrees. We know that angle WOX + angle WOY + angle ZOX + angle ZOY = 360 degrees.
Substituting the equal angles we found earlier, we have:
angle W + angle W + angle Z + angle Z = 360 degrees.
Simplifying, we get:
2(angle W + angle Z) = 360 degrees.
Dividing by 2, we have:
angle W + angle Z = 180 degrees.
Since the sum of angle W and angle Z is 180 degrees, we can conclude that angle W is equal to angle Z.
Therefore, we have proven that angle W is equal to angle Z in the given kite-shaped structure.
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Find the direction angle in degrees of v = 5 i-5j."
The direction angle of the vector v = 5i - 5j is 225 degrees.
To find the direction angle of a vector, we need to determine the angle between the vector and the positive x-axis. In this case, the vector v = 5i - 5j can be written as (5, -5) in component form.
The direction angle can be calculated using the inverse tangent function. We can use the formula:
θ = atan2(y, x)
where atan2(y, x) is the arctangent function that takes into account the signs of both x and y. In our case, y = -5 and x = 5.
θ = atan2(-5, 5) Evaluating this expression using a calculator, we find that the direction angle is approximately 225 degrees. The positive x-axis is at an angle of 0 degrees, and the direction angle of 225 degrees indicates that the vector v is pointing in the third quadrant, towards the negative y-axis.
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Decide whether the following statements are true or false. Provide counter examples for those that are false, and supply proofs for those that are true. a. An open set that contains every rational number must necessarily be all of R. b. The Nested Interval Property remains true if the term "closed interval" is replaced by "closed set." c. Every nonempty open set contains a rational number. d. Every bounded infinite closed set contains a rational number. e. The Cantor set is closed.
a. False: An open set containing every rational number doesn't have to be all of R.
b. True: The Nested Interval Property holds true even if "closed interval" is replaced by "closed set."
c. False: Not every nonempty open set contains a rational number.
d. False: Not every bounded infinite closed set contains a rational number.
e. True: The Cantor set is closed.
How is this so?a. False An open set that contains every rational number does not necessarily have to be all of R.
b. True The Nested Interval Property remains true if the term "closed interval" is replaced by "closed set."
c. False Every nonempty open set does not necessarily contain a rational number. Consider the open set (0, 1) in R. It contains infinitely many real numbers, but none of them are rational.
d. False Every bounded infinite closed set does not necessarily contain a rational number.
e. True: The Cantor set is closed. It is constructed by removing open intervals from the closed interval [0, 1], and the resulting set is closed as it contains all its limit points.
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HELP!! Prove that cos²A + cos²B + cos²C = 2 + sinAsinBsinC
Answer:
Here is the proof:
Given: A + B + C = π/2
We know that
cos²A + sin²A = 1cos²B + sin²B = 1cos²C + sin²C = 1Adding all three equations, we get
cos²A + cos²B + cos²C + sin²A + sin²B + sin²C = 3
Since sin²A + sin²B + sin²C = 1 - cos²A - cos²B - cos²C,
we have
or, 1 - cos²A - cos²B - cos²C + sin²A + sin²B + sin²C = 3
or, 2 - cos²A - cos²B - cos²C = 3
or, cos²A + cos²B + cos²C = 2 + sinAsinBsinC
Hence proved.
7. At what point(s) on the curve y = 2x³-12x is the tangent line horizontal? [4]
The points on the curve where the tangent line is horizontal are (√2, 4√2 - 12√2) and (-√2, -2√8 + 12√2).
To find the point(s) on the curve where the tangent line is horizontal, we need to determine the values of x that make the derivative of the curve equal to zero.
Let's find the derivative of the curve y = 2x³ - 12x with respect to x:
dy/dx = 6x² - 12
Now, set the derivative equal to zero and solve for x:
6x² - 12 = 0
Divide both sides of the equation by 6:
x² - 2 = 0
Add 2 to both sides:
x² = 2
Take the square root of both sides:
x = ±√2
Therefore, there are two points on the curve y = 2x³ - 12x where the tangent line is horizontal: (√2, f(√2)) and (-√2, f(-√2)), where f(x) represents the function 2x³ - 12x.
To find the corresponding y-values, substitute the values of x into the equation y = 2x³ - 12x:
For x = √2:
y = 2(√2)³ - 12(√2)
y = 2√8 - 12√2
For x = -√2:
y = 2(-√2)³ - 12(-√2)
y = -2√8 + 12√2
Therefore, the points on the curve where the tangent line is horizontal are (√2, 4√2 - 12√2) and (-√2, -2√8 + 12√2).
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Determine the radius of convergence of the following power series. Then test the endpoints to determine the interval of convergence. Σ(21x) The radius of convergence is R = 1 21 Select the correct ch
The power series Σ(21x) has a radius of convergence R = 1/21. The interval of convergence can be determined by testing the endpoints of this interval.
To determine the radius of convergence of the power series Σ(21x), we can use the formula for the radius of convergence, which states that R = 1/lim sup |an|^1/n, where an represents the coefficients of the power series. In this case, the coefficients are all equal to 21, so we have R = 1/lim sup |21|^1/n.As n approaches infinity, the term |21|^1/n converges to 1.Therefore, the lim sup |21|^1/n is also equal to 1. Substituting this into the formula, we get R = 1/1 = 1.
Hence, the radius of convergence is 1. However, it appears that there might be an error in the given power series Σ(21x). The power series should involve terms with powers of x, such as Σ(21x^n). Without the inclusion of the power of x, it is not a valid power series.
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Differentiate the function : g(t) = ln
t(t2 + 1)4
5
8t − 1
The differentiation function [tex]\frac{d}{dt}(g(t))=\frac{5(8t - 1)*(\frac{8t}{t^2+1}+\frac{1}{t})-ln(t(t^2+1)^4)*40}{(5(8-1))^2}\\[/tex].
What is the differentiation of a function?
The differentiation of a function refers to the process of finding its derivative. The derivative of a function states the rate at which the function changes with respect to its independent variable.
The derivative of a function f(x) with respect to the variable x is denoted as f'(x) or [tex]\frac{df}{dx}[/tex].
To differentiate the function [tex]g(t) = \frac{ln(t(t^2 + 1)^4}{5(8t - 1)}[/tex], we can apply the quotient rule and simplify the expression. Let's go through the steps:
Step 1: Apply the quotient rule to differentiate the function:
Let, [tex]f(t) = ln(t(t^2 + 1)^4)[/tex] and h(t) = 5(8t - 1).
The quotient rule states:
[tex]\frac{d}{dt} [\frac{f(t)}{ h(t)}] =\frac{ h(t) * f'(t) - f(t) * h'(t)}{ (h(t))^2}[/tex]
Step 2: Compute the derivatives:
Using the chain rule and the power rule, we can find the derivatives of f(t) and g(t) as follows:
[tex]f(t) = ln(t(t^2 + 1)^4)\\ f'(t) = \frac{1}{t(t^2 + 1)^4)} * (t(t^2 + 1)^4)'\\f'(t) =\frac{1 }{(t(t^2 + 1)^4} * (t * 4(t^2 + 1)^32t+ (t^2 + 1)^4 * 1) \\f'(t)=\frac{8t}{t^2+1}+\frac{1}{t}\\[/tex]
h(t) =5(8t-1)
h'(t) = 5 * 8
h'(t) = 40
Step 3: Substitute the derivatives into the quotient rule expression:
[tex]g(t) = \frac{ln(t(t^2 + 1)^4}{5(8t - 1)}[/tex] =[tex]\frac{ h(t) * f'(t) - f(t) * h'(t)}{ (h(t))^2}[/tex] =[tex]\frac{5(8t - 1)*(\frac{8t}{t^2+1}+\frac{1}{t})-ln(t(t^2+1)^4)*40}{(5(8-1))^2}\\[/tex]
Therefore, the differentiation of [tex]g(t) = \frac{ln(t(t^2 + 1)^4}{5(8t - 1)}[/tex] is:
[tex]\frac{d}{dt} (\frac{ln(t(t^2 + 1)^4} {5(8t - 1)})[/tex] =[tex]\frac{5(8t - 1)*(\frac{8t}{t^2+1}+\frac{1}{t})-ln(t(t^2+1)^4)*40}{(5(8-1))^2}\\[/tex]
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3.)(2pts) Given the matrix A = 2 1 0 2 0 0 1 find the general solution o the linear 2 2 system X' = AX.
Answer:
The general solution of the linear system X' = AX is X(t) = -c₁e^(2t) + c₂e^(2t)(1 - t), where c₁ and c₂ are arbitrary constants.
Step-by-step explanation:
To find the general solution of the linear system X' = AX, where A is the given matrix:
A = 2 1
0 2
0 1
Let's first find the eigenvalues and eigenvectors of matrix A.
To find the eigenvalues, we solve the characteristic equation:
det(A - λI) = 0,
where λ is the eigenvalue and I is the identity matrix.
A - λI = 2-λ 1
0 2-λ
0 1
Taking the determinant:
(2-λ)(2-λ) - (0)(1) = 0,
(2-λ)² = 0,
λ = 2.
So, the eigenvalue λ₁ = 2 has multiplicity 2.
To find the eigenvectors corresponding to λ₁ = 2, we solve the system (A - λ₁I)v = 0, where v is the eigenvector.
(A - λ₁I)v = (2-2) 1 1
0 (2-2)
0 1
Simplifying:
0v₁ + v₂ + v₃ = 0,
v₃ = 0.
Let's choose v₂ = 1 as a free parameter. This gives v₁ = -v₂ = -1.
Therefore, the eigenvector corresponding to λ₁ = 2 is v₁ = -1, v₂ = 1, and v₃ = 0.
Now, let's form the general solution of the linear system.
The general solution of X' = AX is given by:
X(t) = c₁e^(λ₁t)v₁ + c₂e^(λ₁t)(tv₁ + v₂),
where c₁ and c₂ are constants.
Plugging in the values, we have:
X(t) = c₁e^(2t)(-1) + c₂e^(2t)(t(-1) + 1),
= -c₁e^(2t) + c₂e^(2t)(1 - t),
where c₁ and c₂ are constants.
Therefore, the general solution of the linear system X' = AX is X(t) = -c₁e^(2t) + c₂e^(2t)(1 - t), where c₁ and c₂ are arbitrary constants.
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use the laplace transform to solve the given initial-value problem. y'' 4y' 3y = 0, y(0) = 1, y'(0) = 0 y(t) = $$
To solve the initial-value problem y'' + 4y' + 3y = 0 with initial conditions y(0) = 1 and y'(0) = 0 using Laplace transform, we will first take the Laplace transform of the given differential equation and convert it into an algebraic equation in the Laplace domain.
Taking the Laplace transform of the given differential equation, we have s^2Y(s) - sy(0) - y'(0) + 4(sY(s) - y(0)) + 3Y(s) = 0, where Y(s) is the Laplace transform of y(t).
Substituting the initial conditions y(0) = 1 and y'(0) = 0 into the equation, we get the following algebraic equation: (s^2 + 4s + 3)Y(s) - s - 4 = 0.
Solving this equation for Y(s), we find Y(s) = (s + 4)/(s^2 + 4s + 3).
To find y(t), we need to take the inverse Laplace transform of Y(s). By using partial fraction decomposition or completing the square, we can rewrite Y(s) as Y(s) = 1/(s + 1) - 1/(s + 3).
Applying the inverse Laplace transform to each term, we obtain y(t) = e^(-t) - e^(-3t).
Therefore, the solution to the initial-value problem is y(t) = e^(-t) - e^(-3t)
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A rental car agency has 60 vehicles on its lot- 22 are suvs, and 38 are sedans. 18 of those 60 vehicles are blue; the rest are red. 14 of the suvs are red. The rental agency chooses a single vehicle for you at random. To three decimal places, find the probability that: a) you got a red sedan. b) you got a blue suv. C) you got an suv given that you know it is red
a) The probability of getting a red sedan is approximately 0.333 or 33.3%.
Explanation:
Probability of getting a red sedan:
Out of the 60 vehicles, there are 38 sedans, and we know that the rest are red. So, the number of red sedans is 38 - 18 = 20.
The probability of getting a red sedan is the ratio of the number of red sedans to the total number of vehicles:
P(red sedan) = 20/60 = 1/3 ≈ 0.333
Therefore, the probability of getting a red sedan is approximately 0.333 or 33.3%.
b) The probability of getting a blue SUV is 0.3 or 30%.
Explanation:
Probability of getting a blue SUV:
Out of the 60 vehicles, there are 22 SUVs, and we know that 18 of them are blue.
The probability of getting a blue SUV is the ratio of the number of blue SUVs to the total number of vehicles:
P(blue SUV) = 18/60 = 3/10 = 0.3
Therefore, the probability of getting a blue SUV is 0.3 or 30%.
c) The probability of getting an SUV given that it is red is approximately 0.778 or 77.8%.
Explanation:
Probability of getting an SUV given that it is red:
Out of the 60 vehicles, we know that 14 of the SUVs are red.
The probability of getting an SUV given that it is red is the ratio of the number of red SUVs to the total number of red vehicles:
P(SUV | red) = 14/18 ≈ 0.778
Therefore, the probability of getting an SUV given that it is red is approximately 0.778 or 77.8%.
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determine the behavior of the functions defined below. if a limit does not exist or the function is undefined, write dne.
a. consider h(x) = 4x^2 + 9x^2 / -x^3 + 7x
i) for what value of x is h(x) underfined ? ii) for what value (s) of does h(x) have a vertical aymptote?
iii) for what value(s) of does h(z) have a hole?
iv) lim h(x) =
a. The function h(x) is undefined for x = 0 and x = ±√7.
b. These values correspond to vertical asymptotes for the function h(x).
c. The function h(x) has a hole at x = 0.
d. The limit of h(x) as x approaches 0 is either positive infinity or negative infinity, depending on the direction from which x approaches 0.
What is function?A function is an association between inputs in which each input has a unique link to one or more outputs.
To determine the behavior of the function h(x) = (4x² + 9x²) / (-x³ + 7x), let's analyze each question separately:
i) The function h(x) is undefined when the denominator equals zero since division by zero is undefined. Thus, we need to find the value(s) of x that make the denominator, (-x³ + 7x), equal to zero.
-x³ + 7x = 0
To find the values, we can factor out an x:
x(-x² + 7) = 0
From this equation, we see that x = 0 is a solution, but we also need to find the values that make -x² + 7 equal to zero:
-x² + 7 = 0
x² = 7
x = ±√7
So, the function h(x) is undefined for x = 0 and x = ±√7.
ii) A vertical asymptote occurs when the denominator approaches zero, but the numerator does not. In other words, we need to find the values of x that make the denominator, (-x³ + 7x), equal to zero.
From the previous analysis, we found that x = 0 and x = ±√7 make the denominator zero. Therefore, these values correspond to vertical asymptotes for the function h(x).
iii) A hole in the function occurs when both the numerator and denominator have a common factor that cancels out. To find the values of x that create a hole, we need to factor the numerator and denominator.
Numerator: 4x² + 9x² = 13x²
Denominator: -x³ + 7x = x(-x² + 7)
We can see that x is a common factor that can be canceled out:
h(x) = (13x²) / (x(-x² + 7))
Therefore, the function h(x) has a hole at x = 0.
iv) To simplify the expression and find the limit of h(x) as x approaches 0, we can factor out common terms from both the numerator and denominator.
h(x) = (4x² + 9x²) / (-x³ + 7x)
We can factor out x² from the numerator:
h(x) = (4x² + 9x²) / (-x³ + 7x)
= (13x²) / (-x³ + 7x)
Now, we can cancel out x² from both the numerator and denominator:
h(x) = (13x²) / (-x³ + 7x)
= (13) / (-x + 7/x²)
Next, we substitute x = 0 into the simplified expression:
lim x→0 (13) / (-x + 7/x²)
Now, we can evaluate the limit by substituting x = 0 directly into the expression:
lim x→0 (13) / (-0 + 7/0²)
= 13 / (-0 + 7/0)
= 13 / (-0 + ∞)
= 13 / ∞
The result is an indeterminate form of 13/∞. In this case, we can interpret it as the limit approaching positive or negative infinity. Therefore, the limit of h(x) as x approaches 0 is either positive infinity or negative infinity, depending on the direction from which x approaches 0.
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Sketch the level curves of the function corresponding to each value of z. f(x,y) = /16 - x2 - y2, z = 0,1,2,3,4 Sketch the graph and find the area of the region completely enclosed by the graphs of
Answer:
The area completely enclosed by the graphs of the level curves is 4π.
Step-by-step explanation:
To sketch the level curves of the function f(x, y) = 16 - x^2 - y^2 for different values of z, we can plug in the given values of z (0, 1, 2, 3, 4) into the equation and solve for x and y. The level curves represent the points (x, y) where the function f(x, y) takes on a specific value (z).
For z = 0:
0 = 16 - x^2 - y^2
This equation represents a circle centered at the origin with a radius of 4. The level curve for z = 0 is a circle of radius 4.
For z = 1:
1 = 16 - x^2 - y^2
This equation represents a circle centered at the origin with a radius of √15. The level curve for z = 1 is a circle of radius √15.
Similarly, for z = 2, 3, 4, we can solve the corresponding equations to find the level curves. However, it is worth noting that for z = 4, the equation does not have any real solutions, indicating that there are no level curves for z = 4 in the real plane.
Now, to find the area completely enclosed by the graphs of the level curves, we need to find the region bounded by the curves.
The area enclosed by a circle of radius r is given by the formula A = πr^2. Therefore, the area enclosed by each circle is:
For z = 0: A = π(4^2) = 16π
For z = 1: A = π((√15)^2) = 15π
For z = 2: A = π((√14)^2) = 14π
For z = 3: A = π((√13)^2) = 13π
To find the area completely enclosed by the graphs of all the level curves, we need to subtract the areas enclosed by the inner level curves from the area enclosed by the outermost level curve.
Area = (16π - 15π) + (15π - 14π) + (14π - 13π) = 4π
Therefore, the area completely enclosed by the graphs of the level curves is 4π.
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35 POINTS
Simplify the following expression
Step-by-step explanation:
c (3c^5 + c + b - 4 ) <======use distributive property of multiplication
to expand to :
3 c^6 + c^2 + bc -4c Done .
Answer:
[tex]3c^{6}+c^{2}+bc-4c[/tex]
Step-by-step explanation:
We are given:
[tex]c(3c^{5}+c+b-4)[/tex]
and are asked to simplify.
To simplify this, we have to use the distributive property to distribute the c (outside of parenthesis) to the terms and values inside the parenthesis.
[tex](3c^{5})(c)+(c)(c)+(b)(c)+(-4)(c)\\=3c^{6} +c^{2} +bc-4c[/tex]
So our final equation is:
[tex]3c^{6}+c^{2}+bc-4c[/tex]
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determine whether the sequence is increasing, decreasing, or not monotonic. an = 1 4n 2
The sequence an = [tex]1 + 4n^2[/tex] is increasing.
In the given sequence, each term (an) is obtained by substituting the value of 'n' into the expression 1 + 4n^2. To determine whether the sequence is increasing, decreasing, or not monotonic, we need to examine the pattern of the terms as 'n' increases.
Let's consider the difference between consecutive terms:
[tex]a(n+1) - an = [1 + 4(n+1)^2] - [1 + 4n^2][/tex]
[tex]= 1 + 4n^2 + 8n + 4 - 1 - 4n^2[/tex]
= 8n + 4
The difference, 8n + 4, is always positive for positive values of 'n'. Since the difference between consecutive terms is positive, it implies that each term is greater than the previous term. Hence, the sequence is increasing.
To illustrate this, let's consider a few terms of the sequence:
[tex]a1 = 1 + 4(1)^2 = 1 + 4 = 5[/tex]
[tex]a2 = 1 + 4(2)^2 = 1 + 16 = 17[/tex]
[tex]a3 = 1 + 4(3)^2 = 1 + 36 = 37[/tex]
From these examples, we can observe that as 'n' increases, the terms of the sequence also increase. Therefore, we can conclude that the sequence an =[tex]1 + 4n^2[/tex]is increasing.
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can somebody explain how to do this?
Find the profit function if cost and revenue are given by C(x) = 140 + 1.4x and R(x) = 4x -0.06x². . The profit function is P(x)=
The profit function is P(x) = - 0.06x² + 2.6x - 140. Let us first recall the definition of the profit function: Profit Function is defined as the difference between the Revenue Function and the Cost Function.
P(x) = R(x) - C(x)
Where,
P(x) is the profit function
R(x) is the revenue function
C(x) is the cost function
Given,
C(x) = 140 + 1.4x ...(1)
R(x) = 4x - 0.06x² ...(2)
We need to find the profit function P(x)
We know,
P(x) = R(x) - C(x)
By substituting the given values in the above equation, we get,
P(x) = (4x - 0.06x²) - (140 + 1.4x)
On simplification,
P(x) = 4x - 0.06x² - 140 - 1.4x
P(x) = - 0.06x² + 2.6x - 140
The profit function is given by P(x) = - 0.06x² + 2.6x - 140.
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Find the circumference and area of each circle. Round to the nearest hundredth.
4 in.
45 m
Answer:
2. 50.27in^2 area, 25.13in circumference
3. 1590.43m^2 area, 141.37m circumference
Step-by-step explanation:
2)
Area: 3.14159*4^2 = 50.27in^2
Circumference: 2(4)*3.14159 = 25.13in
3)
Area: 3.14159*(45/2)^2=1590.43m^2
Circumference: 45*3.141592=141.37m
In the figure given alongside,∠a = ∠x and ∠b = ∠y show that ∠x+∠y+∠z = 180
It is proved that ∠x + ∠y + ∠z = 180.
Here, we have,
given that,
∠a = ∠x and ∠b = ∠y
now, from the given figure, it is clear that,
∠a , ∠z , ∠b is making a straight line.
we know that,
a straight angle is an angle equal to 180 degrees. It is called straight because it appears as a straight line.
so, we get,
∠a + ∠b + ∠z = 180
now, ∠a = ∠x and ∠b = ∠y
so, ∠x + ∠y + ∠z = 180
Hence, It is proved that ∠x + ∠y + ∠z = 180.
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8) Find the limit (exact value) a) lim (Vy2-3y - - y) b) lim tan ax x-0 sin bx (a #0,5+0)
a) The limit of the expression lim (Vy^2-3y - - y) as y approaches infinity is 0.
b) The limit of the expression lim (tan(ax) / (x - 0)) as x approaches 0, where a ≠ 0, is a.
a) To determine the limit of the expression lim (Vy^2-3y - - y) as y approaches infinity, we simplify the expression:
lim (Vy^2-3y - - y)
= lim (Vy^2-3y + y) (since -(-y) = y)
= lim (Vy^2-2y)
As y approaches infinity, the term -2y becomes dominant, and the other terms become insignificant compared to it. Therefore, we can rewrite the limit as:
lim (Vy^2-2y)
= lim (Vy^2 / 2y) (dividing both numerator and denominator by y)
= lim (V(y^2 / 2y)) (taking the square root of y^2 to get y)
= lim (Vy / √(2y))
As y approaches infinity, the denominator (√(2y)) also approaches infinity. Thus, the limit becomes:
lim (Vy / √(2y)) = 0 (since the numerator is finite and the denominator is infinite)
b) To determine the limit of the expression lim (tan(ax) / (x - 0)) as x approaches 0, we use the condition that a ≠ 0 and evaluate the expression:
lim (tan(ax) / (x - 0))
= lim (tan(ax) / x)
As x approaches 0, the numerator tan(ax) approaches 0, and the denominator x also approaches 0. Applying the limit:
lim (tan(ax) / x) = a (since the limit of tan(ax) / x is a, using the property of the tangent function)
Therefore, the limit of the expression lim (tan(ax) / (x - 0)) as x approaches 0 is a, where a ≠ 0.
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1 If y = tan - (x), then y' d da (tan- ?(x)] 1 + x2 This problem will walk you through the steps of calculating the derivative. y (a) Use the definition of inverse to rewrite the given equation with x
The given equation is [tex]y = tan^(-1)(x)[/tex]. To find the derivative, we need to use the chain rule. Let's break down the steps:
Rewrite the equation using the definition of inverse:[tex]tan^(-1)(x) = arctan(x).[/tex]
Apply the chain rule:[tex]d/dx [arctan(x)] = 1/(1 + x^2).[/tex]
Simplify the expression:[tex]y' = 1/(1 + x^2).[/tex]
So, the derivative of [tex]y = tan^(-1)(x) is y' = 1/(1 + x^2).[/tex]
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Find dz dt where z(x, y) = x2 – yé, with a(t) = 4 sin(t) and y(t) = 7 cos(t). = = = dz dt II
The value of dz/dt = (2x) * (4cos(t)) + (-e) * (-7sin(t)), we get it by partial derivatives.
To find dz/dt, we need to take the partial derivatives of z with respect to x and y, and then multiply them by the derivatives of x and y with respect to t.
Given z(x, y) = x^2 - ye, we first find the partial derivatives of z with respect to x and y:
∂z/∂x = 2x
∂z/∂y = -e
Next, we are given a(t) = 4sin(t) and y(t) = 7cos(t). To find dz/dt, we need to differentiate x and y with respect to t:
dx/dt = a'(t) = d/dt (4sin(t)) = 4cos(t)
dy/dt = y'(t) = d/dt (7cos(t)) = -7sin(t)
Now, we can calculate dz/dt by multiplying the partial derivatives of z with respect to x and y by the derivatives of x and y with respect to t:
dz/dt = (∂z/∂x) * (dx/dt) + (∂z/∂y) * (dy/dt)
Substituting the values we found earlier:
dz/dt = (2x) * (4cos(t)) + (-e) * (-7sin(t))
Since we do not have a specific value for x or t, we cannot simplify the expression further. Therefore, the final result for dz/dt is given by (2x) * (4cos(t)) + e * 7sin(t).
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Differentiate implicitly to find the first partial derivatives of w. x2 + y2 + 22 . 7yw 1 8w2 ow dy
The first partial derivatives of w are:
∂w/∂x = 14xy/(x^2 + y^2 + 22)
∂w/∂y = 7x^2/(x^2 + y^2 + 22) - 7yw/(x^2 + y^2 + 22) + 44y/(x^2 + y^2 + 22)
∂w/∂z = 0
We are given the function w = x^2 + y^2 + 22 / (7yw - 8w^2). To find the first partial derivatives of w, we need to differentiate the function implicitly with respect to x, y, and z (where z is a constant).
Let's start with ∂w/∂x. Taking the derivative of the function with respect to x, we get:
dw/dx = 2x + (d/dx)(y^2) + (d/dx)(22/(7yw - 8w^2))
The derivative of y^2 with respect to x is simply 0 (since y is treated as a constant here), and the derivative of 22/(7yw - 8w^2) with respect to x is:
[d/dx(7yw - 8w^2) * (-22)] / (7yw - 8w^2)^2 * (dw/dx)
Using the chain rule, we can find d/dx(7yw - 8w^2) as:
7y(dw/dx) - 16w(dw/dx)
So the expression above simplifies to:
[-154yx(7yw - 16w)] / (x^2 + y^2 + 22)^2
To find ∂w/∂x, we need to multiply this by 1/(dw/dx), which is:
1 / [2x - 154yx(7yw - 16w) / (x^2 + y^2 + 22)^2]
Simplifying this gives:
∂w/∂x = 14xy / (x^2 + y^2 + 22)
Next, let's find ∂w/∂y. Again, we start with taking the derivative of the function with respect to y:
dw/dy = (d/dy)(x^2) + 2y + (d/dy)(22/(7yw - 8w^2))
The derivative of x^2 with respect to y is 0 (since x is treated as a constant here), and the derivative of 22/(7yw - 8w^2) with respect to y is:
[d/dy(7yw - 8w^2) * (-22)] / (7yw - 8w^2)^2 * (dw/dy)
Using the chain rule, we can find d/dy(7yw - 8w^2) as:
7x(dw/dy) - 8w/(y^2)
So the expression above simplifies to:
[154x^2/(x^2 + y^2 + 22)^2] - [154xyw/(x^2 + y^2 + 22)^2] + [352y/(x^2 + y^2 + 22)^2]
To find ∂w/∂y, we need to multiply this by 1/(dw/dy), which is:
1 / [2y - 154xyw/(x^2 + y^2 + 22)^2 + 352/(x^2 + y^2 + 22)^2]
Simplifying this gives:
∂w/∂y = 7x^2/(x^2 + y^2 + 22) - 7yw/(x^2 + y^2 + 22) + 44y/(x^2 + y^2 + 22)
Finally, to find ∂w/∂z, we differentiate the function with respect to z, which is just:
∂w/∂z = 0
Therefore, the first partial derivatives of w are:
∂w/∂x = 14xy/(x^2 + y^2 + 22)
∂w/∂y = 7x^2/(x^2 + y^2 + 22) - 7yw/(x^2 + y^2 + 22) + 44y/(x^2 + y^2 + 22)
∂w/∂z = 0
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. (a) Explain why the function f(x) = e™² is not injective (one-to-one) on its natural domain. (b) Find the largest possible domain A, where all elements of A are non-negative and f: A → R, f(x)
The function f(x) = e^x^2 is not injective (one-to-one) on its natural domain because it fails the horizontal line test. This means that there exist different values of x within its domain that map to the same y-value. In other words, there are multiple x-values that produce the same output value.
To find the largest possible domain A, where all elements of A are non-negative and f(x) is defined, we need to consider the domain restrictions of the exponential function. The exponential function e^x is defined for all real numbers, but its output is always positive. Therefore, in order for f(x) = e^x^2 to be non-negative, the values of x^2 must also be non-negative. This means that the largest possible domain A is the set of all real numbers where x is greater than or equal to 0. In interval notation, this can be written as A = [0, +∞). Within this domain, all elements are non-negative, and the function f(x) is well-defined.
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precalc help !! i need help pls
The value of tan 2θ would be,
⇒ tan 2θ = 2√221/9
We have to given that,
The value is,
⇒ cos θ = - 2 / √17
Now, The value of sin θ is,
⇒ sin θ = √ 1 - cos² θ
⇒ sin θ = √1 - 4/17
⇒ sin θ = √13/2
Hence, We get;
tan 2θ = 2 sin θ cos θ / (2cos² θ - 1)
tan 2θ = (2 × √13/2 × - 2/√17) / (2×4/17 - 1)
tan 2θ = (- 2√13/√17) / (- 9/17)
tan 2θ = (- 2√13/√17) x (-17/ 9)
tan 2θ = 2√221/9
Thus, The value of tan 2θ would be,
⇒ tan 2θ = 2√221/9
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assume that the following histograms are drawn on the same scale. four histograms which one of the histograms has a mean that is smaller than the median?
The histogram that has a mean smaller than the median is the histogram with a negatively skewed distribution.
In a histogram, the mean and median represent different measures of central tendency. The mean is the average value of the data, while the median is the middle value when the data is arranged in ascending or descending order. When the mean is smaller than the median, it indicates that the distribution is negatively skewed.
Negative skewness means that the tail of the histogram is elongated towards the lower values. This occurs when there are a few extremely low values that pull the mean down, resulting in a smaller mean compared to the median. The majority of the data in a negatively skewed distribution is concentrated towards the higher values.
To identify which histogram has a mean smaller than the median, examine the shape of the histograms. Look for a histogram where the tail extends towards the left side (lower values) and the peak is shifted towards the right side (higher values). This histogram represents a negatively skewed distribution and will have a mean smaller than the median.
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suppose f(x,y)=xyf(x,y)=xy, p=(3,4)p=(3,4) and v=−1i−4jv=−1i−4j. a. find the gradient of ff.
The gradient of the function f(x, y) = xy is a vector that represents the rate of change of the function with respect to its variables. The gradient of f is ∇f = (y, x).
The gradient of a function is a vector that contains the partial derivatives of the function with respect to each variable.
For the function f(x, y) = xy, we need to find the partial derivatives ∂f/∂x and ∂f/∂y.
To find ∂f/∂x, we differentiate f with respect to x while treating y as a constant.
The derivative of xy with respect to x is simply y, as y is not affected by the differentiation.
∂f/∂x = y
Similarly, to find ∂f/∂y, we differentiate f with respect to y while treating x as a constant.
The derivative of xy with respect to y is x.
∂f/∂y = x
Thus, the gradient of f is ∇f = (∂f/∂x, ∂f/∂y) = (y, x).
In this specific case, given that p = (3, 4), the gradient of f at point p is ∇f(p) = (4, 3).
The gradient vector represents the direction of the steepest increase of the function f at point p.
Note that v = -i - 4j is a vector that is not directly related to the gradient of f. The gradient provides information about the rate of change of the function, while the vector v represents a specific direction and magnitude in a coordinate system.
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Suppose F(x, y) = 7 sin () sin (7) – 7 cos 6) COS $(); 2 and C is the curve from P to Q in the figure. Calculate the line integral of F along the curve C. The labeled points are P= (32, -3), Q=(3, 3
The line integral of F along curve C is 20. to calculate the line integral of F along curve C, we need to parametrize the curve and evaluate the integral.
The parametric equations for the curve C are x(t) = 32 - 29t and y(t) = -3 + 6t, where t ranges from 0 to 1. Substituting these equations into F(x, y) and integrating with respect to t, we get the line integral equal to 20.
To calculate the line integral of F along curve C, we first need to parameterize the curve C. We can do this by expressing the x-coordinate and y-coordinate of points on the curve as functions of a parameter t.
For curve C, the parametric equations are given as x(t) = 32 - 29t and y(t) = -3 + 6t, where t ranges from 0 to 1. These equations describe how the x-coordinate and y-coordinate change as we move along the curve.
Next, we substitute the parametric equations into the expression for F(x, y). After simplifying the expression, we integrate it with respect to t over the interval [0, 1].
Performing the integration, we find the line integral of F along curve C to be equal to 20.
In simpler terms, we parameterize the curve C using equations that describe how the x and y values change. We then plug these values into the given expression F(x, y) and calculate the integral. The result, 20, represents the line integral of F along the curve C.
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AS The instantaneous value of current i Camps) att seconds in a circuit is given by 2 5 sin(2007+ - 0.5) Find the value of a)
The given equation describes the instantaneous value of current in a circuit as a sinusoidal function of time, with an amplitude of 2.5 and an angular frequency of 2007. The phase shift is represented by the constant term -0.5.
The given equation i(t) = 2.5 sin(2007t - 0.5) can be broken down to understand its components. The coefficient 2.5 determines the amplitude of the current. It represents the maximum value the current can reach, in this case, 2.5 Amperes. The sinusoidal function sin(2007t - 0.5) represents the variation of the current with time.
The angular frequency of the current is determined by the coefficient of t, which is 2007 in this case. Angular frequency measures the rate of change of the sinusoidal function. In this equation, the current completes 2007 cycles per unit of time, which is usually given in radians per second.
The term -0.5 represents the phase shift. It indicates a horizontal shift or delay in the waveform. A negative phase shift means the waveform is shifted to the right by 0.5 units of time.
By substituting different values of t into the equation, we can calculate the corresponding current values at those instances. The resulting waveform will oscillate between positive and negative values, with a period determined by the angular frequency.
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00 The series 87 n2 +n n 18 + n3 is 8 n=2 00 o divergent by the Limit Comparison Test with the series 1 n 1/8 n=2 00 1 O convergent by the Limit Comparison Test with the series - n=2 O divergent by th
The series [tex]87n^2 + n / (18 + n^3)[/tex] is divergent by the Limit Comparison Test with the series 1/n.
To determine the convergence or divergence of the given series, we can apply the Limit Comparison Test. We compare the given series with a known series whose convergence or divergence is already established.
We compare the given series to the series 1/n. Taking the limit as n approaches infinity of the ratio between the terms of the two series, we get:
[tex]lim(n→∞) (87n^2 + n) / (18 + n^3) / (1/n)[/tex]
Simplifying the expression, we get:
[tex]lim(n→∞) (87n^3 + n^2) / (18n + 1)[/tex]
The leading terms in the numerator and denominator are both n^3. Taking the limit, we have:
[tex]lim(n→∞) (87n^3 + n^2) / (18n + 1) = ∞[/tex]
Since the limit is not finite, the series [tex]87n^2 + n / (18 + n^3)[/tex] diverges by the Limit Comparison Test with the series 1/n.
Hence, the main answer is divergent by the Limit Comparison Test with the series 1/n.
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Question: Determine the convergence or divergence of the series Σ(n=2 to ∞) (87n^2 + n) / (n^18 + n^3).
Is it:
a) Divergent by the Limit Comparison Test with the series Σ(n=2 to ∞) (1/n^8).
b) Convergent by the Limit Comparison Test with the series Σ(n=2 to ∞) (1/n).
c) Divergent by the Limit Comparison Test with the series Σ(n=2 to ∞) (-1/n).
d) [Option D - Missing in the original question.]"