The specific heat capacity of the metal sample is 0.416 cal/g·°C. This value represents the amount of heat energy required to raise the temperature of one gram of the metal by one degree Celsius.
To determine the specific heat capacity of the metal sample, we can use the equation:
q = m * c * ΔT
Where:
q is the heat energy absorbed by the metal sample,
m is the mass of the metal sample,
c is the specific heat capacity of the metal, and
ΔT is the change in temperature.
Given:
m = 25.0 g (mass of the metal sample)
ΔT = (72.5°C - 52.5°C) = 20.0°C (change in temperature)
q = 130.0 cal (heat energy absorbed by the metal sample)
Rearranging the equation, we can solve for c:
c = q / (m * ΔT)
= 130.0 cal / (25.0 g * 20.0°C)
≈ 0.416 cal/g·°C
The specific heat capacity of the metal sample is approximately 0.416 cal/g·°C. This value represents the amount of heat energy required to raise the temperature of one gram of the metal by one degree Celsius.
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Guess A Particular Solution Up To U2+2xuy=2x2 And Then Write The General Solution.
To guess a particular solution up to the term involving the highest power of u and its derivatives, we assume that the particular solution has the form:
u_p = a(x) + b(x)y
where a(x) and b(x) are functions to be determined.
Substituting this into the given equation:
u^2 + 2xu(dy/dx) = 2x^2
Expanding the terms and collecting like terms:
(a + by)^2 + 2x(a + by)(dy/dx) = 2x^2
Expanding further:
a^2 + 2aby + b^2y^2 + 2ax(dy/dx) + 2bxy(dy/dx) = 2x^2
Comparing coefficients of like terms:
a^2 = 0 (coefficient of 1)
2ab = 0 (coefficient of y)
b^2 = 0 (coefficient of y^2)
2ax + 2bxy = 2x^2 (coefficient of x)
From the equations above, we can see that a = 0, b = 0, and 2ax = 2x^2.
Solving the last equation for a particular solution:
2ax = 2x^2
a = x
Therefore, a particular solution up to u^2 + 2xuy is:
u_p = x
To find the general solution, we need to add the homogeneous solution. The given equation is a first-order linear PDE, so the homogeneous equation is:
2xu(dy/dx) = 0
This equation has the solution u_h = C(x), where C(x) is an arbitrary function of x.
Therefore, the general solution to the given PDE is:
u = u_p + u_h = x + C(x)
where C(x) is an arbitrary function of x.
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Let X represent the full height of a certain species of tree. Assume that X has a normal probability distribution with μ = 183.2 ft and σ = 3.8 ft. You intend to measure a random sample of n = 116 trees.
What is the mean of the distribution of sample means? μ ¯ x =
What is the standard deviation of the distribution of sample means (i.e., the standard error in estimating the mean)? (Report answer accurate to 4 decimal places.) σ ¯ x =
This means that we can expect the mean of the sample means to be very close to the population mean, with an error of about 0.35 ft.
The distribution of sample means is normal as the sample size n is large. The mean of the distribution of sample means is the same as the population mean, which is μ = 183.2 ft.
The standard deviation of the distribution of sample means, also known as the standard error in estimating the mean, is given by the formula:
σ¯x=σnσx¯=σnσx¯=3.81
The mean of the distribution of sample means is the same as the 16≈0.3508 ft
population mean, which is μ = 183.2 ft.
The standard deviation of the distribution of sample means is given by σ¯x=σnσx¯=σnσx¯
=3.8116≈0.3508 ft.
The distribution of sample means for a sample of n = 116 trees is normal as the sample size is large.
The mean of the distribution of sample means is the same as the population mean, which is μ = 183.2 ft. The standard deviation of the distribution of sample means, also known as the standard error in estimating the mean, can be calculated using the formula σ¯x=σn.
Substituting the given values, we get:σx¯=σn=3.8116≈0.3508 ft.
This means that we can expect the mean of the sample means to be very close to the population mean, with an error of about 0.35 ft.
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Nathan correctly graphed the line of the inequality x+4y>4 on a coordinate grid, as shown, but did not shade the solution set. Which of the following points would appear in the solution set of this inequality?
The inequality in the graph is x + 4y > 4, with Nathan not shading the solution set.We will then substitute the coordinates of the solution set that satisfies the inequality.The points (0, 0), (1, 0), and (3, 1) are the ones that will appear in the solution set.
Points on the line of the inequality are substituted into the inequality to determine whether they belong to the solution set. Since the line itself is not part of the solution set, it is critical to verify whether the inequality contains "<" or ">" instead of "<=" or ">=". This indicates whether the boundary line should be included in the answer.To find out the solution set, choose a point within the region. The point to use should not be on the line, but instead, it should be inside the area enclosed by the inequality graph. For instance, (0,0) is in the region.
The solution set of x + 4y > 4 is located below the line on the coordinate plane. Any point below the line will satisfy the inequality. That means all of the points located below the line will be the solution set.
The solution set for inequality x + 4y > 4 will be any point that is under the line, thus the points (0, 0), (1, 0), and (3, 1) are the ones that will appear in the solution set.
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You buy some calla lilies and peonies at a flower store. Calla lilies cost $3.50 each and peonies cost $5.50 each. The total cost of 12 flowers is $52. Find how many calla lilies and peonies you bought of each.
7 calla lilies and 5 peonies were bought.
Let's denote the number of calla lilies bought as "C" and the number of peonies bought as "P".
According to the given information, we can set up a system of equations:
C + P = 12 (Equation 1) - represents the total number of flowers bought.
3.50C + 5.50P = 52 (Equation 2) - represents the total cost of the flowers.
The second equation represents the total cost of the flowers, with the prices of each flower type multiplied by the respective number of flowers bought.
Now, let's solve this system of equations to find the values of C and P.
From Equation 1, we have C = 12 - P. (Equation 3)
Substituting Equation 3 into Equation 2, we get:
3.50(12 - P) + 5.50P = 52
Simplifying the equation:
42 - 3.50P + 5.50P = 52
2P = 10
P = 5
Substituting the value of P back into Equation 1, we can find C:
C + 5 = 12
C = 12 - 5
C = 7
Therefore, 7 calla lilies and 5 peonies were bought.
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What is an indicated angle?.
Answer:
An indicated angle is an angle that is measured by an instrument, such as a protractor or a compass.
Step-by-step explanation:
The angle is indicated by aligning the instrument with the two lines that form the angle, and then reading the measurement from the instrument's markings.
Indicated angles are often used in geometry and trigonometry to calculate angles in a variety of shapes and problems. They can be measured in degrees, radians, or other units of angle measurement, depending on the context.
It's important to note that an indicated angle may not always be the same as the actual angle between two lines, especially if the instrument used to measure the angle is not accurate or precise.
\section*{Problem 2}
\subsection*{Part 1}
Which of the following arguments are valid? Explain your reasoning.\\
\begin{enumerate}[label=(\alph*)]
\item I have a student in my class who is getting an $A$. Therefore, John, a student in my class, is getting an $A$. \\\\
%Enter your answer below this comment line.
\\\\
\item Every Girl Scout who sells at least 30 boxes of cookies will get a prize. Suzy, a Girl Scout, got a prize. Therefore, Suzy sold at least 30 boxes of cookies.\\\\
%Enter your answer below this comment line.
\\\\
\end{enumerate}
\subsection*{Part 2}
Determine whether each argument is valid. If the argument is valid, give a proof using the laws of logic. If the argument is invalid, give values for the predicates $P$ and $Q$ over the domain ${a,\; b}$ that demonstrate the argument is invalid.\\
\begin{enumerate}[label=(\alph*)]
\item \[
\begin{array}{||c||}
\hline \hline
\exists x\, (P(x)\; \land \;Q(x) )\\
\\
\therefore \exists x\, Q(x)\; \land\; \exists x \,P(x) \\
\hline \hline
\end{array}
\]\\\\
%Enter your answer here.
\\\\
\item \[
\begin{array}{||c||}
\hline \hline
\forall x\, (P(x)\; \lor \;Q(x) )\\
\\
\therefore \forall x\, Q(x)\; \lor \; \forall x\, P(x) \\
\hline \hline
\end{array}
\]\\\\
%Enter your answer here.
\\\\
\end{enumerate}
\newpage
%--------------------------------------------------------------------------------------------------
The argument is invalid because just one student getting an A does not necessarily imply that every student gets an A in the class. There might be more students in the class who aren't getting an A.
Therefore, the argument is invalid. The argument is valid. Since Suzy received a prize and according to the statement in the argument, every girl scout who sells at least 30 boxes of cookies will get a prize, Suzy must have sold at least 30 boxes of cookies. Therefore, the argument is valid.
a. The argument is invalid. Let's consider the domain to be
[tex]${a,\; b}$[/tex]
Let [tex]$P(a)$[/tex] be true,[tex]$Q(a)$[/tex] be false and [tex]$Q(b)$[/tex] be true.
Then, [tex]$\exists x\, (P(x)\; \land \;Q(x))$[/tex] is true because [tex]$P(a) \land Q(a)$[/tex] is true.
However, [tex]$\exists x\, Q(x)\; \land\; \exists x \,P(x)$[/tex] is false because [tex]$\exists x\, Q(x)$[/tex] is true and [tex]$\exists x \,P(x)$[/tex] is false.
Therefore, the argument is invalid.
b. The argument is invalid.
Let's consider the domain to be
[tex]${a,\; b}$[/tex]
Let [tex]$P(a)$[/tex] be true and [tex]$Q(b)$[/tex]be true.
Then, [tex]$\forall x\, (P(x)\; \lor \;Q(x) )$[/tex] is true because [tex]$P(a) \lor Q(a)$[/tex] and [tex]$P(b) \lor Q(b)$[/tex] are true.
However, [tex]$\forall x\, Q(x)\; \lor \; \forall x\, P(x)$[/tex] is false because [tex]$\forall x\, Q(x)$[/tex] is false and [tex]$\forall x\, P(x)$[/tex] is false.
Therefore, the argument is invalid.
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Show that t for the Pearson Correlation Coefficient is mathematically equivalent to t-test statistic for the least squares regression parameter.
Since Cov(X, Y) / sqrt(Var(X)) is the t-test statistic for the least squares regression parameter, we can conclude that:
t_r = t_regression.
To show the equivalence between the t-statistic for the Pearson Correlation Coefficient and the t-test statistic for the least squares regression parameter, we need to understand the mathematical relationships between these two statistics.
Let's consider a simple linear regression model with one independent variable (X) and one dependent variable (Y):
Y = β0 + β1*X + ε
where β0 and β1 are the intercept and slope coefficients, respectively, and ε is the error term.
The Pearson Correlation Coefficient (r) measures the strength and direction of the linear relationship between X and Y. It is defined as the covariance of X and Y divided by the product of their standard deviations:
r = Cov(X, Y) / (SD(X) * SD(Y))
The t-statistic for the Pearson Correlation Coefficient can be calculated as:
[tex]t_r = r \times \sqrt{(n - 2) / (1 - r^2)}[/tex]
where n is the sample size.
On the other hand, in a linear regression, we estimate the slope coefficient (β1) using the least squares method. The t-test statistic for the least squares regression parameter tests the hypothesis that the slope coefficient is equal to zero. It can be calculated as:
t_regression = (β1 - 0) / (SE(β1))
where SE(β1) is the standard error of the least squares regression parameter.
To show the equivalence between t_r and t_regression, we need to express them in terms of each other.
The Pearson Correlation Coefficient (r) can be written in terms of the slope coefficient (β1) and the standard deviations of X and Y:
r = (β1 * SD(X)) / SD(Y)
By substituting this expression for r in the t_r equation, we get:
t_r = ((β1 * SD(X)) / SD(Y)) * sqrt((n - 2) / (1 - ((β1 * SD(X)) / SD(Y))^2))
Simplifying this equation further:
t_r = (β1 * SD(X)) * sqrt((n - 2) / ((1 - ((β1 * SD(X)) / SD(Y))) * (1 + ((β1 * SD(X)) / SD(Y)))))
t_r = (β1 * SD(X)) * sqrt((n - 2) / (SD(Y)^2 - (β1 * SD(X))^2))
Now, let's consider the least squares regression equation for β1:
β1 = Cov(X, Y) / Var(X)
Substituting the definitions of Cov(X, Y) and Var(X):
β1 = Cov(X, Y) / (SD(X)^2)
By rearranging the equation, we can express Cov(X, Y) in terms of β1:
Cov(X, Y) = β1 * SD(X)^2
Substituting this expression for Cov(X, Y) in the t_r equation:
t_r = (β1 * SD(X)) * sqrt((n - 2) / (SD(Y)^2 - (β1 * SD(X))^2))
= (Cov(X, Y) / SD(X)) * sqrt((n - 2) / (SD(Y)^2 - (Cov(X, Y))^2 / SD(X)^2))
By substituting Var(X) = SD(X)^2 and rearranging, we have:
t_r = (Cov(X, Y) / sqrt(Var(X))) * sqrt((n - 2) / (SD(Y)^2 - (Cov(X, Y))^2 / Var(X)))
Since Cov(X, Y) / sqrt(Var(X)) is the t-test statistic for the least squares regression parameter, we can conclude that:
t_r = t_regression
Therefore, we have mathematically shown the equivalence between the t-statistic for the Pearson Correlation Coefficient and the t-test statistic for the least squares regression parameter.
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A random sample of size 64 is selected from a certain population with mean 76 and standard deviation sample of size 64 is selected from a certain population with mean 76 and standard 16. What is the probability of getting the average
X greater than 75 ?
Hence, the probability of getting an average X greater than 75 is 0.6915.
Given:
Sample size (N) = 64
Sample mean (X) = 76
Standard deviation (σ) = 16
To find:
The probability of getting the average X greater than 75, P(X> 75)
We can find the probability as follows:
P(X > 75) = P(Z > (75 - 76) / (16 / √64)) = P(Z > -0.5)
We know that the standard normal distribution is symmetric about its mean, which is 0. So, the area of interest is P(Z > -0.5), which is equivalent to the area P(Z < 0.5) using the symmetry of the standard normal distribution.
Using the standard normal distribution table, we find that P(Z < 0.5) = 0.6915.
Therefore, P(X > 75) = P(Z > -0.5) = P(Z < 0.5) = 0.6915.
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Write an equation in slope-intercept fo for the line that contains (4,9) and (8,6) y=
The slope-intercept equation of the line that passes through the points (4,9) and (8,6) is y = -3/4x + 12. This can be found by using the slope formula to calculate the slope and then plugging in one of the points to solve for the y-intercept.
The slope-intercept form of a linear equation is y = mx + b, where m is the slope of the line and b is the y-intercept. To find the slope of the line that passes through (4,9) and (8,6), we can use the slope formula:
slope = (y₂ - y₁) / (x₂ - x₁)
Substituting the coordinates of the two points, we get:
slope = (6 - 9) / (8 - 4)
slope = -3 / 4
Now that we know the slope of the line, we can plug it into the slope-intercept equation and solve for b. Using the coordinates of one of the points (it doesn't matter which one), we get:
9 = (-3/4)(4) + b
9 = -3 + b
b = 12
So the final equation in slope-intercept form is:
y = -3/4x + 12
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A line passes through the points A(n,4) and B(6,8) and is parallel to y=2x−5. What is the value of n ? n= (Type an integer or a simplified fraction.)
If a line passes through the points A(n,4) and B(6,8) and is parallel to y=2x−5, then the value of n is 4.
To find the value of n, follow these steps:
The slope of the line that passes through the points (x₁, y₁) and (x₂, y₂) can be calculated as follows: slope= y₂- y₁/ x₂- x₁ Since the line is parallel to the line y=2x−5, it means that the slope of the two lines are equal.The equation of the line y=2x−5 can be written in slope-intercept form as follows: y= mx + c, where m is the slope= 2 and c is the y-intercept.So, the slope of the line that passes through the points A(n,4) and B(6,8) is 4/ 6-n= 4/ 6-n. The slope is equal to the slope of the line y=2x−5. So, 4/6-n = 2.Simplifying, we get 6-n= 2⇒n= 4.Learn more about parallel line:
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Four students each flip a coin multiple times and record the number of times the coin lands heads up. The results are shown in the table. Student Number of Flips Ana 50 Brady 10 Collin 80 Deshawn 20 Which student is most likely to find that the actual number of times his or her coin lands heads up most closely matches the picted number of heads-up landings?
The student that has the highest probability to find that the actual number of times his or her coin lands heads up most closely matches the predicted numberof heads-up landings is Collin.
How is this so?Let's calculate the expected number of heads-up landings for each student -
Ana = 0.5 * 50 = 25
Brady = 0.5 * 10 = 5
Collin = 0.5 * 80 = 40
Deshawn = 0.5 * 20 = 10
From the above we can see that Collin (80 flips) is most likely to find that the actual number of times his coin lands heads up most closely matchesthe predicted number of heads-up landings (40).
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Full Question:
Although part of your question is missing, you might be referring to this full question:
Four students are determining the probability of flipping a coin and it landing head's up. Each flips a coin the number of times shown in the table below.
Student
Number of Flips
Ana
50
Brady
10
Collin
80
Deshawn
20
Which student is most likely to find that the actual number of times his or her coin lands heads up most closely matches the predicted number of heads-up landings?
Define: (i) arc length of a curve (ii) surface integral of a vector function (b) Using part (i), show that the arc length of the curve r(t)=3ti+(3t^2+2)j+4t^3/2k from t=0 to t=1 is 6 . [2,2] Green's Theorem (a) State the Green theorem in the plane. (b) Express part (a) in vector notation. (c) Give one example where the Green theorem fails, and explain how.
(i) Arc length of a curve: The arc length of a curve is the length of the curve between two given points. It measures the distance along the curve and represents the total length of the curve segment.
(ii) Surface integral of a vector function: A surface integral of a vector function represents the integral of the vector function over a given surface. It measures the flux of the vector field through the surface and is used to calculate quantities such as the total flow or the total charge passing through the surface.
(b) To find the arc length of the curve r(t) = 3ti + (3t^2 + 2)j + (4t^(3/2))k from t = 0 to t = 1, we can use the formula for arc length in parametric form. The arc length is given by the integral:
L = ∫[a,b] √[ (dx/dt)^2 + (dy/dt)^2 + (dz/dt)^2 ] dt,
where (dx/dt, dy/dt, dz/dt) are the derivatives of x, y, and z with respect to t.
In this case, we have:
dx/dt = 3
dy/dt = 6t
dz/dt = (6t^(1/2))/√2
Substituting these values into the formula, we get:
L = ∫[0,1] √[ 3^2 + (6t)^2 + ((6t^(1/2))/√2)^2 ] dt
= ∫[0,1] √[ 9 + 36t^2 + 9t ] dt
= ∫[0,1] √[ 9t^2 + 9t + 9 ] dt
= ∫[0,1] 3√[ t^2 + t + 1 ] dt.
Now, let's evaluate this integral:
L = 3∫[0,1] √[ t^2 + t + 1 ] dt.
To simplify the integral, we complete the square inside the square root:
L = 3∫[0,1] √[ (t^2 + t + 1/4) + 3/4 ] dt
= 3∫[0,1] √[ (t + 1/2)^2 + 3/4 ] dt.
Next, we can make a substitution to simplify the integral further. Let u = t + 1/2, then du = dt. Changing the limits of integration accordingly, we have:
L = 3∫[-1/2,1/2] √[ u^2 + 3/4 ] du.
Now, we can evaluate this integral using basic integration techniques or a calculator. The result should be:
L = 3(2√3)/2
= 3√3.
Therefore, the arc length of the curve r(t) = 3ti + (3t^2 + 2)j + (4t^(3/2))k from t = 0 to t = 1 is 3√3, which is approximately 5.196.
(a) Green's Theorem in the plane: Green's Theorem relates a line integral around a simple closed curve C to a double integral over the plane region D bounded by C. It states:
∮C (P dx + Q dy) = ∬D ( ∂Q/∂x - ∂P/∂y ) dA,
where C is a simple closed curve, P and
Q are continuously differentiable functions, and D is the region enclosed by C.
(b) Green's Theorem in vector notation: In vector notation, Green's Theorem can be expressed as:
∮C F · dr = ∬D (∇ × F) · dA,
where F is a vector field, C is a simple closed curve, dr is the differential displacement vector along C, ∇ × F is the curl of F, and dA is the differential area element.
(c) Example where Green's Theorem fails: Green's Theorem fails when the region D is not simply connected or when the vector field F has singularities (discontinuities or undefined points) within the region D. For example, if the region D has a hole or a boundary with a self-intersection, Green's Theorem cannot be applied.
Additionally, if the vector field F has a singularity (such as a point where it is not defined or becomes infinite) within the region D, the curl of F may not be well-defined, which violates the conditions for applying Green's Theorem. In such cases, alternative methods or theorems, such as Stokes' Theorem, may be required to evaluate line integrals or flux integrals over non-simply connected regions.
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Let P and Q be two points in R2. Let be the line in R that passes through P and Q. The vector PQ is a direction vector for &, so if we set p=OP, then a vector equation for is x = p +1PQ. There is a point R on the line which is at equal distance from P and from Q. For which value of t is x equal to OR?
By setting x equal to OR, we obtain the equation r = p + tPQ, which represents the position vector of point R on the line.
In the first paragraph, it is stated that the line passing through points P and Q in R2 can be represented by the vector equation x = p + 1PQ, where p is the position vector of point P. This equation indicates that any point x on the line can be obtained by starting from P (represented by the vector p) and moving in the direction of the vector PQ.
In the second paragraph, it is mentioned that there exists a point R on the line that is equidistant from points P and Q. This means that the distance between R and P is the same as the distance between R and Q. Let's denote the position vector of point R as r.
To find the value of t for which x is equal to OR (the position vector of R), we can set x = r. Substituting the vector equation x = p + 1PQ with r, we get r = p + tPQ, where t is the scalar value we are looking for. Thus, by setting x equal to OR, we obtain the equation r = p + tPQ, which represents the position vector of point R on the line.
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If the radiu of a circle i 4 and the cale factor i. 75 what it the new circle coordinate
If the radius of a circle is 4 and the scale factor is 0.75, the new circle coordinates will remain unchanged. The new circle will have a radius of 3, but the center point will stay the same.
To find the new coordinates of the circle after applying a scale factor, we need to multiply the radius of the original circle by the scale factor. In this case, the radius of the original circle is 4, and the scale factor is 0.75.
To find the new radius, we multiply 4 by 0.75, which gives us 3.
The coordinates of a circle represent the center point of the circle. Since the scale factor only affects the radius, the center point remains the same. Therefore, the new circle coordinates will be the same as the original coordinates.
In conclusion, if the radius of a circle is 4 and the scale factor is 0.75, the new circle coordinates will remain unchanged. The new circle will have a radius of 3, but the center point will stay the same.
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It takes Boeing 28,718 hours to produce the fifth 787 jet. The learning factor is 80%. Time required for the production of the eleventh 787 : 11th unit time hours (round your response to the nearest whole
Rounding the response to the nearest whole, the time required for the production of the eleventh 787 jet is approximately 51,529 hours.
To calculate the time required for the production of the eleventh 787 jet, we can use the learning curve concept. The learning curve states that as cumulative production doubles, the average time per unit decreases by a constant percentage, which is referred to as the learning factor.
In this case, the learning factor is given as 80%, which means that every time the cumulative production doubles, the time required per unit decreases by 80%.
To find the time required for the eleventh unit, we need to determine the cumulative production when the eleventh unit is being produced. Since we know the time required for the fifth unit is 28,718 hours, we can use the learning factor to calculate the cumulative production at that point.
Let's denote the cumulative production as CP and the time required for the fifth unit as T5. The learning factor is LF = 80%.
Using the learning curve formula:
CP1 = CP0 *[tex]2^{(log(LF)/log(2))[/tex]
Where CP1 is the cumulative production when the fifth unit is produced and CP0 is the cumulative production when the first unit is produced (CP0 = 1).
CP1 = 1 * [tex]2^{(log(0.8)/log(2))[/tex] = 1 * 2^(-0.32193) = 0.6688
Now, we can calculate the cumulative production when the eleventh unit is produced (CP11).
CP11 = CP1 * [tex]2^{(log(LF)/log(2))[/tex] = 0.6688 * 2^(log(0.8)/log(2)) = 0.6688 * 2^(-0.32193) = 0.4425
Since the time required for the fifth unit is 28,718 hours, we can calculate the time required for the eleventh unit (T11).
T11 = T5 *[tex](CP11/5)^{log(LF)/log(2)[/tex]
T11 = 28,718 * [tex](0.4425/5)^{(log(0.8)/log(2))[/tex] = 28,718 * 0.0885^(-0.32193) ≈ 51,529.49 hours
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Two popular strategy video games, AE and C, are known for their long play times. A popular game review website is interested in finding the mean difference in playtime between these games. The website selects a random sample of 43 gamers to play AE and finds their sample mean play time to be 3.6 hours with a variance of 54 minutes. The website also selected a random sample of 40 gamers to test game C and finds their sample mean play time to be 3.1 hours and a standard deviation of 0.4 hours. Find the 90% confidence interval for the population mean difference m m AE C − .
The confidence interval indicates that we can be 90% confident that the true population mean difference in playtime between games AE and C falls between 0.24 and 0.76 hours.
The 90% confidence interval for the population mean difference between games AE and C (denoted as μAE-C), we can use the following formula:
Confidence Interval = (x(bar) AE - x(bar) C) ± Z × √(s²AE/nAE + s²C/nC)
Where:
x(bar) AE and x(bar) C are the sample means for games AE and C, respectively.
s²AE and s²C are the sample variances for games AE and C, respectively.
nAE and nC are the sample sizes for games AE and C, respectively.
Z is the critical value corresponding to the desired confidence level. For a 90% confidence level, Z is approximately 1.645.
Given the following information:
x(bar) AE = 3.6 hours
s²AE = 54 minutes = 0.9 hours (since 1 hour = 60 minutes)
nAE = 43
x(bar) C = 3.1 hours
s²C = (0.4 hours)² = 0.16 hours²
nC = 40
Substituting these values into the formula, we have:
Confidence Interval = (3.6 - 3.1) ± 1.645 × √(0.9/43 + 0.16/40)
Calculating the values inside the square root:
√(0.9/43 + 0.16/40) ≈ √(0.0209 + 0.004) ≈ √0.0249 ≈ 0.158
Substituting the values into the confidence interval formula:
Confidence Interval = 0.5 ± 1.645 × 0.158
Calculating the values inside the confidence interval:
1.645 × 0.158 ≈ 0.26
Therefore, the 90% confidence interval for the population mean difference between games AE and C is:
(0.5 - 0.26, 0.5 + 0.26) = (0.24, 0.76)
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Find the point at which the line f(x)=-5x-2 intersects the line g(x)=-7x. Enter the exact answer as a point, (a,b).
The point at which the line f(x)=-5x-2 intersects the line g(x)=-7x is [tex]\((\frac{2}{3}, -\frac{14}{3})\)[/tex].
To find the point of intersection between two lines, we need to set their equations equal to each other and solve for x and y.
Given the equations:
f(x)=-5x-2 and g(x)=-7x
We set them equal to each other:
[tex]\(-5x-2=-7x\)[/tex]
Adding [tex]\(7x\)[/tex] to both sides:
[tex]\(2x-5x=-2\)[/tex]
Combining like terms:
[tex]\(-3x=-2\)[/tex]
Dividing both sides by [tex]\(-3\)[/tex] to solve for [tex]\(x\)[/tex]:
[tex]\(x=\frac{2}{3}\)[/tex]
Now, substitute this value of [tex]\(x\)[/tex] into either of the original equations to find the corresponding y value. Let's use g(x)=-7x:
[tex]\(g\left(\frac{2}{3}\right)=-7\left(\frac{2}{3}\right)\)[/tex]
[tex]\(g\left(\frac{2}{3}\right)=-\frac{14}{3}\)[/tex]
Therefore, the point of intersection is [tex]\((\frac{2}{3}, -\frac{14}{3})\)[/tex].
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You can retry this question below If f(x)=5+2x−2x^2
use the definition of the derivative to find f′(3)
The value of f'(3) is -10.
Given, f(x) = 5 + 2x - 2x²
To find, f'(3)
The definition of derivative is given as
f'(x) = lim h→0 [f(x+h) - f(x)]/h
Let's calculate
f'(x)f'(x) = [d/dx(5) + d/dx(2x) - d/dx(2x²)]f'(x)
= [0 + 2 - 4x]f'(x) = 2 - 4xf'(3)
= 2 - 4(3)f'(3) = -10
Hence, the value of f'(3) is -10.
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4. Prove using the definition of "big Oh" that n^{2}+50 n \in O\left(n^{2}\right) \text {. } (Find appropriate values of C and N such that n^{2}+50 n ≤ C n^{2} for n ≥
The definition of "big Oh" :
Big-Oh: The Big-Oh notation denotes that a function f(x) is asymptotically less than or equal to another function g(x). Mathematically, it can be expressed as: If there exist positive constants.
The statement n^2 + 50n ∈ O(n^2) is true.
We need to show that there exist constants C and N such that n^2 + 50n ≤ Cn^2 for all n ≥ N.
To do this, we can choose C = 2 and N = 50.
Then, for n ≥ 50, we have:
n^2 + 50n ≤ n^2 + n^2 = 2n^2
Since 2n^2 ≥ Cn^2 for all n ≥ N, we have shown that n^2 + 50n ∈ O(n^2).
Therefore, the statement n^2 + 50n ∈ O(n^2) is true.
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We wish to estimate what percent of adult residents in a certain county are parents. out of 400 adult residents sampled, 156 had kids. based on this, construct a 95% confidence interval for the proportion p of adult residents who are parents in the country.
Express your answers in trivia inequality form and give your as decimals to three places.
___
Given: n = 400; x = 156We can calculate the sample proportion:
$$\hat p=\frac{x}{n}=\frac{156}{400}=0.39$$
To construct a 95% confidence interval for the population proportion p, we can use the formula:
$$\hat p\pm z_{\alpha/2}\sqrt{\frac{\hat p(1-\hat p)}{n}}$$where $z_{\alpha/2}$ is the z-score corresponding to a 95% confidence level, which is 1.96 (rounded to two decimal places).
Putting the values in the formula,
we have: $$0.39\pm 1.96\sqrt{\frac{0.39(1-0.39)}{400}}$$Simplifying, we get: $$0.39\pm 1.96\times 0.0321$$Now,
we can express the 95% confidence interval in the form of a trivium inequality: $$\boxed{0.30
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if z=yx+y^2 where x=oe^l and y=lm^2+4no^2 find delta z/delta o and delta z/delta l when l=0, m=-4, n=2, o=1
The values of the partial derivatives are as follows: δz/δo = 0 and δz/δl = 0. Therefore, the partial derivative δz/δo is 0, and the partial derivative δz/δl is also 0 when l = 0, m = -4, n = 2, and o = 1.
To find δz/δo and δz/δl, we need to differentiate the expression for [tex]z = yx + y^2[/tex] with respect to o and l, respectively. Then we can evaluate the derivatives at the given values of l, m, n, and o.
Given:
[tex]x = o * e^l[/tex]
[tex]y = l * m^2 + 4 * n * o^2[/tex]
l = 0, m = -4, n = 2, o = 1
Let's find δz/δo:
To find δz/δo, we differentiate [tex]z = yx + y^2[/tex] with respect to o:
δz/δo = δ(yx)/δo + δ([tex]y^2[/tex])/δo
Now we substitute the given expressions for x and y:
[tex]x = o * e^l \\= 1 * e^0 \\= 1[/tex]
[tex]y = l * m^2 + 4 * n * o^2 \\= 0 * (-4)^2 + 4 * 2 * 1^2 \\= 8[/tex]
Plugging these values into the equation for δz/δo, we get:
δz/δo = δ(yx)/δo + δ(y²)/δo = x * δy/δo + 2y * δy/δo
Now we differentiate y with respect to o:
δy/δo = δ[tex](l * m^2 + 4 * n * o^2)[/tex]/δo
= δ[tex](0 * (-4)^2 + 4 * 2 * 1^2)[/tex]/δo
= δ(8)/δo
= 0
Therefore, δz/δo = x * δy/δo + 2y * δy/δo
= 1 * 0 + 2 * 8 * 0
= 0
So, δz/δo = 0.
Next, let's find δz/δl:
To find δz/δl, we differentiate [tex]z = yx + y^2[/tex] with respect to l:
δz/δl = δ(yx)/δl + δ(y²)/δl
Using the given expressions for x and y:
x = 1
[tex]y = 0 * (-4)^2 + 4 * 2 * 1^2[/tex]
= 8
Plugging these values into the equation for δz/δl, we have:
δz/δl = δ(yx)/δl + δ([tex]y^2[/tex])/δl
= x * δy/δl + 2y * δy/δl
Now we differentiate y with respect to l:
δy/δl = δ[tex](l * m^2 + 4 * n * o^2)[/tex]/δl
= δ[tex](0 * (-4)^2 + 4 * 2 * 1^2)[/tex]/δl
= δ(8)/δl
= 0
Therefore, δz/δl = x * δy/δl + 2y * δy/δl
= 1 * 0 + 2 * 8 * 0
= 0
So, δz/δl = 0.
To summarize:
δz/δo = 0
δz/δl = 0
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Let f(x)=Ax²+6x+4 and g(x)=2x−3. Find A such that the graphs of f(x) and g(x) intersect when x=4 If necessary, entet your answer as a decimal 1) Moving to another question will save this response. A company manufactures and sells baseball hats They've estimated the cost to manutacture H hats in a month. given by C(H)=2.4H+1960 dollars each month. The demand for H hats at p dollars per hat is given by the demand equation 2H+129p=6450 What is the maximum amount of montly profit the company can make when nanuacturing and selfng these hats? Give your answer as a numelical yakie (no labsis) rounced appropriated
The maximum monthly profit the company can make when manufacturing and selling these hats is $5327.11.
Let f(x) = Ax² + 6x + 4 and g(x) = 2x - 3.
Find A such that the graphs of f(x) and g(x) intersect when x = 4
When x = 4, we have:
g(x) = 2(4) - 3 = 8 - 3 = 5g(x) = 5
Now, let's find f(x) by replacing x with 4 in the equation:
f(x) = Ax² + 6x + 4f(x)
= A(4)² + 6(4) + 4f(x)
= 16A + 24 + 4f(x)
= 16A + 28f(x)
= 16A + 28
Now that we have the values of f(x) and g(x), we can equate them and solve for A:
16A + 28 = 5
Simplify the equation:16
A = -23A = -23/16
Therefore, A = -1.4375.
Cost function, C(H) = 2.4H + 1960
Demand function, 2H + 129p = 6450
We can solve the demand function for H:
H = (6450 - 129p)/2
The maximum monthly profit is given by:
C(18.82) = 5830 - 309.6(18.82)
= $5327.11(rounded to 2 decimal places)
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Prove:d2x К 1 dr² = ((d+ 2)² (d-2)²) dt2 m
(a) Classify this ODE and explain why there is little hope of solving it as is.
(b) In order to solve, let's assume
(c) We want to expand the right-hand side function in an appropriate Taylor series. What is the "appropriate" Taylor series? Let the variable that we are expanding in be called z. What quantity is playing the role of z? And are we expanding around z = 0 (Maclaurin series) or some other value of z? [HINT: factor a d² out of the denominator of both terms.] Also, how many terms in the series do we need to keep? [HINT: we are trying to simplify the ODE. How many terms in the series do you need in order to make the ODE look like an equation that you know how to solve?]
(d) Expand the right-hand side function of the ODE in the appropriate Taylor series you described in part (c). [You have two options here. One is the "direct" approach. The other is to use one series to obtain a different series via re-expanding, as you did in class for 2/3. Pick one and do it. If you feel up to the challenge, do it both ways and make sure they agree.]
(e) If all went well, your new, approximate ODE should resemble the simple harmonic oscillator equation. What is the frequency of oscillations of the solutions to that equation in terms of K, m, and d?
(f) Finally, comment on the convergence of the Taylor series you used above. Is it convergent? Why or why not? If it is, what is its radius of convergence? How is this related to the very first step where you factored d² out of the denominator? Could we have factored 2 out of the denominator instead? Explain.
a. The general solution differs from the usual form due to the non-standard roots of the characteristic equation.
b. To solve the ODE, we introduce a new variable and rewrite the equation.
c. The "appropriate" Taylor series is derived by expanding the function in terms of a specific variable.
d. Expanding the right-hand side function of the ODE using the appropriate Taylor series.
e. The new, approximate ODE resembles the equation for simple harmonic motion.
f. The convergence and radius of convergence of the Taylor series used.
(a) The ODE is a homogeneous second-order ODE with constant coefficients. We know that for such equations, the characteristic equation has roots of the form r = λ ± iμ, which gives the general solution c1e^(λt) cos(μt) + c2e^(λt) sin(μt). However, the characteristic equation of this ODE is (d² + 1/r²), which has roots of the form r = ±i/r. These roots are not of the form λ ± iμ, so the general solution is not the usual one. In fact, it involves hyperbolic trigonometric functions and is not easy to find.
(b) We let y = x'' so that we can rewrite the ODE as y' = -r²y + f(t), where f(t) = (d²/dr²)(1/r²)x(t). We will solve for y(t) and then integrate twice to get x(t).
(c) The "appropriate" Taylor series is f(z) = (1 + z²/2 + z⁴/24 + ...)d²/dr²(1/r²)x(t) evaluated at z = rt, which is playing the role of t. We are expanding around z = 0, since that is where the coefficient of d²/dr² is 1. We only need to keep the first two terms of the series, since we only need to simplify the ODE.
(d) We have f(z) = (1 + z²/2)d²/dr²(x(t)/r²) = (1 + z²/2)d²/dt²(x(t)/r²). Using the chain rule, we get d²/dt²(x(t)/r²) = [d²/dt²x(t)]/r² - 2(d/dt x(t))(d/dr)(1/r) + 2(d/dt x(t))(d/dr)(1/r)². Substituting this expression into the previous one gives y' = -r²y + (1 + rt²/2)d²/dt²(x(t)/r²).
(e) The new, approximate ODE is y' = -r²y + (1 + rt²/2)y. This is the equation for simple harmonic motion with frequency sqrt(2 + r²)/(2mr).
(f) The Taylor series is convergent since the function we are expanding is analytic everywhere. Its radius of convergence is infinite. We factored d² out of the denominator since that is the coefficient of x'' in the ODE. We could not have factored 2 out of the denominator since that would have changed the ODE and the subsequent calculations.
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you read about a study testing whether night shift workers sleep the recommended 8 hours per day. assuming that the population variance of sleep (per day) is unknown, what type of t test is appropriate for this study?
The type of t test which is appropriate for this study is one-sample t-test.
We are given that;
The time of recommended sleep= 8hours
Now,
In statistics, Standard deviation is a measure of the variation of a set of values.
σ = standard deviation of population
N = number of observation of population
X = mean
μ = population mean
A one-sample t-test is a statistical hypothesis test used to determine whether an unknown population mean is different from a specific value.
It examines whether the mean of a population is statistically different from a known or hypothesized value
If the population variance of sleep (per day) is unknown, then a one-sample t-test is appropriate for this study
Therefore, by variance answer will be one-sample t-test.
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Job Interview Question (JIQ). A researcher wishes to know whether different age groups have varying mean times watching TV. She considers the following one-way fixed-effects ANOVA model: TIME ij=μ+τi+εij where μ is the grand mean viewing time (hours), μi is the mean viewing time of group i,τi=μi−μ is the differential effect of group i on viewing time, ε ij is the the random error component about the mean μ+τ i for the j th subject from the i th group. The age groups are (adult) women (W), (adult) men (M), teens (T), and children (C). Dummy variables W,M and T are created, which are defined as follows: W=1 if the individual is a woman, 0 otherwise, M=1 if the individual is a man, 0 otherwise, and T=1 if the individual is a teenager, 0 otherwise. The PROC GLM output is shown below: Estimate: (a) women's mean viewing time (b) difference in mean viewing time between women and children (c) difference in mean viewing time between women and teenagers
(a) Estimate for women's mean viewing time can be obtained from the coefficient estimate for the dummy variable W.
(b) Difference in mean viewing time between women and children can be obtained by subtracting the coefficient estimate for the dummy variable C from the coefficient estimate for the dummy variable W.
(c) Difference in mean viewing time between women and teenagers can be obtained by subtracting the coefficient estimate for the dummy variable T from the coefficient estimate for the dummy variable W.
The PROC GLM output provides the estimates for the model coefficients. To answer the questions:
(a) The estimate for women's mean viewing time (μw) can be obtained from the coefficient estimate for the dummy variable W.
(b) The difference in mean viewing time between women and children (μw - μc) can be obtained by subtracting the coefficient estimate for the dummy variable C from the coefficient estimate for the dummy variable W.
(c) The difference in mean viewing time between women and teenagers (μw - μt) can be obtained by subtracting the coefficient estimate for the dummy variable T from the coefficient estimate for the dummy variable W.
By examining the coefficient estimates in the PROC GLM output, you can determine the specific values for (a), (b), and (c) in the context of the given ANOVA model.
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Find dy/dx for the following function. y=x³cosxsin x dy/dx=
Hence, the dy/dx of the following function is dy/dx = x³ cos² x - x³ sin² x + 3x² cos x sin x
We're given a function, y = x³ cos x sin x, and we're asked to find dy/dx, which is the derivative of y with respect to x.
Therefore, we'll have to use the product rule and the chain rule.
Let's get started.
Notice that the function y can be written as a product of three functions, u, v, and w, as follows:
u = x³ (power function) (derivative of u, du/dx = 3x²)
v = cos x (trigonometric function) (derivative of v, dv/dx = -sin x)
w = sin x (trigonometric function) (derivative of w, dw/dx = cos x)
So, y = uvw
Next, we'll need to use the product rule to find dy/dx, which is given by:
dy/dx = uvw' + uv'w + u'vw' where the ' symbol indicates differentiation with respect to x.
Using this formula, we'll find dy/dx as follows:
dy/dx = [x³ cos x cos x] + [x³ (-sin x) sin x] + [3x² cos x sin x] which simplifies as follows:
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Let's say that Marco is thinking of buying a new laptop computer that costs $960. Again, he is considering a payment plan that would give him six months to pay for the computer, with no interest charged. For the purposes of Questions, we will assume there are no taxes or other fees that would increase the total cost of the laptop.
Marco would need to make monthly payments of $160 for six months to pay off the laptop without any interest charges.
Marco is considering a payment plan for a laptop that costs $960, with a six-month payment period and no interest charges.
To calculate the monthly payment amount, we divide the total cost of the laptop by the number of months in the payment period:
Monthly payment = Total cost / Number of months
In this case, the total cost is $960, and the payment period is six months:
Monthly payment = $960 / 6
Monthly payment = $160
Therefore, Marco would need to make monthly payments of $160 for six months to pay off the laptop without any interest charges.
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Use Wolfram Mathematica to solve this question. A will throw a six-sided fair die repeatedly until he obtains a 2. B will throw the same die repeatedly until she obtains a 2 or 3. We assume that successive throws are independent, and A and B are throwing the die independently of one another. Let X be the sum of the numbers of throws required by A and B.
a) Find P(X=9)
b) Find E(X)
c) Find Var(X)
a) A and B are independent, we multiply these probabilities together:
P(X = 9) = (5/6)^7 * (1/6)^2
b) Find E(X): E(X) = E(A) + E(B) = 6 + 3
c) Var(X) = Var(A) + Var(B)
Let's analyze each part of the question:
a) Find P(X = 9):
To find the probability that the sum of the numbers of throws required by A and B is 9, we need to consider all the possible ways they can achieve this sum. A can throw the die 7 times (getting anything except a 2), and then B can throw the die 2 times (getting a 2). The probability of A throwing the die 7 times without obtaining a 2 is (5/6)^7, and the probability of B throwing the die 2 times and getting a 2 is (1/6)^2. Since A and B are independent, we multiply these probabilities together:
P(X = 9) = (5/6)^7 * (1/6)^2
b) Find E(X):
The expected value of X can be calculated by considering the individual expected values of A and B and summing them. A requires an average of 6 throws to obtain a 2 (since it's a geometric distribution with p = 1/6), and B requires an average of 3 throws to obtain a 2 or 3 (also a geometric distribution with p = 2/6). Therefore:
E(X) = E(A) + E(B) = 6 + 3
c) Find Var(X):
The variance of X can be calculated using the variances of A and B, as they are independent. The variance of A can be calculated using the formula Var(A) = (1 - p) / p^2, where p = 1/6. Similarly, the variance of B can be calculated using the same formula with p = 2/6. Therefore:
Var(X) = Var(A) + Var(B)
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Which graph shows a dilation?
The graph that shows a dilation is the first graph that shows a rectangle with an initial dilation of 4:2 and a final dilation of 8:4.
What is graph dilation?A graph is said to be dilated if the ratio of the y-axis and x-axis of the first graph is equal to the ratio of the y and x-axis in the second graph.
So, in the first graph, we can see that there is a scale factor of 4:2 and in the second graph, there is a scale factor of 8:4 which when divided gives 4:2, meaning that they have the same ratio. Thus, we can say that the selected figure exemplifies graph dilation.
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If A and B are events, use the result derived in Exercise 2.5(a) and the Axioms ir prove that P(A)=P(A∩B)+P(A∩ B
ˉ
). *2.22. If A and B are events and B⊂A, use the result derived in Exercise 2.5(b) and the Axioms in Definition 2.6 to prove that P(A)=P(B)+P(A∩ B
ˉ
). 2.23. If A and B are events and B⊂A, why is it "obvious" that P(B)≤P(A) ? 2.24.Use the identities A = Intersection of A and S and S = Unions of B and not B and a distributive law to prove that A = Unions of (Intersection of A and B) and (Intersection of A and not B).
*Exercise2.5(b) Use the identities A = Intersection of A and S and S = Unions of B and not B and a distributive law to prove that, If A contains B then A = Unions of B and (Intersection of A and not B).
*Definition 2.6student submitted image, transcription available below
When P(A) >= 0, P(S) = 1, and If those form a sequence of pairwise mutually exclusive events in S.
Proof for P(A)=P(A∩B)+P(A∩ B') is shown below: Let A and B be any two events. Then A can be expressed as A = (A∩B)∪(A∩B') which are mutually exclusive events.
This implies that P(A) = P(A∩B)+P(A∩B') by axiom 3 of probability. There
From the above result derived in Exercise 2.5 (a), we can see that it holds true for any two events A and B.
Therefore, we can consider B as the subset of A, i.e., B⊂A and prove that P(A)=P(B)+P(A∩ B') using the result derived in
Hence, we can say that if A and B are events and B⊂A, use the result derived in Exercise 2.5(b) and the Axioms in Definition 2.6 to prove that P(A)=P(B)+P(A∩ B').
Proof: If B⊂A, then we can express A as the union of B and A∩B' since the set A can be partitioned as the set B and the complement of B, A-B.
Therefore, P(A) = P(B)+P(A∩ B') since P(A) = P(B∪(A∩B'))
using axiom 3 of probability and using the Axioms in Definition 2.6.
Hence, we have seen the proof for P(A)=P(A∩B)+P(A∩ B') and P(A)=P(B)+P(A∩ B') using the results derived in Exercise 2.5(a) and 2.5(b) respectively. We have also understood the proof for B⊂A and why P(B)≤P(A) is obvious and the proof for A = Unions of (Intersection of A and B) and (Intersection of A and not B).
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