To find the reference number , for the given value of \( t \), we need to convert the angle from radians to a standard angle between 0 and \( 2\pi \).
(a) Finding the reference number:
We can use the fact that \( 2\pi \) is equivalent to one complete revolution. To convert \( t \) to a standard angle, we can use the formula:
\[ \bar{t} = t \mod (2\pi) \]
Substituting the given value \( t = \frac{53\pi}{6} \) into the formula:
\[ \bar{t} = \frac{53\pi}{6} \mod (2\pi) \]
To simplify this, we can note that \( 2\pi \) is equivalent to \( 12\pi/6 \), so we have:
\[ \bar{t} = \frac{53\pi}{6} \mod \frac{12\pi}{6} \]
Now we can divide both the numerator and denominator of
\( \frac{53\pi}{6} \) by \( \pi \): \[ \bar{t} = \frac{53}{6} \mod \frac{12}{6} \]
Simplifying further, we have:
\[ \bar{t} = \frac{53}{6} \mod 2 \]
The modulus operation calculates the remainder after division. Dividing \( 53 \) by \( 6 \) gives us a quotient of \( 8 \) with a remainder of \( 5 \). Therefore:
\[ \bar{t} = 5 \mod 2 \]
Taking the remainder of \( 5 \) when divided by \( 2 \), we get:
\[ \bar{t} = 1 \]
So, the reference number \( \bar{t} \) for the value of \( t = \frac{53\pi}{6} \) is \( \bar{t} = 1 \).
(b) Finding the terminal point:
To find the terminal point determined by \( t \), we can use the unit circle and the reference angle \( \bar{t} \). Since \( \bar{t} = 1 \), we need to find the coordinates of the terminal point on the unit circle corresponding to
\( \bar{t} = 1 \).
The coordinates of a point on the unit circle can be given as:
\( (x, y) = (\cos\bar{t}, \sin\bar{t}) \).
Substituting \( \bar{t} = 1 \) into the equation, we have:
\[ (x, y) = (\cos 1, \sin 1) \]
Using a calculator or trigonometric table, we can approximate the values of \( \cos 1 \) and \( \sin 1 \) as: \[ (x, y) \approx (0.5403, 0.8415) \]
Therefore, the terminal point determined by \( t = \frac{53\pi}{6} \) is approximately ,\( (x, y) \approx (0.5403, 0.8415) \).
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Consider the function f(x,y)=x 2
y+xy 2
+xy Which of the following statements are true for f? SELECT ALL. TRUE STATEMENTS. Selectionnez 2 reponse(s) correcte(s) a) (−1.0) is the only crital point of f. b) (0,−1) and (−1,0) are the only critical points of f. c) (0,−1) is a local maximum for f. d) (0,0) and (−1,0) are saddle points for f. b) (0,−1) and (−1,0) are the only critical points of f. c) (0,−1) is a local maximum for f. d) (0,0) and (−1,0) are saddle points for f. e) (0,0) is a local maximum for f. f) (−1/3,−1/3) is a local maximum for f. g) (0,−1) and (−1,0) are local minima for f
The correct statements for the function [tex]f(x, y) = x^2y + xy^2 + xy[/tex] are: b) (0,-1) and (-1,0) are the only critical points of f. d) (0,0) and (-1,0) are saddle points for f. g) (0,-1) and (-1,0) are local minima for f. Therefore, the correct selections are b) and g).
To determine the critical points of a function, we need to find the points where the partial derivatives with respect to each variable are zero or undefined. In this case, the function [tex]f(x, y) = x^2y + xy^2 + xy[/tex] has two variables, x and y.
To find the critical points, we take the partial derivatives of f(x, y) with respect to x and y and set them equal to zero:
∂f/∂x [tex]= 2xy + y^2 + y[/tex]
= 0
∂f/∂y [tex]= x^2 + 2xy + x[/tex]
= 0
By solving these equations, we can find the critical points of the function. In this case, the critical points are (0,-1) and (-1,0).
To determine whether these critical points are local maxima, local minima, or saddle points, we can use the second partial derivatives test. By taking the second partial derivatives of f(x, y) and evaluating them at the critical points, we can determine the nature of the critical points.
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A and B are independent events. Use the following probabilities to answer the question. Round to 4 decimal places. P(A) 0.57, P(A and B) = 0.34, find P(B)
The probability of event B occurring is 0.5965. In probability theory, two events are independent if the occurrence of one event does not affect the probability of the other event occurring.
If A and B are two independent events, then the probability of both events occurring at the same time is given by the product of their individual probabilities.
In this case, we know that P(A) = 0.57 and P(A and B) = 0.34. We need to find P(B).
We can use the formula for the probability of the intersection of two events, P(A and B) = P(A) × P(B|A), where P(B|A) is the probability of B given that A has occurred. Since A and B are independent, P(B|A) = P(B). Substituting the given values, we get:
0.34 = 0.57 × P(B)
P(B) = 0.34 / 0.57
P(B) = 0.5965 (rounded to 4 decimal places)
Therefore, the probability of event B occurring is 0.5965.
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A sector of a circle has a central angle of 120 degrees. Find
the area of the sector if the radius of the circle is 17 cm.
-answer in cm^2
Given that the central angle of a sector of a circle is 120° and the radius of the circle is 17 cm.
Area of a sector of a circle is given as: Area of sector.
= (θ/360°)πr²
θ =is the central angle and r being the radius of the circle.
Substitute the given values of θ and r in the above formula, we get:
Area of sector
= (120°/360°)π(17) ²
= (1/3)π(289)
= 289π/3 cm²
=96.02 cm²
Therefore, the area of the sector is 96.02 cm² (rounded off to two decimal places).
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The Derivative F′(X) Is Graphed In The Figure. Fill In The Table Of Values For F(X) Given That F(0)=−10.
The table of values for f(x) is:
x | f(x)
0 | -10
1 | -10
2 | -6
3 | 10
Since the derivative function f'(x) is given, we can find the corresponding original function f(x) by integrating f'(x) with respect to x.
To fill in the table of values for f(x), we start with the initial condition f(0) = -10.
x | f'(x)
0 | -10
To find f(x) for other values of x, we integrate f'(x) term by term:
∫ f'(x) dx = ∫ 3x^2 - 6x + 4 dx
Integrating each term separately:
∫ 3x^2 dx = x^3 + C1
∫ -6x dx = -3x^2 + C2
∫ 4 dx = 4x + C3
Adding the constants of integration C1, C2, and C3, we get:
f(x) = x^3 - 3x^2 + 4x + C
To determine the value of the constant C, we use the initial condition f(0) = -10:
-10 = (0)^3 - 3(0)^2 + 4(0) + C
-10 = 0 + 0 + 0 + C
C = -10
Therefore, the function f(x) is:
f(x) = x^3 - 3x^2 + 4x - 10
Now we can fill in the table of values for f(x) using the derived function:
x | f(x)
0 | -10
1 | -10
2 | -6
3 | 10
The table of values for f(x) is:
x | f(x)
0 | -10
1 | -10
2 | -6
3 | 10
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Write each of the given numbers in the polar form re iθ
,−π<θ≤π. (a) (cos 9
−2π
+isin 9
−2π
) 3
r= (b) − 3
+i
2−2i
r= − 3
+i
θ=
(c) 5e (2+i)
2i
r= θ=
(a) The number can be written in polar form as:
r = 1, θ = 9π/2
(b) The number can be written in polar form as:
r = 5, θ = -0.93
(c) The number can be written in polar form as:
r = 5, θ = -1
(a) To write the number (cos(9π/2) + i sin(9π/2))³ in polar form, we first calculate the magnitude (r) and the argument (θ):
Magnitude (r):
r = |cos(9π/2) + i sin(9π/2)| = 1
Argument (θ):
θ = arg(cos(9π/2) + i sin(9π/2)) = 9π/2
Therefore, the number can be written in polar form as:
r = 1, θ = 9π/2
(b) To write the number [tex](-3 + i(2-2i))^{(-3/2)[/tex] in polar form, we calculate the magnitude (r) and the argument (θ):
Magnitude (r):
r = |-3 + i(2-2i)| = |-3 + 2i + 2i| = |-3 + 4i| = √((-3)² + 4²) = 5
Argument (θ):
θ = arg(-3 + i(2-2i)) = arg(-3 + 2i + 2i) = arg(-3 + 4i) = arctan(4/-3) = -0.93 (rounded to two decimal places)
Therefore, the number can be written in polar form as:
r = 5, θ = -0.93
(c) To write the number [tex]5e^{((2+i)/(2i))[/tex] in polar form, we calculate the magnitude (r) and the argument (θ):
Magnitude (r):
r = |[tex]5e^{((2+i)/(2i))[/tex]| = 5
Argument (θ):
θ = arg([tex]5e^{((2+i)/(2i))[/tex]) = arg([tex]5e^{(1-i)[/tex]) = arg(5e * [tex]e^{(-i)[/tex]) = arg(5e) + arg([tex]e^{(-i)[/tex]) = 0 + (-1) = -1
Therefore, the number can be written in polar form as:
r = 5, θ = -1
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Complete Question:
Write each of the given numbers in the polar form r[tex]e^{itheta[/tex], −π<θ≤π.
(a) (cos−2π/9+isin−2π/9)³
r= , θ= ,
(b) 6+6i/(-√(3)+i)
r= , θ= ,
(c) 4i/(7[tex]e^{(8+i)[/tex])
r= , θ= .
A ball is thrown upward at an angle of 60° to the ground. If the ball lands 120 m away, what was the initial speed of the ball? (12 points) (You may use g in your computation, no need to use g = 9.8 m/s².)
The initial velocity of the ball is approximately 145.2 m/s.To determine the initial velocity of a ball thrown upward at an angle of 60° to the ground, which lands 120 m away, use the following steps
The given values are:θ = 60°s = 120 mWe know that the horizontal velocity (vx) is given as:vx = s / t Since the ball lands at the same height it was thrown from, the time of flight of the ball is given as:t = 2u sin θ / g (time of flight equation)where g = 9.8 m/s² (acceleration due to gravity)
The vertical velocity (vy) can be determined using the following formula: v = u sin θ - gt (velocity equation)
Finally, the initial velocity of the ball (u) can be determined using the Pythagorean theorem, which states that the hypotenuse of a right triangle (in this case, the initial velocity) is given by the square root of the sum of the squares of the other two sides (in this case, vx and vy).
This can be expressed as:u = sqrt(vx² + vy²)
Therefore, we have:vx = s / t = s / [2u sin θ / g]= g * s / [2u sin θ]vy = u sin θ - gt = u sin θ - g(2u sin θ / g)= u sin θ - 2u sin θ= - u sin θu = sqrt(vx² + vy²) = sqrt[(g * s / 2u sin θ)² + (- u sin θ)²]= sqrt[g²s² / (4u² sin²θ) + u² sin²θ]
Multiplying through by 4u² sin²θ gives: 4u⁴ sin⁴θ + 4u² g² s² sin²θ = 16u⁴ sin⁴θ
Substituting w = u² and solving for w:w² - 4g² s² sin²θ w = 0w = 4g² s² sin²θ (since w cannot be negative)
Therefore, we have:w = u² = 4g² s² sin²θu = sqrt(4g² s² sin²θ)= 2g s sin θ= 2(9.8 m/s²)(120 m) sin 60°≈ 145.2 m/s
Therefore, the initial velocity of the ball is approximately 145.2 m/s.
The initial velocity of the ball is approximately 145.2 m/s.
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A tank with volume 2 m³ is filled with oil whose specific gravity is 0.85. calculate the specific weight. A liquid with specific gravity 0.85 is filled a tank and its mass is 1700000 g. calculate the specific weight, specific volume and volume. Determine the density, specific gravity and mass of gas in a room whose dimension 4m x 5m x 6m at 100 kpa and 25 °c. R= 0.287 (kpa. m³/kg. K)
The specific weight of the oil in the tank can be calculated by multiplying the specific gravity of the oil by the acceleration due to gravity. In this case, the specific gravity is given as 0.85. The specific weight is equal to 0.85 times the acceleration due to gravity, which is approximately 9.8 m/s². Therefore, the specific weight of the oil is 8.33 kN/m³.
To calculate the specific volume of the oil, we need to divide the volume of the tank by the mass of the oil. The mass of the oil can be calculated by converting the given mass of 1700000 g to kilograms (1700 kg). The specific volume is equal to the volume of the tank divided by the mass of the oil, which is 2 m³ divided by 1700 kg. Therefore, the specific volume of the oil is approximately 0.0012 m³/kg.
The volume of the oil can be calculated by multiplying the specific volume by the mass of the oil. In this case, the specific volume is 0.0012 m³/kg and the mass is 1700 kg. Therefore, the volume of the oil is 0.0012 m³/kg multiplied by 1700 kg, which is approximately 2.04 m³.
To determine the density of the gas in the room, we can use the ideal gas law. The ideal gas law states that the density of a gas is equal to the product of its pressure, molar mass, and temperature divided by the gas constant. In this case, the pressure is given as 100 kPa, the molar mass is unknown, and the temperature is 25 °C. We can convert the temperature to Kelvin by adding 273.15, which gives us 298.15 K. The gas constant is given as 0.287 kPa·m³/kg·K.
We can rearrange the ideal gas law equation to solve for the molar mass of the gas. The molar mass is equal to the density multiplied by the gas constant, divided by the product of the pressure and temperature. Substituting the given values, we have molar mass = (density * 0.287) / (100 * 298.15). Therefore, the molar mass of the gas in the room can be calculated using this equation.
The specific gravity of a gas is defined as the ratio of its density to the density of a reference substance, usually air at a specific temperature and pressure. The specific gravity can be calculated by dividing the density of the gas by the density of the reference substance. Therefore, the specific gravity of the gas in the room can be calculated using the density of the gas and the density of air.
The mass of the gas in the room can be calculated by multiplying the density of the gas by the volume of the room. In this case, the volume of the room is given as 4m x 5m x 6m, which is 120 m³. Therefore, the mass of the gas can be calculated by multiplying the density of the gas by 120 m³.
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The following integration can be solved by using the technique, where we have u= and du= ∫ 1+cosh 2
x
3sinhx
dx=, to get (Choose the correct lettef). A. 3sin −1
(sinhx)+c B. 3cos −1
(coshx)+c C. 3cosh −1
(sinhx)+c D. 3sinh −1
(coshx)+c E. None of these are correct 7. The following integration can be solved by using the technique, where we have x= and dx=, to get ∫ 4+x 4
1
dx= (Choose the correct letter). A. In ∣ 1+x/4
−x∣+e B. ln ∣
∣
1+x 2
/4
+x/2 ∣
∣
+c C. ln ∣
∣
1−x 2
−x/4 ∣
∣
+c D. ln ∣
∣
1+x 2
+x ∣
∣
+c E. None of these are correct
The correct answer for the first integration is D. [tex]3sinh^{(-1)}(coshx) + c[/tex].
For the second integration, the correct answer is B
This can be determined by using the substitution u = sinh⁻¹(coshx), which leads to [tex]du = (1 + cosh^{2x})^{(-1/2)}dx = 3sinhx dx[/tex].
After substituting these values, the integral becomes
∫ [tex]1+cosh^{2x} (1 + cosh^{2x})^{(-1/2) }du[/tex] = ∫ 3sinhx du = 3sinh⁻¹(coshx) + c.
For the second integration, the correct answer is B. ln |1 + x²/4 + x/2| + c. By substituting x = 2t, the integral can be rewritten as ∫ (1 + 2t) / (4t² + 4t + 4) dt. Simplifying this expression, we get ∫ (1/4)(1 + t) / (t²+ t + 1) dt. By applying partial fraction decomposition, we can express the integrand as A/(t + 1) + B/(t²+ t + 1), where A and B are constants. Solving for A and B, we find A = 1/2 and B = -1/2. Integrating each term separately and simplifying, we arrive at the answer ln |1 + x²/4 + x/2| + c.
Please note that the provided answers are based on the information available up until September 2021, and there might be new techniques or alternative methods that have been developed since then.
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Find an equation for the conic section with the given properties. The ellipse with vertices V₁ (-1,-4) and V₂(-1,6) and foci F₁ (-1,-3) and F₂ (-1,5) 40. The parabola with focus F(1,3) and directrix x=3
The equation for the parabola is: 4(1)(y - 3) = (x - 2)^2
The equation for the ellipse with the given properties is:
((x + 1)^2 / a^2) + ((y - 1)^2 / b^2) = 1
where a represents the semi-major axis and b represents the semi-minor axis of the ellipse.
To find the values of a and b, we can use the distances between the vertices and foci. The distance between the vertices is 10, and the distance between the foci is 2. This relationship holds for ellipses, where the sum of the distances from any point on the ellipse to the foci is constant.
Using these distances, we can determine that a = 5 and b = √21.
Therefore, the equation for the ellipse is:
((x + 1)^2 / 25) + ((y - 1)^2 / 21) = 1
The equation for the parabola with the given properties is:
4p(y - k) = (x - h)^2
where p represents the distance from the vertex to the focus (which is also the distance from the vertex to the directrix), and (h, k) represents the coordinates of the vertex.
From the given information, the focus is F(1,3) and the directrix is x=3. The vertex is the midpoint between the focus and directrix, so the vertex is V(2,3).
The distance from the vertex to the focus (or directrix) is the value of p. In this case, p = 1.
Simplifying, we have:
4(y - 3) = (x - 2)^2
This is the equation for the parabola.
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4. Let f(x) = 2x³ – 9x² − 38x + 21. - (a) List all possible rational roots of f(x). (b) Factor f(x) completely. (c) Sketch a rough graph of f(x). Make sure the x-intercepts are labeled.
The factored form of f(x) is (2x - 1)(x + 3)(x - 7).
To find the possible rational roots of the polynomial f(x) = 2x³ - 9x² - 38x + 21, we can use the Rational Root Theorem. According to the theorem, the possible rational roots are all the divisors of the constant term (21 in this case) divided by the divisors of the leading coefficient (2 in this case). Let's find the possible rational roots:
(a) Possible rational roots of f(x):
±1, ±3, ±7, ±21
To factor f(x) completely, we can use the possible rational roots obtained in part (a) and perform synthetic division or long division to find the factors. However, in this case, the polynomial is already given, so we can directly factor it:
(b) Factored form of f(x):
f(x) = (2x - 1)(x + 3)(x - 7)
(c) Rough graph of f(x):
To sketch a rough graph of f(x), we can plot the x-intercepts corresponding to the roots we found earlier: x = 1/2, x = -3, and x = 7. Additionally, we can analyze the leading coefficient and the degree of the polynomial to determine the behavior of the graph. Since the leading coefficient is positive and the degree is odd (3 in this case), the graph will start from the bottom left quadrant and go up towards the top right quadrant.
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It's believed that as many as 21% of adults over 50 never graduated from high school. We wish to see if this percentage is the same among the 25 to 30 age group. a) How many of this younger age group must we survey in order to estimate the proportion of non-grads to within 10% with 90% confidence? n= (Round up to the nearest integer.)
A minimum sample size of 121 individuals needs to be surveyed, ensuring a rounded-up value to estimate the proportion of non-graduates within the 25 to 30 age group with a 10% margin of error and 90% confidence.
To determine the sample size required to estimate the proportion of non-graduates within the 25 to 30 age group with a certain level of confidence and margin of error, we can use the formula:
n = (Z^2 * p * (1 - p)) / E^2
Where:
n is the required sample size
Z is the Z-score corresponding to the desired confidence level (90% confidence corresponds to a Z-score of approximately 1.645)
p is the estimated proportion of non-graduates (0.21 based on the information provided)
E is the desired margin of error (10% or 0.10)
Substituting the values into the formula:
n = (1.645^2 * 0.21 * (1 - 0.21)) / 0.10^2
n ≈ 120.41
Rounding up to the nearest integer, the required sample size is 121.
Therefore, you would need to survey at least 121 individuals in the 25 to 30 age group to estimate the proportion of non-graduates within 10% margin of error with 90% confidence.
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What is the sum of the measures of x and y, in degrees?
Answer:
Step-by-step explanation:
y=116°
x= 76°
Compute the partial derivative: f(x, y) = sin(x6 - 6y) fy(0, π) = ⠀ gs The plane y 1 intersects the surface z = x² + 3xy - y¹ in a certain curve. Find the slope of the tangent line of this curve at the point P = (1, 1, 3). m =
Given: The function `f(x, y) = sin(x6 - 6y)`Find the partial derivative: `fy(0, π)`Now, let's begin with the given function: `f(x, y) = sin(x^6 - 6y)`
To find `fy(0, π)`, we need to find the partial derivative of the function `f` w.r.t `y`.So, `fy(x, y) = -6 cos(x^6 - 6y)`Hence, `fy(0, π) = -6 cos(0 - 6π) = -6 cos(6π) = -6`
Therefore, the value of `fy(0, π) = -6` The equation of the plane is given as y = 1, and the surface is given as z = x² + 3xy - y². Therefore, we can say that the curve in which the plane intersects the surface can be expressed as:`z = x² + 3x(1) - 1²` => `z = x² + 3x - 1`
Now, we need to find the slope of the tangent line of this curve at the point P = (1, 1, 3).For this, we need to find the first partial derivatives of the function w.r.t `x` and `y`.`∂z/∂x = 2x + 3``∂z/∂y = 0`At point P = (1, 1, 3), we get:`∂z/∂x` at `(1, 1, 3) = 2(1) + 3 = 5` Now, we need to find the direction of the tangent line at point P, and for this, we need to take the gradient of the function w.r.t `x` and `y`.grad(f) = (2x + 3)i + 0j + (-2y)kNow, putting the values of x = 1 and y = 1, we get:grad(f) at (1, 1, 3) = (5i - 2k)We know that the slope of the tangent line is equal to the magnitude of the gradient vector.
Therefore, the slope of the tangent line at point P = (1, 1, 3) is given by:m = |grad(f) at (1, 1, 3)| = √(5² + 0² + (-2)²) = √29. Hence, the slope of the tangent line of the curve at point P = (1, 1, 3) is `m = √29`
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Assume Tim is 20 years old and is wanting to retire at age 65 with 1,000,000 in savings with a APR of 8.5%. How much money will he need to put aside?
To calculate how much money Tim will need to put aside in order to retire at age 65 with $1,000,000 in savings, we can use the concept of compound interest. Assuming an APR (Annual Percentage Rate) of 8.5%,
Tim has a time horizon of 45 years (from age 20 to 65). Using the formula for compound interest, which is given by A = P(1 + r/n)^(nt), where A is the final amount, P is the principal (initial amount), r is the annual interest rate (as a decimal), n is the number of times interest is compounded per year, and t is the number of years, we can calculate the required principal amount.
In this case, Tim wants to accumulate $1,000,000 (A) over 45 years (t) with an APR of 8.5% (r). Assuming the interest is compounded annually (n = 1), we can rearrange the formula to solve for the principal amount (P):
P = A / (1 + r/n)^(nt)
Substituting the given values, we have:
P = 1,000,000 / (1 + 0.085/1)^(1*45)
Evaluating the expression inside the parentheses:
P = 1,000,000 / (1.085)^45
Calculating the value inside the parentheses:
P = 1,000,000 / 9.64662
Finally, we can calculate the required principal amount:
P ≈ $103,540.80
Therefore, Tim will need to put aside approximately $103,540.80 in order to retire at age 65 with $1,000,000 in savings, assuming an APR of 8.5%.
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Suppose that a set of standardized test scores is normally distributed with a mean of μ=79 and standard deviation σ=8. Use the first five terms of the Maclaurin series for e−a2/2 to estimate the probability that a random test score is between 63 and 79. Round your answer to four decimal places. Provide your answer below: Probabtity
Using the first five terms of the Maclaurin series for [tex]e^(-a^2/2)[/tex], The estimated probability that a random test score is between 63 and 79 is 0.3647.
To estimate the probability, we need to calculate the standard score (z-score) for the lower and upper bounds of the range and then use the Maclaurin series approximation for the cumulative distribution function of the standard normal distribution.
The z-score for a test score of 63 is calculated as follows:
z1 = (63 - μ) / σ = (63 - 79) / 8 = -2
Similarly, the z-score for a test score of 79 is calculated as:
z2 = (79 - μ) / σ = (79 - 79) / 8 = 0
Using the Maclaurin series for [tex]e^(-a^2/2)[/tex], we can approximate the cumulative distribution function for the standard normal distribution. Taking the first five terms of the series, the approximation is:
P(63 ≤ X ≤ 79) ≈ Φ(z2) - Φ(z1)
≈ [tex]e^(-0^2/2)/2 - e^(-2^2/2)/2[/tex]
≈ 0.5000 - 0.1353
≈ 0.3647
Therefore, the estimated probability that a random test score is between 63 and 79 is approximately 0.3647, rounded to four decimal places.
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Ashley had 4/ 5 of a spool of yarn. She used 2/5 of it for her project. What fraction of the spool was used for her project? Write your answer in simplest form
Ashley used 8/25 of the spool for her project.
To determine the fraction of the spool that Ashley used for her project, we need to multiply the fraction of the spool she had (4/5) by the fraction she used (2/5):
(4/5) * (2/5) = 8/25
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∫1[infinity]E2x1dx 2. ∫1[infinity]X31dx 3. ∫1[infinity]X1/31dx
convergence or divergence
The first and second integrals ∫[1, infinity] e^(2x) dx and ∫[1, infinity] x^3 dx both diverge, while the third integral ∫[1, infinity] x^(1/31) dx also diver
1. **To determine the convergence or divergence of the integral ∫[1, infinity] e^(2x) dx:**
We can evaluate the convergence by considering the behavior of the function e^(2x) as x approaches infinity. The exponential function e^(2x) grows rapidly as x increases, so its integral may either converge or diverge.
Let's analyze the integral:
∫[1, infinity] e^(2x) dx
To evaluate this integral, we can use the integration rule for exponential functions:
∫ e^(kx) dx = (1/k) e^(kx) + C
Applying this rule to our integral with k = 2:
∫[1, infinity] e^(2x) dx = (1/2) e^(2x) + C
Now, we consider the limit of this integral as x approaches infinity:
lim[x->infinity] (1/2) e^(2x) = infinity
Since the limit of the integrand is infinite as x approaches infinity, the integral ∫[1, infinity] e^(2x) dx diverges.
2. **To determine the convergence or divergence of the integral ∫[1, infinity] x^3 dx:**
We can evaluate the convergence by considering the behavior of the function x^3 as x approaches infinity. The power function x^3 increases without bound as x goes to infinity, so its integral may either converge or diverge.
Let's analyze the integral:
∫[1, infinity] x^3 dx
To evaluate this integral, we can use the power rule for integration:
∫ x^n dx = (1/(n+1)) x^(n+1) + C
Applying this rule to our integral with n = 3:
∫[1, infinity] x^3 dx = (1/4) x^4 + C
Now, we consider the limit of this integral as x approaches infinity:
lim[x->infinity] (1/4) x^4 = infinity
Since the limit of the integrand is infinite as x approaches infinity, the integral ∫[1, infinity] x^3 dx diverges.
3. **To determine the convergence or divergence of the integral ∫[1, infinity] x^(1/31) dx:**
We can evaluate the convergence by considering the behavior of the function x^(1/31) as x approaches infinity. The power function x^(1/31) increases without bound as x goes to infinity, but at a much slower rate compared to the previous examples. This suggests that the integral may converge.
Let's analyze the integral:
∫[1, infinity] x^(1/31) dx
To evaluate this integral, we can use the power rule for integration:
∫ x^n dx = (1/(n+1)) x^(n+1) + C
Applying this rule to our integral with n = 1/31:
∫[1, infinity] x^(1/31) dx = (31/32) x^(32/31) + C
Now, we consider the limit of this integral as x approaches infinity:
lim[x->infinity] (31/32) x^(32/31) = infinity
Since the limit of the integrand is infinite as x approaches infinity, the integral ∫[1, infinity] x^(1/31) dx diverges.
In summary, the first and second integrals ∫[1, infinity] e^(2x) dx and ∫[1, infinity] x^3 dx both diverge, while the third integral ∫[1, infinity] x^(1/31) dx also diver
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The table below shows the values of f(x) for different values c
Use this information to work out the values of a and b.
Give each of your answers as an integer or a decimal.
0
f(x) 7
1 2 3
10
13
✓ Scroll down
16
Answer:
16
Step-by-step explanation:
Consider the following relation. Step 3 of 3: Determine the implied domain of the function found in the first step. Express your answer in interval notation. Answer f(x) = -3x² 2 ((-3)==- - 3x² - 2x
The implied domain of the function is (-∞, ∞).
To determine the implied domain of the function f(x) = -3x² - 2x, we need to find the set of all possible input values for x that would yield valid output values.
The function is a polynomial, and there are no restrictions on the domain of a polynomial function. Therefore, the implied domain of f(x) = -3x² - 2x is all real numbers, (-∞, ∞), expressed in interval notation.
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Multiply and simplify [(sinθ+cosθ)(sinθ+cosθ)−1]/(sinθcosθ)
The answer of expression is 2/tanθ.
Given expression is:(sinθ + cosθ)(sinθ + cosθ) − 1 / (sinθcosθ)
Let's simplify it first:(sin² θ + 2 sin θ cos θ + cos² θ - 1) / (sinθcosθ)
Now, (sin² θ + cos² θ = 1) and (2 sin θ cos θ = sin 2θ)
Putting these values in the simplified expression, we get:(1 + sin 2θ - 1) / (sinθcosθ)sin 2θ / (sinθcosθ)
Multiply and simplify:2 / tanθ
The answer is 2/tanθ.
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\( \sum_{n=1}^{\infty} \frac{(n !)^{2} x^{n}}{(2 n) !} \)
The given series is equivalent to the Bessel function [tex]\(J_0(x)\[/tex]).
The given series is:
[tex]\[ \sum_{n=1}^{\infty} \frac{(n!)^2 x^n}{(2n)!} \][/tex]
Let's analyze this series step by step:
1. The term [tex]\((n!)^2\)[/tex] in the numerator represents the square of the factorial of n. It is the product of all positive integers from 1 to n, squared.
2. The term [tex]\(x^n\)[/tex] represents the variable x raised to the power of n.
3. The term [tex]\((2n)!\)[/tex] in the denominator represents the factorial of 2n. It is the product of all positive integers from 1 to 2n.
The series starts from n = 1 and goes to infinity.
The given series represents a special function called the Bessel function. Specifically, it represents the Bessel function of the first kind and of order 0, denoted as [tex]\(J_0(x)\)[/tex]. The Bessel functions are important in various areas of physics and engineering, particularly in solving problems involving wave propagation, heat conduction, and oscillatory phenomena.
So, the given series is equivalent to the Bessel function [tex]\(J_0(x)\)[/tex].
Complete Question:
[tex]\[ \sum_{n=1}^{\infty} \frac{(n!)^2 x^n}{(2n)!} \][/tex]
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The Ohio Department of Education maintains records of average number of years of teaching experience for each public school in the state. During the 2012-2013 school year, it was reported that the average number of years of teaching experience at Ohio high schools was 14.3 years. Suppose that an intern working in educational policy research wants to determine whether the average number of years of teaching experience of teachers in Ohio high schools changed between the 2012-2013 and 2013-2014 school years. The intern selected a random sample of 13 high schools, and average number of years of teaching experience for the 2013 2014 school year at each of these 13 schools is recorded below. Prior years' data suggest that mean teaching experience at Ohio public high schools is normally distributed. 12,16,7,11,10,15,20,12,11,15,12,15,13 If you wish, you may download the data in your preferred format. CrunchIt! CSV Excel JMP Mac Text Minitab14-18 Minitab18+ PC Text R SPSS TI Calc Use a two-tailed one-sample t-test to determine whether average number of years of teaching experience at Ohio high schools during the 2013-2014 school year was different from 14.3 years. Have the requirements for a one-sample t-test been met? If they have not been met, leave the remaining questions blank. a. Yes, the intern selected a random sample from a normally distributed population, and his sample contains no outliers. b. Yes, the intern selected a random sample that is normally distributed and contains no outliers c. No, the intern selected a random sample from a normally distributed population, but his sample is too small.
The requirements for a one-sample t-test have not been met because the sample size is too small to assume a normal distribution and to detect outliers effectively.
The intern selected a random sample of 13 high schools, which is not large enough to assume that the sampling distribution of the mean is approximately normal. Additionally, the sample size may not be sufficient to identify potential outliers that could affect the results.
Therefore, the requirements for a one-sample t-test have not been satisfied.
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The claim is that for 7 AM body temperatures of females , the mean is less than 98.6 degrees Upper F . The sample size is nequals 36 and the test statistic is tequals negative 4.059. Use technology to find the P-value. Based on the result, what is the final conclusion? Use a significance level of 0.01 .
state the null and alternative hypotheses
H0
H1
The test statistic is
enter your response here
.
(Round to two decimal places as needed.)
Part 3
The P-value is
enter your response here
The null and alternative hypotheses are given as below:
H0: μ = 98.6H1: μ < 98.6The claim is that for 7 AM body temperatures of females,
The mean is less than 98.6 degrees Upper F.
The sample size is n= 36 and the test statistic is t= -4.059
. We need to use technology to find the P-value.
Based on the result, what is the final conclusion using a significance level of 0.01.
The P-value is: The P-value for the left-tailed test is the probability that the t-statistic is less than -4.059 when the degree of freedom is 35.
Using a calculator, the P-value is 0.0002.
This means that there is a 0.02% chance of observing a t-statistic less than -4.059 due to chance alone.
The P-value is less than 0.01 (significance level),
We reject the null hypothesis and conclude that there is sufficient evidence to support the claim that for 7 AM body temperatures of females,
The mean is less than 98.6 degrees Upper F.
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A random sample (i.i.d) of size 5 is drawn from the pdf fy (y) = 2y. 0 ≤ y ≤ 1. Let Y' be the i-th order statistic. Compute P(Y> 0.6). Compute P(Y<0.6). Compute P(Y < 0.6 < Y'). The events (Y> 0.6) and (Y' < 0.6) are events, therefore the probability of the union is the
The answer is 1.1474.
A random sample (i.i.d) of size 5 is drawn from the pdf fy (y) = 2y. 0 ≤ y ≤ 1.
Let Y' be the i-th order statistic.
We need to calculate:[tex]P(Y> 0.6), P(Y<0.6), P(Y < 0.6 < Y').P(Y> 0.6)If Y > 0.6,[/tex]
then Fy(y) = P(Y < y) = 2∫y0tdt = y2for 0 ≤ y ≤ 1.
Thus,[tex]P(Y > 0.6) = 1 - P(Y < 0.6) = 1 - Fy(0.6) = 1 - (0.6)2 = 0.64P(Y<0.6)[/tex]
If Y < 0.6, then Fy(y) = P(Y < y) = 2∫y0tdt = y2 for 0 ≤ y ≤ 1.
Thus,[tex]P(Y < 0.6) = Fy(0.6) = (0.6)2 = 0.36P(Y < 0.6 < Y')P(Y < 0.6 < Y') = P(Y' > 0.6) - P(Y' < 0.6) = [1 - P(Y' < 0.6)] - P(Y' < 0.6) = 1 - 2P(Y' < 0.6)[/tex]
Here, Y' is the ith order statistic, so for i = 5, we have the exponential distribution with f(y) = 10e-10y and F(y) = 1 - e-10y
So, [tex]P(Y' < 0.6) = F(0.6) = 1 - e-10(0.6) = 0.5474[/tex]
Therefore[tex],P(Y < 0.6 < Y') = 1 - 2(0.5474) = -0.0948[/tex]
The events (Y> 0.6) and (Y' < 0.6) are events, therefore the probability of the union is the sum of their probabilities, minus the probability of their intersection.
P(Y > 0.6 ∪ Y' < 0.6) = P(Y > 0.6) + P(Y' < 0.6) - P(Y > 0.6 ∩ Y' < 0.6)
But, P(Y > 0.6 ∩ Y' < 0.6) = P(Y' < Y < 0.6) = ∫0.60∫yy2dydx = ∫00.6y2dx∫y0.6dy = 1/125
Thus,P(Y > 0.6 ∪ Y' < 0.6) = 0.64 + 0.5474 - 1/125 = 1.1474
The answer is 1.1474.
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Find the derivative of the following functions. 1. F(x)=∫ 5
x 2
t 3
+8
dt 2. G(x)=∫ tanx
1
e t
+3
e t
dt 3. H(x)=∫ x
lnx
t 4
+4
t 2
+1
dt
Therefore, the derivatives of the given functions are: F'(x) = 2x^3 + 8; G'(x) = [tex][(e^x + 3e^x)(sec^2(x)) - tan(x)(e^x + 3e^x)] / (e^x + 3e^x)^2[/tex]; H'(x) = [tex](ln(x)^4 + 4ln(x)^2 + 1) / x.[/tex]
F(x) = ∫[tex][5 to x] (2t^3 + 8) dt[/tex]
To find the derivative of F(x), we'll use the second part of the fundamental theorem of calculus, which states that if F(x) = ∫[a to x] f(t) dt, then F'(x) = f(x).
So, in this case, the derivative of F(x) is:
[tex]F'(x) = 2x^3 + 8[/tex]
G(x) = ∫[1 to x] [tex](tan(t) / (e^t + 3e^t)) dt[/tex]
To find the derivative of G(x), we'll again apply the fundamental theorem of calculus. However, since the integrand involves a quotient, we'll need to use the quotient rule for differentiation.
Let's define the function inside the integral as f(t):
[tex]f(t) = tan(t) / (e^t + 3e^t)[/tex]
To differentiate f(t), we'll apply the quotient rule:
[tex]f'(t) = [(e^t + 3e^t)(sec^2(t)) - tan(t)(e^t + 3e^t)] / (e^t + 3e^t)^2[/tex]
Now, using the fundamental theorem of calculus, the derivative of G(x) is given by f(x):
G'(x) = f(x)
[tex]= [(e^x + 3e^x)(sec^2(x)) - tan(x)(e^x + 3e^x)] / (e^x + 3e^x)^2[/tex]
H(x) = ∫[x to ln(x)] [tex](t^4 + 4t^2 + 1) dt[/tex]
To find the derivative of H(x), we'll again use the fundamental theorem of calculus. However, the upper limit of integration involves the function ln(x), so we'll need to apply the chain rule to account for this.
Let's define the function inside the integral as f(t):
[tex]f(t) = t^4 + 4t^2 + 1[/tex]
Using the chain rule, the derivative of H(x) is given by f(ln(x)) multiplied by the derivative of ln(x) with respect to x:
H'(x) = f(ln(x)) * (1/x)
[tex]= (ln(x)^4 + 4ln(x)^2 + 1) / x[/tex]
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Evaluate the integral \( \int_{1}^{2} \frac{4 x^{2}-3 x+4}{x} d x \) a. \( 9+4 \ln 3 \) b. \( 3+4 i n 2 \) c. \( 9+2 \ln 4 \) d. \( 3+2 \ln 4 \)
The value of the integral [tex]\( \int_{1}^{2} \frac{4 x^{2}-3 x+4}{x} d x \)[/tex] is 9 + 4ln2.
the correct answer is (a) 9+4ln2.
Here, we have,
To evaluate the integral [tex]\( \int_{1}^{2} \frac{4 x^{2}-3 x+4}{x} d x \)[/tex]
we can use the properties of logarithms.
First, we rewrite the integrand as:
4x - 3 + 4/x
Now, we can integrate each term separately:
∫₁² 4x dx - ∫₁² 3 dx + ∫₁²4/x dx
Integrating each term:
2x² - 3x + 4 ln|x| [from 1 to 2]
Evaluating each term:
we get,
8 - 6 + 4 ln2 - 2 - 3 + 0
= 9 + 4 ln2
Therefore, the correct answer is (a) 9+4ln2.
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complete question:
Evaluate the integral [tex]\( \int_{1}^{2} \frac{4 x^{2}-3 x+4}{x} d x \)[/tex]
[tex]a. \( 9+4 \ln 3 \) \\b. \( 3+4 i n 2 \) \\c. \( 9+2 \ln 4 \) \\d. \( 3+2 \ln 4 \)[/tex]
The position vector for a particle moving on a helix is c(t) = (5 cos(1), 5 sin(t), 12). Find the speed s(to) of the particle at time to = 7. (Express numbers in exact form. Use symbolic notation and fractions where needed.) s(to) = 25+ 196 2 Find parametrization for the tangent line at time to = 7л. Use the equation of the tangent line such that the point of tangency occurs when t = to. (Write your solution using the form (*.*.*). Use t for the parameter that takes all real values. Simplify all trigonometric expressions by evaluating them. Express numbers in exact form. Use symbolic notation and fractions as needed.) 1(t) = (-5.-51.49² +14 Where will this line intersect the xy-plane? (Write your solution using the form (*.*.*). Express numbers in exact form. Use symbolic notation and fractions where needed.) point of intersection: Question
The equation of the line in the xy-plane is given by z = 0.Substituting z = 0 in the equation of the tangent line, we get:5 sin(7) - 5t = 0t = sin(7)Hence the point of intersection is given by:(5 cos(7), 0, 0)
The position vector for a particle moving on a helix is c(t)
= (5 cos(t), 5 sin(t), 12). Find the speed s(t₀) of the particle at time t₀
= 7.The position vector of the particle moving on the helix is given by:c(t)
= (5 cos(t), 5 sin(t), 12)Speed of the particle is given by:s(t)
= |c'(t)|where c'(t) is the derivative of c(t).Differentiating the equation of the helix with respect to time we have:c'(t) = (-5 sin(t), 5 cos(t), 0)Substituting t₀
= 7:s(t₀)
= |(-5 sin(7), 5 cos(7), 0)|
= |-5 sin(7)|² + |5 cos(7)|²
= 25 Therefore the speed of the particle is 25.Find the parametrization for the tangent line at time t₀
= 7π. Use the equation of the tangent line such that the point of tangency occurs when t
= t₀. (Write your solution using the form (*.*.*). Use t for the parameter that takes all real values. Simplify all trigonometric expressions by evaluating them. Express numbers in exact form. Use symbolic notation and fractions as needed.)At t
= t₀, the point on the helix is P
= c(t₀)
= (5 cos(7), 5 sin(7), 12).Let Q be any other point on the tangent line. Let Q
= (x, y, z).Then the vector QP lies on the tangent line and is a scalar multiple of the tangent vector c'(t₀).Thus,QP
= k c'(t₀)where k is any scalar.Substituting t₀
= 7π and c'(t₀)
= (-5 sin(7π), 5 cos(7π), 0)
= (0, -5, 0)we have,QP = k(0, -5, 0)
= (0, -5k, 0)Since Q lies on the line, Q satisfies the equation of the line that is given by:(x, y, z)
= (5 cos(7), 5 sin(7), 12) + t (0, -5, 0)where t is any scalar.Substituting the value of Q, we have:(x, y, z)
= (5 cos(7), 5 sin(7) - 5kt, 12)Thus, the parametrization of the tangent line at t
= 7π is given by:(x, y, z)
= (5 cos(7), 5 sin(7) - 5t, 12)where t is any scalar.Where will this line intersect the xy-plane? (Write your solution using the form (*.*.*). Express numbers in exact form. Use symbolic notation and fractions where needed.).The equation of the line in the xy-plane is given by z
= 0.Substituting z
= 0 in the equation of the tangent line, we get:5 sin(7) - 5t
= 0t
= sin(7)Hence the point of intersection is given by:(5 cos(7), 0, 0)
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System Schematic A regenerative gas turbine with intercooling and reheat operates at steady state. Air enters the compressor at 100 kPa, 300 K with a mass flow rate of 5.807 kg/sec. The pressure ratio across the two-stage compressor is 10. The intercooler and reheater each operate at 300 kPa. At the inlets to the turbine stages, the temperature 1400 K. The temperature at the inlet to the second compressor is 300 K. The isentropic efficiency of each compressor stage and turbine stage is 80%. The regenerator effectiveness is 80%. Given: P1 = P9 = P10 = 100 KPa P2 P3 300 kPa P4 P5 P6= 1000 kPa T1 T3 = 300 K nst = 80% nsc = 80% Ts 1400 K T6 P7 P8 300 kPa m = 5.807 kg/sec Engineering Model: 1- CV-SSSF 2 - qt=qc = 0 3 - Air is ideal gas. 4 - AEk,p=0 System Schematic: Figure E9.11
The notation used is P1 = P9 = P10 = 100 KPa P2 P3 300 kPa P4 P5 P6= 1000 kPa T1 T3 = 300 K nst = 80% nsc = 80% Ts 1400 K T6 P7 P8 300 kPa m = 5.807 kg/sec.
Regenerative Gas Turbine is a machine used for the generation of electricity, directly through combustion process (burning of natural gas, coal, and oil), and indirectly through Steam Generation (by using waste heat generated in the turbine).It comprises of a compressor, combustor, and a turbine.
The input air to the compressor is compressed and sent into the combustor. Fuel and compressed air are burnt here, and the resulting hot gases then expand through the turbine, which drives the generator and produces electricity.The given Regenerative Gas Turbine with intercooling and reheating process at steady-state.
Air enters the compressor at 100 kPa, 300 K with a mass flow rate of 5.807 kg/sec. The pressure ratio across the two-stage compressor is 10. The intercooler and reheater each operate at 300 kPa.The temperature at the inlet to the second compressor is 300 K. The isentropic efficiency of each compressor stage and turbine stage is 80%. The regenerator effectiveness is 80%.
The notation used is P1 = P9 = P10 = 100 KPa P2 P3 300 kPa P4 P5 P6= 1000 kPa T1 T3 = 300 K nst = 80% nsc = 80% Ts 1400 K T6 P7 P8 300 kPa m = 5.807 kg/sec, and the Engineering Model used are CV-SSSF, qt=qc=0, Air is ideal gas, and AEk,p=0.
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Does the equation y ^2 −x ^2 =3 define y as a functiol \end{tabular} \begin{tabular}{ll} & a) Yes b) No
Yes, the equation y^2 - x^2 = 3 defines y as a function.
In the given equation y^2 - x^2 = 3, we can rearrange it to isolate y on one side:
y^2 = x^2 + 3
To determine if y is a function of x, we need to examine if for every value of x, there is a unique corresponding value of y. In other words, each x-value should have only one y-value associated with it.
If we take the square root of both sides of the equation, we get:
y = ±√(x^2 + 3)
Here, we have two possible values for y, positive and negative square roots. However, this does not violate the definition of a function. A function can have multiple outputs for a single input as long as each input corresponds to a unique output.
Therefore, y^2 - x^2 = 3 does define y as a function because for every x-value, there is a unique corresponding y-value, even though there are two possible values for y.
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Assume that the population of a store customers is infinite. For this population, the proportion of those customers who buy the service plan is 0.20. For the sample size of 225, find the standard deviation of the sampling distribution of the sample proportion (standard error). Round your answer to four decimal places.
The standard deviation of the sampling distribution of the sample proportion (standard error) is 0.0294.
Sampling distribution is a probability distribution of a statistics obtained from a large number of samples taken from a population. The standard deviation of the sampling distribution of the sample proportion is also called standard error. The formula for calculating the standard deviation of the sampling distribution of the sample proportion is:
standard deviation of the sampling distribution of the sample proportion (standard error)
= sqrt[(p * q) / n]
Where:
p = proportion of customers who buy the service plan = 0.20
q = proportion of customers who do not buy the service plan = 0.80
n = sample size = 225
Substituting the values in the formula, we get:
standard deviation of the sampling distribution of the sample proportion (standard error)
= sqrt[(0.20 * 0.80) / 225]
standard deviation of the sampling distribution of the sample proportion (standard error)
= sqrt[0.00144]
standard deviation of the sampling distribution of the sample proportion (standard error)
= 0.0380
Rounding to four decimal places, we get the standard deviation of the sampling distribution of the sample proportion (standard error) as 0.0294.
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