Answer:
Problem 1: Given initial volume of gas (V1) at 45°C, find the volume of the gas (V2) at 0°C, assuming constant pressure.
Problem 2: Given initial volume of gas (V1) at 27°C and 700 mmHg, find the pressure of the gas (P2) at 45°C and 780 mmHg.
Step-by-step explanation:
simplify the following: cos340°. sin385 ° + cos(−25°) . sin160 °
The simplified solution of cos340°. sin385 ° + cos(−25°) . sin160 ° is: 0.707.
Here, we have,
given that,
cos340°. sin385 ° + cos(−25°) . sin160 °
we have to Simplify the following:
now, we have,
cos 340° = 0.9397.
The sin of 385 degrees is 0.42262.
The value of cos -25° is equal to the x-coordinate (0.9063).
∴cos-25° = 0.90631
The value of sin 160° is equal to 0.342.
so, we get,
0.9397 × 0.42262 + 0.90631 × 0.342
=0.3971 + 0.3099
=0.707
Hence, The simplified solution of cos340°. sin385 ° + cos(−25°) . sin160 ° is: 0.707.
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According to the 2010 census, Chicago is the third-largest city in the United States. In 2011, its population was 2,707,000, an increase of 0.4% compared to the previous year. a. Assuming that the populations of Chicago and Houston are growing exponentially, write an equation that can be used to predict when the population of Houston will equal that of Chicago. b. Solve your equation. For each step, list a property or give an explanation. Then interpret the solution.
a. An equation that can be used to predict when the population of Houston will equal that of Chicago is [tex]$2.145 \cdot 1.022^x=2.707 \cdot 1.004^x$[/tex]
b. The population will be the same at some point during the year of 2011+13 = 2024.
What is population increase?Pοpulatiοn grοwth is the increase in the number οf humans οn Earth. Fοr mοst οf human histοry οur pοpulatiοn size was relatively stable.
a.
Let g(x) represent the population of Chicago in millions, x years after 2011. If the population of Chicago grows at 0.4 % each year, then the population is multiplied by 1.004 every year.
Thus
[tex]g(x)=2.707 \cdot \underbrace{1.004 \cdot 1.004 \cdots 1.004}_{x \text { times }}=2.707 \cdot 1.004^x[/tex]
we found f(x) as
[tex]f(x)=2.145 \cdot 1.022^x[/tex]
to represent the population of Houston. Then the populations will be equal when f(x)=g(x), or
[tex]2.145 \cdot 1.022^x=2.707 \cdot 1.004^x[/tex]
b.
There are several ways to solve this equation. Here is an example:
[tex]$$\begin{gathered}2.145 \cdot 1.022^x=2.707 \cdot 1.004^x \\\log \left[2.145 \cdot 1.022^x\right]=\log \left[2.707 \cdot 1.004^x\right] \\\log 2.145+\log 1.022^x=\log 2.707+\log 1.004^x \\\log 2.145+x \log 1.022=\log 2.707+x \log 1.004 \\x \log 1.022-x \log 1.004=\log 2.707-\log 2.145 \\x(\log 1.022-\log 1.004)=\log 2.707-\log 2.145 \\x=\frac{\log 2.707-\log 2.145}{\log 1.022-\log 1.004} \\x \approx 13.10\end{gathered}$$[/tex]
As x represents the number of years after 2011, then we conclude the population will be the same at some point during the year of 2011+13 = 2024.
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which of the following situations can be modeled by a function whose value changes at a constant rate per unit of time? select all that apply. a the population of a city is increasing 5% per year. b the water level of a tank falls by 5 gallons every day. c the number of reptiles in the zoo increases by 5 reptiles each year. d the amount of money collected by a charity increases by 5 times each year.
b) The water level of a tank falls by 5 gallons every day.
c) The number of reptiles in the zoo increases by 5 reptiles each year.
In both scenarios, the values change by a fixed amount consistently over a specific unit of time, indicating a constant rate of change.
The situations that can be modeled by a function whose value changes at a constant rate per unit of time are:
a) The population of a city is increasing 5% per year. This scenario represents a constant growth rate over time, where the population changes by a fixed percentage annually.
b) The water level of a tank falls by 5 gallons every day. Here, the water level decreases by a fixed amount (5 gallons) consistently each day.
c) The number of reptiles in the zoo increases by 5 reptiles each year. This situation represents a constant annual increase in the reptile population, with a fixed number of reptiles being added each year.
These three scenarios involve changes that occur at a constant rate per unit of time, making them suitable for modeling using a function with a constant rate of change.
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Question 8(Multiple Choice Worth 10 points) (07.01 MC) Select the possible solution(s) to the differential equation (4a + 2) dt 3. 1. 4at + 2at = 3t-C II 11.2-C =t III. 2a + 2a = 3a + 2 01 O11 OI and
The possible solution(s) to the given differential equation (4a + 2) da/dt = 3 are: D - 1 and 3
To solve the given differential equation (4a + 2) da/dt = 3, we can separate the variables and integrate both sides.
Starting with the given equation:
(4a + 2) da/dt = 3
Dividing both sides by (4a + 2):
da/dt = 3 / (4a + 2)
Now, we can separate variables by multiplying both sides by dt and dividing by 3:
da / (4a + 2) = dt / 3
Integrating both sides, we get:
∫ da / (4a + 2) = ∫ dt / 3
The integral of the left side can be solved using a substitution or by using partial fractions, depending on the complexity of the integrand. After integrating both sides, we obtain the possible solutions for the equation.
1. Solution 1: 4at + 2at = 3t + c, where c is the constant of integration.
2. Solution 2: 2/3a² + 2/3a + c = t, where c is the constant of integration.
3. Solution 3: 2a² + 2a = 3a + 2
Comparing the possible solutions with the given options, option D (1 and 3) is the correct answers.
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the complete question is:
Select the possible solution(s) to the differential equation (4a + 2) da/dt = 3
1- 4at + 2at = 3t-c
2- 2/3a^2 + 2/3a + c = t
3- 2a^2 + 2a = 3a + 2
A- 1
B - 2
C- 1 and 2
D - 1 and 3
Question 8
8. DETAILS LARCALC11 9.5.013.MI. Determine the convergence or divergence of the series. (If you need to use coorco, enter INFINITY or -INFINITY, respectively.) 00 (-1)"(8n - 1) 5 + 1 n = 1 8n - 1 lim
To determine the convergence or divergence of the series Σ[tex]((-1)^{n+1}/ (8n - 1)^{5+1})[/tex], n = 1 to ∞, we need to find the limit of the general term of the series as n approaches infinity.
Let's analyze the general term of the series, given by [tex]a_n = (-1)^{(n+1} ) / (8n - 1)^{5+1}[/tex].
As n approaches infinity, we can observe that the denominator [tex](8n - 1)^{5 + 1}[/tex] becomes larger and larger, while the numerator (-1)^(n+1) alternates between -1 and 1.
Since the series is an alternating series, we can apply the Alternating Series Test to determine its convergence or divergence. The test states that if the absolute values of the terms decrease monotonically to zero as n approaches infinity, then the series converges.
In this case, the denominator increases without bound, while the numerator alternates between -1 and 1. As a result, the absolute values of the terms do not approach zero. Therefore, the series diverges.
Hence, the series Σ[tex]((-1)^{n+1} ) / (8n - 1)^{5+1})[/tex] is divergent.
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Suppose that a population P(t) follows the following Gompertz differential equation. dP = 5P(16 - In P), dt with initial condition P(0) = 50. (a) What is the limiting value of the population? (b) What
the population will approach and stabilize at approximately 8886110.52 individuals, assuming the Gompertz differential equation accurately models the population dynamics.
The Gompertz differential equation is given by dP/dt = 5P(16 - ln(P)), where P(t) represents the population at time t. To find the limiting value of the population, we need to solve the differential equation and find its equilibrium solution, which occurs when dP/dt = 0.Setting dP/dt = 0 in the Gompertz equation, we have 5P(16 - ln(P)) = 0. This equation holds true when P = 0 or 16 - ln(P) = 0.Firstly, if P = 0, it implies an extinction of the population, which is not a meaningful solution in this case.
To find the non-trivial equilibrium solution, we solve the equation 16 - ln(P) = 0 for P. Taking the natural logarithm of both sides gives ln(P) = 16, and solving for P yields P = e^16.Therefore, the limiting value of the population is e^16, approximately equal to 8886110.52.
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2. Minimise the function f(21,02) = (6 - 4x12 + (3.02 + 5)2 subject to X2 >e" Hint: The equations 16 In(r) -24 +9p2 + 15r = 0 16r - 24 +9e2r + 15e" = 0 each have only one real root.
The minimum value of the function f(21,02) = (6 - 4x12 + (3.02 + 5)2 subject to X2 > e is subject to the given constraints.
To minimize the function f(21,02) = (6 - 4x12 + (3.02 + 5)2, we need to find the values of x and e that satisfy the given constraints. The constraint X2 > e suggests that the value of x squared must be greater than e.
Additionally, we are given two equations: 16ln(r) - 24 + 9p2 + 15r = 0 and 16r - 24 + 9e2r + 15e" = 0. It is stated that each of these equations has only one real root.
To find the minimum value of the function f, we need to solve the system of equations and identify the real root. Once we have the values of x and e, we can substitute them into the function and calculate the minimum value.
By utilizing appropriate mathematical techniques such as substitution or numerical methods, we can solve the equations and find the real root. Then, we can substitute the obtained values of x and e into the function f(21,02) to calculate the minimum value.
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dt Canvas Golden West College MyGWC S * D Question 15 Use Part 1 of the Fundamental Theorem of Calculus to find the derivative of the function. dt © &(a)= (5-5) ° 8(a)= (9-4) © & (9) - (9-9")' (a)=
The derivative of the given function F(a) = ∫[5 to a] 8(t) dt, using Part 1 of the Fundamental Theorem of Calculus, is F'(a) = (9 - 4a) © (9a).
The derivative of the given function can be found using Part 1 of the Fundamental Theorem of Calculus, which states that if a function is defined as the integral of another function, then its derivative can be found by evaluating the integrand at the upper limit of integration and multiplying by the derivative of the upper limit with respect to the variable. In this case, let's consider the function F(a) = ∫[5 to a] 8(t) dt, where 8(t) = (9 - 4t) © (9t). We want to find F'(a), the derivative of F(a) with respect to a.
By applying Part 1 of the Fundamental Theorem of Calculus, we evaluate the integrand 8(t) at the upper limit of integration, which is a, and then multiply by the derivative of the upper limit with respect to a, which is 1.
Therefore, F'(a) = 8(a) * 1 = (9 - 4a) © (9a).
In summary, the derivative of the given function F(a) = ∫[5 to a] 8(t) dt, using Part 1 of the Fundamental Theorem of Calculus, is F'(a) = (9 - 4a) © (9a).
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please solve this question.
Answer:
2 < x
Step-by-step explanation:
the little circle on 2 is not filled, which means we do not include 2. if it was filled (darkened circle) we include this endpoint.
so, x > 2. in other word 2 < x.
Question 8 G0/10 pts 3 99 Details 23 Use Simpson's Rule and all the data in the following table to estimate the value of the integral 1 f(a)da. X 5 f(x) 8 3 12 برابر 8 11 14 17 20 23 11 15 6 13 2
Using Simpson's Rule, the estimated value of the integral ∫f(a)da is 89.
Simpson's Rule is a numerical integration method that approximates the value of an integral by dividing the interval into subintervals and using a quadratic polynomial to interpolate the function within each subinterval. The table provides the values of f(x) at different points. To apply Simpson's Rule, we group the data into pairs of subintervals. Using the formula for Simpson's Rule, we calculate the estimated value of the integral to be 89. This is obtained by multiplying the common interval width (5) by one-third of the sum of the first and last function values (11+15), and adding to it four times one-third of the sum of the function values at the odd indices (6+2+13).
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2 f(x) = x^ - 15; Xo = 4 x К ХК k xk 0 6 1 7 2 8 W N 3 9 4 10 5 (Round to six decimal places as needed.)
To find the values of f(x) for the given function [tex]f(x) = x^{-15}[/tex], we need to substitute the given values of x into the function.
Using the values of x from 0 to 5, we can calculate f(x) as follows:
For x = 0: [tex]f(0) = 0^{-15}[/tex] = undefined (since any number raised to the power of -15 is undefined)
For x = 1: f(1) = [tex]1^{-15}[/tex] = 1
For x = 2: f(2) = [tex]2^{-15}[/tex] = 0.0000305176
For x = 3: f(3) =[tex]3^{-15}[/tex] = 2.7750e-23
For x = 4: f(4) = [tex]4^{-15}[/tex] = 1.5259e-28
For x = 5: f(5) = [tex]5^{-15}[/tex] = 3.0518e-34
Rounding these values to six decimal places, we have:
f(0) = undefined
f(1) = 1
f(2) = 0.000031
f(3) = 2.7750e-23
f(4) = 1.5259e-28
f(5) = 3.0518e-34
These are the calculated values of f(x) for the given function and corresponding values of x from 0 to 5.
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the arithmetic mean of four numbers is 15. two of the numbers are 10 and 18 and the other two are equal. what is the product of the two equal numbers?
The arithmetic mean of four numbers is 15. two of the numbers are 10 and 18 and the other two are equal. So the product of the two equal numbers is 256.
To find the arithmetic mean of four numbers, you add them all up and then divide by four. So if the mean is 15 and two of the numbers are 10 and 18, then the sum of all four numbers must be:
15 x 4 = 60
We know that two of the numbers are 10 and 18, which add up to 28. So the sum of the other two numbers must be:
60 - 28 = 32
Since the other two numbers are equal, we can call them x. So:
2x = 32
x = 16
Therefore, the two equal numbers are both 16, and their product is:
16 x 16 = 256
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If [ f(x) 1 /(x) f(x) dx = 35 and g(x) dx = 12, find Sº [2f(x) + 3g(x)] dx.
The problem involves finding the value of the integral Sº [2f(x) + 3g(x)] dx, given that the integral of f(x) / x f(x) dx is equal to 35 and the integral of g(x) dx is equal to 12.
To solve this problem, we can use linearity and the properties of integrals.
Linearity states that the integral of a sum is equal to the sum of the integrals. Therefore, we can split the integral Sº [2f(x) + 3g(x)] dx into two separate integrals: Sº 2f(x) dx and Sº 3g(x) dx.
Given that the integral of f(x) / x f(x) dx is equal to 35, we can substitute this value into the integral Sº 2f(x) dx. So, Sº 2f(x) dx = 2 * 35 = 70.
Similarly, given that the integral of g(x) dx is equal to 12, we can substitute this value into the integral Sº 3g(x) dx. So, Sº 3g(x) dx = 3 * 12 = 36.
Finally, we can add the results of the two integrals: 70 + 36 = 106. Therefore, the value of the integral Sº [2f(x) + 3g(x)] dx is 106.
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Find the intervals on which fis increasing and the intervals on which it is decreasing. f(x) = 10-x? Select the correct choice below and, if necessary, fill in the answer box(es) to complete your choice. A. The function is increasing on the open interval(s) and decreasing on the open interval(s) (Simplify your answers. Type your answers in interval notation. Use a comma to separate answers as needed.) B. The function is increasing on the open interval(s). The function is never decreasing. (Simplify your answer. Type your answer in interval notation. Use a comma to separate answers as needed.) The function is decreasing on the open interval(s). The function is never increasing. (Simplify your answer. Type your answer in interval notation. Use a comma to separate answers as needed.) D. The function is never increasing nor decreasing.
For the given function f(x) = 10 - x, the function is never increasing. (option c)
To determine the intervals on which the function is increasing or decreasing, we need to examine the slope of the function. The slope of a function represents the rate at which the function is changing. In this case, the slope of f(x) = 10 - x is -1, which means that the function is decreasing at a constant rate of 1 as we move along the x-axis.
Since the slope is negative (-1), the function is always decreasing. This means that the function f(x) = 10 - x is decreasing on the entire domain. Therefore, we can conclude that the function is never increasing.
The correct answer choice for this question is C. The function is never increasing.
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Homework: 12.2 Question 4, 12.2.29 Part 1 of 2 Find the largest open intervals on which the function is concave upward or concave downward, and find the location of any points of inflection 1 f(x)= X-9 Select the correct choice below and fill in the answer boxes to complete your choice (Type your answer in interval notation. Use a comma to separate answers as needed. Use integers or fractions for any numbers in the expression) O A. The function is concave upward on and concave downward on B. The function is concave downward on There are no intervals on which the function is concave upward C. The function is concave upward on There are no intervals on which the function is nca downward
There are no intervals on which the function f(x) is concave upward or concave downward.
to determine the intervals on which the function f(x) = x - 9 is concave upward or concave downward, we need to analyze its second derivative.
the first derivative of f(x) is f'(x) = 1, and the second derivative is f''(x) = 0.
since the second derivative f''(x) = 0 is constant, it does not change sign. in other words, the function f(x) = x - 9 is neither concave upward nor concave downward, as the second derivative is identically zero.
hence, the correct choice is:
c. the function is concave upward on ∅ (empty set).there are no intervals on which the function is concave downward.
please note that in this case, the function is a simple linear function, and it does not exhibit any curvature or inflection points.
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Find the equation of the tangent line to the graph
of x3 + y4 = y + 1
at the point (−1, −1).
The equation of the tangent line to the graph of x^3 + y^4 = y + 1 at the point (-1, -1) is 3x - 5y = 2.
To find the equation of the tangent line to the graph of the equation x^3 + y^4 = y + 1 at the point (-1, -1), we can use the concept of implicit differentiation.
1. Start by differentiating both sides of the equation with respect to x:
d/dx(x^3 + y^4) = d/dx(y + 1)
2. Differentiating each term:
3x^2 + 4y^3(dy/dx) = dy/dx
3. Substitute the coordinates of the point (-1, -1) into the equation:
3(-1)^2 + 4(-1)^3(dy/dx) = dy/dx
Simplifying the equation:
3 - 4(dy/dx) = dy/dx
4. Move the dy/dx terms to one side of the equation:
3 = 5(dy/dx)
5. Solve for dy/dx:
dy/dx = 3/5
Now we have the slope of the tangent line at the point (-1, -1), which is dy/dx = 3/5.
6. Use the point-slope form of a linear equation to find the equation of the tangent line:
y - y1 = m(x - x1), where (x1, y1) is the point on the line and m is the slope.
Substituting the values into the equation:
y - (-1) = (3/5)(x - (-1))
Simplifying:
y + 1 = (3/5)(x + 1)
7. Convert the equation to the standard form:
5y + 5 = 3x + 3
Rearrange:
∴ 3x - 5y = 2
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= (8 points) Find the maximum and minimum values of f(2, y) = fc +y on the ellipse 22 + 4y2 = 1 maximum value minimum value:
The maximum value of f(2, y) = fc + y on the ellipse 22 + 4y2 = 1 is 1.5, and the minimum value is -0.5.
To find the maximum and minimum values of f(2, y) on the given ellipse, we substitute the equation of the ellipse into f(2, y). This gives us f(2, y) = fc + y = 1 + y. Since the ellipse is centered at (0,0) and has a major axis of length 1, its maximum and minimum values occur at the points where y is maximized and minimized, respectively. Plugging these values into f(2, y) gives us the maximum of 1.5 and the minimum of -0.5.
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(1 point) Let S(x) = 4(x - 2x for x > 0. Find the open intervals on which ſ is increasing (decreasing). Then determine the x-coordinates of all relative maxima (minima). I 1. ſ is increasing on the
The function S(x) = 4(x - 2x) for x > 0 is increasing on the open interval (0, +∞) and does not have any relative maxima or minima.
To determine the intervals on which S(x) is increasing or decreasing, we need to examine the derivative of S(x). Taking the derivative of S(x) with respect to x, we get:
S'(x) = 4(1 - 2) = -4
Since the derivative is a constant (-4) and negative, it means that S(x) is decreasing for all values of x. Therefore, S(x) does not have any relative maxima or minima.
In terms of intervals, the function S(x) is decreasing on the entire domain of x > 0, which means it is decreasing on the open interval (0, +∞). Since it is always decreasing and does not have any turning points, there are no relative maxima or minima to be found.
In summary, the function S(x) = 4(x - 2x) for x > 0 is increasing on the open interval (0, +∞), and it does not have any relative maxima or minima.
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Rewrite y = 9/2x +5 in standard form.
The equation y = 9/2x + 5 can be rewritten in standard form as 9x - 2y = -10. The standard form of a linear equation is Ax + By = C, where A, B, and C are constants and A is typically positive.
In standard form, the equation of a line is typically written as Ax + By = C, where A, B, and C are constants. To convert y = (9/2)x + 5 into standard form, we start by multiplying both sides of the equation by 2 to eliminate the fraction. This gives us 2y = 9x + 10.
Next, we rearrange the equation to have the variables on the left side and the constant term on the right side. We subtract 9x from both sides to get -9x + 2y = 10. The equation -9x + 2y = 10 is now in standard form, where A = -9, B = 2, and C = 10. In summary, the equation y = (9/2)x + 5 can be rewritten in standard form as -9x + 2y = 10.
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Question * Let R be the region in the first quadrant bounded above by the parabola y = 4 x² and below by the line y = 1. Then the area of R is: None of these √√3 units squared This option 6 units
The area of region R is 1/3 units squared. None of the given options match this result, so the correct answer is "None of these."
To find the area of the region R bounded by the parabola y = 4[tex]x^{2}[/tex] and the line y = 1, we need to determine the points of intersection between these two curves.
First, let's set the equations equal to each other and solve for x:
4[tex]x^{2}[/tex]=1
Divide both sides by 4:
[tex]x^{2}[/tex] = 1/4
Taking the square root of both sides, we get:
x = ±1/2
Since we're only interested in the region in the first quadrant, we consider the positive solution:
x = 1/2
Now, we can integrate to find the area. We integrate the difference between the curves with respect to x, from 0 to 1/2:
∫[0 to 1/2] (4[tex]x^{2}[/tex] - 1) dx
Integrating the above expression:
[4/3∗x3−x]from0to1/2
=(4/3∗(1/2)3−1/2)−(0−0)
=(4/3∗1/8−1/2)
=1/6−1/2
=−1/3
Since the area cannot be negative, we take the absolute value:
|-1/3| = 1/3
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Find the critical numbers and then say where the function is increasing and where it is decreasing.
y = x^4/5 + x^9/5
a. The critical numbers of the function y = x⁴/⁵ + x⁹/⁵ are (-4/9, 10√8/9)
b. The function is decreasing
What are the critical numbers of a function?The critical number of a function are the maximum or minimum points of the curve.
a. To find the critical numbers of the function y = x⁴/⁵ + x⁹/⁵,we proceed as follows
To find the critical numbers of the function, we differentiate the function with respect to x and equate to zero.
So, y = x⁴/₅ + x⁹/₅
dy/dx = d(x⁴/₅)/dx + d(x⁹/₅)/dx
= (4/5)x⁻¹/₅ + (9/5)x⁻⁴/⁵
Equating it to zero, we have that
dy/dx = 0
(4/5)x⁻¹/₅ + (9/5)x⁻⁴/⁵ = 0
(4/5)x⁻¹/₅ = -(9/5)x⁻⁴/⁵
Dividing both sides by 4/5, we have
(4/5)x⁻¹/₅/(4/5) = -(9/5)x⁻⁴/⁵/(4/5)
x⁻¹/₅ = -(9/4)x⁻⁴/⁵
Dividing both sides by x⁻⁴/⁵, we have that
x⁻¹/₅/ x⁻⁴/⁵ = -(9/4)x⁻⁴/⁵/ x⁻⁴/⁵
x⁻¹ = -9/4
x = -4/9
So, substituting x = -4/9 into the equation for y, we have that
y = (-4/9)⁴/₅ + (-4/9)⁹/₅
y = (-4/9)⁴/₅[1 + (-4/9)⁵/₅]
y = (-4/9)⁴/₅[1 + (-4/9)]
y = (-4/9)⁴/₅[1 - 4/9)]
y = (-4/9)⁴/₅[(9 - 4)/9)]
y = (-4/9)⁴/₅[5/9)]
y =⁵√ (256/6561)[5/9)]
y =⁵√ (256/59049)[5]
y =2√8/9 × [5]
y =10√8/9
So, the critical numbers are (-4/9, 10√8/9)
b. To determine whether the function is increasing or decreasing, we differentiate its first derivative and substitute in the value of x. so,
dy/dx = (4/5)x⁻¹/₅ + (9/5)x⁻⁴/⁵
d(dy/dx) = d[(4/5)x⁻¹/₅ + (9/5)x⁻⁴/⁵]/dx
d²y/dx² = d[(4/5)x⁻¹/₅]dx + d[(9/5)x⁻⁴/⁵]/dx
d²y/dx² = -1/5 × (4/5)x⁻⁶/₅]dx + -4/5 × [(9/5)x⁻⁹/⁵]/dx
= -(4/25)x⁻⁶/₅ - (36/25)x⁻⁹/⁵
Substituting in the value of x = -4/9, we have that
d²y/dx² = -(4/25)x⁻⁶/₅ - (36/25)x⁻⁹/⁵
= -(4/25)(-4/9)⁻⁶/₅ - (36/25)(-4/9)⁻⁹/⁵
= (4/25)(9/4)⁶/₅ + (36/25)(9/4)⁹/⁵
= (4/25)(531441/4096)¹/₅ + (36/25)(387420489/262144)¹/⁵
= (4/25)(9⁵√9/4⁵√4) + (36/25)(9⁵√9⁴/16)
= (1/25)(9⁵√9/4⁴√4) + (36/25)(9⁵√9⁴/16)
= 9⁵√9/4⁴[1/2 + 36/25 × 27]
= 9⁵√9/4⁴[25 + 1944]/50]
= 9⁵√9/4⁴[1969]/50]
Since d²y/dx² = 9⁵√9/4⁴[1969]/50] > 0,
The function is decreasing
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Raul’s car averages 17.3 miles per gallon of gasoline. How many miles can Raul drive if he fills his tank with 10.5 gallons of gasoline
Answer:
181.65 miles
Step-by-step explanation:
17.3 mpg, where g is gallons
so we need 17.3 X 10.5
= 181.65
.The variables x and y vary inversely. Use the given values to write an equation relating x and y. Then find y when x = 3. x = 1, y = 9
The given problem states that x and y vary inversely, and by using the given values, an equation is formed (x * y = 9) which can be used to find y when x = 3 (y = 3).
Since x and y vary inversely, we can write the equation as x * y = k, where k is a constant.
Using the given values x = 1 and y = 9, we can substitute them into the equation to find the value of k:
1 * 9 = k
k = 9
Therefore, the equation relating x and y is x * y = 9.
To find y when x = 3, we substitute x = 3 into the equation:
3 * y = 9
y = 9 / 3
y = 3
So, when x = 3, y = 3.
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3. A particle starts moving from the point (2,1,0) with velocity given by v(t) = (2t, 2t - 1,2 - 4t), where t > 0. (a) (3 points) Find the particle's position at any time t. (b) (4 points) What is the cosine of the angle between the particle's velocity and acceleration vectors when the particle is at the point (6,3,-4)? (c) (3 points) At what time(s) does the particle reach its minimum speed?
a) The position function is x(t) = t^2 + 2, y(t) = t^2 - t + 1, z(t) = 2t - 2t^2
b) Tthe cosine of the angle between the velocity and acceleration vectors at the point (6, 3, -4) is: cosθ = (v(6) · a(6)) / (|v(6)| |a(6)|) = 134 / (sqrt(749) * sqrt(24))
c) The particle reaches its minimum speed at t = 1/12.
(a) To find the particle's position at any time t, we need to integrate the velocity function with respect to time. The position function can be obtained by integrating each component of the velocity vector.
Given velocity function: v(t) = (2t, 2t - 1, 2 - 4t)
Integrating the x-component:
x(t) = ∫(2t) dt = t^2 + C1
Integrating the y-component:
y(t) = ∫(2t - 1) dt = t^2 - t + C2
Integrating the z-component:
z(t) = ∫(2 - 4t) dt = 2t - 2t^2 + C3
where C1, C2, and C3 are constants of integration.
Now, to determine the specific values of the constants, we can use the initial position given as (2, 1, 0) when t = 0.
x(0) = 0^2 + C1 = 2 --> C1 = 2
y(0) = 0^2 - 0 + C2 = 1 --> C2 = 1
z(0) = 2(0) - 2(0)^2 + C3 = 0 --> C3 = 0
Therefore, the position function is:
x(t) = t^2 + 2
y(t) = t^2 - t + 1
z(t) = 2t - 2t^2
(b) To find the cosine of the angle between the velocity and acceleration vectors, we need to find both vectors at the given point (6, 3, -4) and then calculate their dot product.
Given velocity function: v(t) = (2t, 2t - 1, 2 - 4t)
Given acceleration function: a(t) = (d/dt) v(t) = (2, 2, -4)
At the point (6, 3, -4), let's find the velocity and acceleration vectors.
Velocity vector at t = 6:
v(6) = (2(6), 2(6) - 1, 2 - 4(6)) = (12, 11, -22)
Acceleration vector at t = 6:
a(6) = (2, 2, -4)
Now, let's calculate the dot product of the velocity and acceleration vectors:
v(6) · a(6) = (12)(2) + (11)(2) + (-22)(-4) = 24 + 22 + 88 = 134
The magnitude of the velocity vector at t = 6 is:
|v(6)| = sqrt((12)^2 + (11)^2 + (-22)^2) = sqrt(144 + 121 + 484) = sqrt(749)
The magnitude of the acceleration vector at t = 6 is:
|a(6)| = sqrt((2)^2 + (2)^2 + (-4)^2) = sqrt(4 + 4 + 16) = sqrt(24)
Therefore, the cosine of the angle between the velocity and acceleration vectors at the point (6, 3, -4) is:
cosθ = (v(6) · a(6)) / (|v(6)| |a(6)|) = 134 / (sqrt(749) * sqrt(24))
(c) To find the time(s) when the particle reaches its minimum speed, we need to determine when the magnitude of the velocity vector is at its minimum.
Given velocity function: v(t) = (2t, 2t - 1, 2 - 4t)
The magnitude of the velocity vector is:
|v(t)| = sqrt((2t)^2 + (2t - 1)^2 + (2 - 4t)^2) = sqrt(4t^2 + 4t^2 - 4t + 1 + 4 - 16t + 16t^2)
= sqrt(24t^2 - 4t + 5)
To find the minimum speed, we can take the derivative of |v(t)| with respect to t and set it equal to 0, then solve for t.
d|v(t)| / dt = 0
(1/2) * (24t^2 - 4t + 5)^(-1/2) * (48t - 4) = 0
Simplifying:
48t - 4 = 0
48t = 4
t = 1/12
Therefore, the particle reaches its minimum speed at t = 1/12.
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thank you!
Find the following derivative (you can use whatever rules we've learned so far): d -(5 sin(t) + 2 cos(t)) dt Explain in a sentence or two how you know, what method you're using, etc.
The derivative of the function (-(5 sin(t) + 2 cos(t))) is given by :
-5 cos(t) + 2 sin(t)
To find the derivative of the given function, we will use the basic differentiation rules for sine and cosine functions.
The given function is :
(-(5 sin(t) + 2 cos(t)))
The derivative of this given function is:
d(-(5 sin(t) + 2 cos(t)))/dt = -5 d(sin(t))/dt - 2 d(cos(t))/dt
Applying the rules, we get:
-5(cos(t)) - 2(-sin(t))
So, the derivative of the given function is -5 cos(t) + 2 sin(t).
We used the rules:
d(sin(t))/dt = cos(t) and d(cos(t))/dt = -sin(t) to find the derivative of the given function.
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Find the radius of convergence, R, of the series.
[infinity] 3(−1)nnxn
sum.gif
n = 1
R =
Find the interval, I, of convergence of the series. (Enter your answer using interval notation.)
I =
The series is given by the expression ∑[infinity] 3(−1)nnxn, n = 1. The task is to find the radius of convergence, R, and the interval of convergence, I, for the series.
To find the radius of convergence, we can use the ratio test. Let's apply the ratio test to the series:
lim(n→∞) [tex]|\frac{(3(-1)^{(n+1)} * (n+1) * x^{(n+1)}}{ (3(-1)^n * n * x^n)} |[/tex]
Simplifying the expression, we get:
lim(n→∞) [tex]|\frac{(3(-1)^{(n+1)} * (n+1) * x^{(n+1)}}{ (3(-1)^n * n * x^n)} |[/tex]
= lim(n→∞) |(3 * (n+1) * x) / (n * x)|
= lim(n→∞) |3 * (n+1) / n|
= 3.
For the series to converge, the ratio should be less than 1. Therefore, |3| < 1, which is not true. Hence, the series diverges for all values of x. Consequently, the radius of convergence, R, is 0.
Since the series diverges for all x, the interval of convergence, I, is empty, represented by the notation I = {}.
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Calculate the following improper integrals! 7/2 +oo 1 3x² + 4 dx (5.1) | (5.2) / tan(x) dx 0
To calculate the improper integrals, we need to evaluate the integrals of the given functions over their respective intervals.
The first integral involves the function f(x) = 3x^2 + 4, and the interval is from 7/2 to positive infinity. The second integral involves the function g(x) = tan(x), and the interval is from 5.1 to 5.2.
For the first integral, ∫(7/2 to +oo) (3x^2 + 4) dx, we consider the limit as the upper bound approaches infinity. We rewrite the integral as ∫(7/2 to R) (3x^2 + 4) dx, where R is a variable representing the upper bound. We then calculate the integral as the antiderivative of the function 3x^2 + 4, which is x^3 + 4x. Next, we evaluate the integral from 7/2 to R and take the limit as R approaches infinity. By plugging in the upper and lower bounds into the antiderivative and taking the limit, we can determine if the integral converges or diverges.
For the second integral, ∫(5.1 to 5.2) tan(x) dx, we evaluate the integral directly. The integral of tan(x) is -ln|cos(x)|. We substitute the upper and lower bounds into the antiderivative and calculate the difference. This will give us the value of the integral over the given interval.
By following these steps, we can determine the values of the improper integrals and determine if they converge or diverge.
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Find the midpoint of the line connected by A(4, 5) and B(2, -8) and reduce to simplest form.
The midpoint of the line segment connecting points A(4, 5) and B(2, -8) can be found by taking the average of the x-coordinates and the average of the y-coordinates. The midpoint will be in the form (x, y).
To find the x-coordinate of the midpoint, we add the x-coordinates of A and B and divide by 2:
x = (4 + 2) / 2 = 6 / 2 = 3.
To find the y-coordinate of the midpoint, we add the y-coordinates of A and B and divide by 2:
y = (5 + (-8)) / 2 = -3 / 2 = -1.5.
Therefore, the midpoint of the line segment AB is (3, -1.5). To express it in simplest form, we can write it as (3, -3/2).
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calculate the average height above the x-axis of a point in the region 0≤x≤a, 0≤y≤x² for a=13.
To calculate the average height above the x-axis of a point in the region 0≤x≤a, 0≤y≤x² for a=13, we need to find the average value of the function y=x² over the interval [0, 13]. Therefore, the average height above the x-axis of a point in the region 0≤x≤13, 0≤y≤x² is approximately 56.33.
The average height above the x-axis can be found by evaluating the definite integral of the function y=x² over the given interval [0, 13] and dividing it by the length of the interval. In this case, the length of the interval is 13 - 0 = 13.
To find the average height, we calculate the integral of x² with respect to x over the interval [0, 13]:
∫(0 to 13) x² dx = [x³/3] (0 to 13) = (13³/3 - 0³/3) = 2197/3.
To find the average height, we divide this value by the length of the interval:
Average height = (2197/3) / 13 = 2197/39 ≈ 56.33.
Therefore, the average height above the x-axis of a point in the region 0≤x≤13, 0≤y≤x² is approximately 56.33.
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Q6
Find the image of 12 + pi + 2p1 = 4 under the mapping w = pvz (e/) z.
The image of the equation 12 + pi + 2p1 = 4 under the mapping w = pvz (e/) z can be determined by evaluating the expression. The answer will be explained in detail in the following paragraphs.
To find the image of the equation, we need to substitute the given expression w = pvz (e/) z into the equation 12 + pi + 2p1 = 4. Let's break it down step by step.
First, let's substitute the value of w into the equation:
pvz (e/) z + pi + 2p1 = 4
Next, we simplify the equation by combining like terms:
pvz (e/) z + pi + 2p1 = 4
pvz (e/) z = 4 - pi - 2p1
Now, we have the simplified equation after substituting the given expression. To evaluate the image, we need to calculate the value of the right-hand side of the equation.
The final answer will depend on the specific values of p, v, and z provided in the context of the problem. By substituting these values into the expression and performing the necessary calculations, we can determine the image of the equation under the given mapping.
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