The equation of the curve that passes through the point (2, 3) and has a slope of ye at any point (x, y), where y > 0, is given by the equation y = 3e^(2x - 2).
The equation y = 3e^(2x - 2) represents an exponential curve. In this equation, e represents the mathematical constant approximately equal to 2.71828. The term (2x - 2) inside the exponential function indicates that the curve is increasing or decreasing exponentially as x varies. The coefficient 3 in front of the exponential function scales the curve vertically.
The point (2, 3) satisfies the equation, indicating that when x = 2, y = 3. The slope of the curve at any point (x, y) is given by ye, where y is the y-coordinate of the point. This ensures that the slope of the curve depends on the y-coordinate and exhibits exponential growth or decay.
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Type the correct answer in the box. Write your answer as a whole number.
The radius of the base of a cylinder is 10 centimeters, and its height is 20 centimeters. A cone is used to fill the cylinder with water. The radius of the
cone's base is 5 centimeters, and its height is 10 centimeters.
The number of times one needs to use the completely filled cone to completely fill the cylinder with water is
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To completely fill the cylinder with water, 24 full turns of the fully filled cone are required.
To find the number of times the cone needs to be used to completely fill the cylinder, we need to compare the volumes of the cone and the cylinder.
The following formula can be used to determine a cylinder's volume:
Volume of Cylinder = π * [tex]radius^2[/tex] * height
The formula for the volume of a cone is:
Volume of Cone = (1/3) * π *[tex]radius^2[/tex] * height
Given:
Radius of the cylinder's base = 10 cm
Height of the cylinder = 20 cm
Radius of the cone's base = 5 cm
Height of the cone = 10 cm
Let's calculate the volumes of the cylinder and the cone:
Volume of Cylinder = π *[tex](10 cm)^2[/tex] * 20 cm
Volume of Cylinder = π * [tex]100 cm^2[/tex] * 20 cm
Volume of Cylinder = 2000π [tex]cm^3[/tex]
Volume of Cone = (1/3) * π * [tex](5 cm)^2[/tex] * 10 cm
Volume of Cone = (1/3) * π * [tex]25 cm^2[/tex] * 10 cm
Volume of Cone = (250/3)π [tex]cm^3[/tex]
To find the number of times the cone needs to be used, we divide the volume of the cylinder by the volume of the cone:
Number of times = Volume of Cylinder / Volume of Cone
Number of times =[tex](2000π cm^3) / ((250/3)π cm^3)[/tex]
Number of times = (2000/1) / (250/3)
Number of times = (2000/1) * (3/250)
Number of times = (2000 * 3) / 250
Number of times = 6000 / 250
Number of times = 24
Therefore, the number of times one needs to use the completely filled cone to completely fill the cylinder with water is 24.
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Use Cramer's Rule to solve the system of linear equations for x and y. kx + (1 k)y = 3 (1 k)X + ky = 2 X = y = For what value(s) of k will the system be inconsistent? (Enter your answers as a comma-separated list.) k= Find the volume of the tetrahedron having the given vertices. (5, -5, 1), (5, -3, 4), (1, 1, 1), (0, 0, 1)
Using Cramer's Rule, we can solve the system of linear equations for x and y. To find the volume of a tetrahedron with given vertices, we can use the formula involving the determinant.
1. System of linear equations: Given the system of equations: kx + (1-k)y = 3 -- (1) , (1-k)x + ky = 2 -- (2) We can write the equations in matrix form as: | k (1-k) | | x | = | 3 |, | 1-k k | | y | | 2 | To solve for x and y using Cramer's Rule, we need to find the determinants of the coefficient matrix and the matrices obtained by replacing the corresponding column with the constant terms.
Let D be the determinant of the coefficient matrix, Dx be the determinant obtained by replacing the first column with the constants, and Dy be the determinant obtained by replacing the second column with the constants. The values of x and y can be calculated as: x = Dx / D, y = Dy / D
2. Volume of a tetrahedron: To find the volume of the tetrahedron with vertices (5, -5, 1), (5, -3, 4), (1, 1, 1), and (0, 0, 1), we can use the formula: Volume = (1/6) * | x1 y1 z1 1 | , | x2 y2 z2 1 | , | x3 y3 z3 1 |, | x4 y4 z4 1 | Substituting the coordinates of the given vertices, we can calculate the volume using the determinant of the 4x4 matrix.
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Consider the function A) Prove that I is a linear transformation. B) Is T injective? Is T surjective? C) What is the basis for the range of T? D) Is T an isomorphism ? E) What is the nullity of T? F) Are the vector spaces IR, [x] and IR₂ [x] isomorphic ? TOIR, [x] → R₂ [x] given by T (a + bx) = 2a + (a+b)x + (a−b)x²
The function T: ℝ[x] → ℝ₂[x] given by T(a + bx) = 2a + (a+b)x + (a−b)x² is a linear transformation. It is injective but not surjective. The basis for the range of T is {2, x, x²}. T is not an isomorphism. The nullity of T is 0. The vector spaces ℝ, [x], and ℝ₂[x] are not isomorphic.
To prove that T is a linear transformation, we need to show that it satisfies two properties: additive and scalar multiplication preservation. Let's consider two polynomials, p = a₁ + b₁x and q = a₂ + b₂x, and a scalar c ∈ ℝ. We have:
T(p + cq) = T((a₁ + b₁x) + c(a₂ + b₂x))
= T((a₁ + ca₂) + (b₁ + cb₂)x)
= 2(a₁ + ca₂) + (a₁ + ca₂ + b₁ + cb₂)x + (a₁ + ca₂ - b₁ - cb₂)x²
= (2a₁ + a₁ + b₁)x² + (a₁ + ca₂ + b₁ + cb₂)x + 2a₁ + 2ca₂
Expanding and simplifying, we can rewrite this as:
= (2a₁ + a₁ + b₁)x² + (a₁ + b₁)x + 2a₁ + ca₂
= 2(a₁ + b₁)x² + (a₁ + b₁)x + 2a₁ + ca₂
= T(a₁ + b₁x) + cT(a₂ + b₂x)
= T(p) + cT(q)
Thus, T preserves addition and scalar multiplication, making it a linear transformation.
Next, we determine if T is injective. For T to be injective, every distinct input must map to a distinct output. If we set T(a + bx) = T(c + dx), we get:
2a + (a + b)x + (a − b)x² = 2c + (c + d)x + (c − d)x²
Comparing coefficients, we have a = c, a + b = c + d, and a − b = c − d. From the first equation, we have a = c. Substituting this into the second and third equations, we get b = d. Therefore, the only way for T(a + bx) = T(c + dx) is if a = c and b = d. Thus, T is injective.
However, T is not surjective since the range of T is the span of {2, x, x²}, which means not all polynomials in ℝ₂[x] can be reached.
The basis for the range o................f T can be determined by finding the linearly independent vectors in the range. We can rewrite T(a + bx) as:
T(a + bx) = 2a + ax + bx + (a − b)x²
= (2a + a − b) + (b)x + (a − b)x²
From this, we can see that the range of T consists of polynomials of the form c + dx + ex², where c = 2a + a − b, d = b, and e = a − b. The basis for this range is {2, x, x²}.
Since T is injective but not surjective, it cannot be an isomorphism. An isomorphism is a bijective linear transformation.
The nullity of T refers to the dimension of the null space, which is the set of all inputs that map to the zero vector in the range. In this case, the nullity of T is 0 because there are no inputs in ℝ[x] that map to the zero vector in ℝ₂[x].
Finally, the vector spaces ℝ, [x], and ℝ₂[x] are not isomorphic. The isomorphism between vector spaces preserves the structure, and in this case, the dimensions of the vector spaces are different (1, 1, and 2, respectively), which means they cannot be isomorphic.
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Find an equation of the tangent line to the curve at the point (, y()). Tangent line: y = ((-9sqrt(3)/2)x)-(9sqrt(3)/2) y = sin(7x) + cos(2x)
To find the equation of the tangent line to the curve y = sin(7x) + cos(2x) at the point (x, y), we need to find the derivative of the curve and evaluate it at the given point.
First, let's find the derivative of the curve with respect to x:
dy/dx = d/dx (sin(7x) + cos(2x)).
Applying the chain rule, we get:
dy/dx = 7cos(7x) - 2sin(2x).
Now, let's substitute the given point (x, y) into the derivative expression:
dy/dx = 7cos(7x) - 2sin(2x) = y'.
Since the derivative represents the slope of the tangent line, we can evaluate it at the given point (x, y) to find the slope of the tangent line.
Therefore, we have:
7cos(7x) - 2sin(2x) = y'.
Now, we can substitute the values of x and y into the equation:
7cos(7x) - 2sin(2x) = sin(7x) + cos(2x).
To simplify the equation, we rearrange the terms:
7cos(7x) - sin(7x) = 2sin(2x) + cos(2x).
Now, we can solve this equation to find the value of x.
Unfortunately, without the specific values of x and y, we cannot determine the equation of the tangent line or find the exact point of tangency.
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Find a function of the form yp = (a + bx)e^x that satisfies the DE 4y'' + 4y' + y = 3xe^x
A function of the form [tex]yp = (3/4)x^2 e^x[/tex] satisfies the differential equation [tex]4y'' + 4y' + y = 3xe^x[/tex].
Here, the auxiliary equation is [tex]m^2 + m + 1 = 0[/tex]; this equation has complex roots (-1/2 ± √3 i/2).
Therefore, the general solution to the homogeneous equation is given by:
[tex]y_h = c_1 e^(-^1^/^2^ x^) cos((\sqrt{} 3 /2)x) + c_2 e^(-^1^/^2 ^x^) sin((\sqrt{} 3 /2)x)[/tex] where [tex]c_1[/tex] and [tex]c_2[/tex] are arbitrary constants.
Now we will look for a particular solution of the form [tex]y_p = (a + bx)e^x[/tex] ; and hence its derivatives are [tex]y_p' = (a + (b+1)x)e^x[/tex] and [tex]y_p'' = (2b + 2)e^x + (2b+2x)e^x[/tex].
Substituting this in [tex]4y'' + 4y' + y = 3xe^x[/tex], we get:
[tex]4[(2b + 2)e^x + (2b+2x)e^x] + 4[(a + (b+1)x)e^x] + (a+bx)e^x[/tex] = [tex]3xe^x[/tex]
Simplifying and comparing coefficients of [tex]x_2[/tex] and [tex]x[/tex], we get:
[tex]a = 0[/tex] and [tex]b = 3/4[/tex]
Therefore, the particular solution is [tex]y_p = (3/4)x^2 e^x[/tex], and the general solution to the differential equation is: [tex]y = c_1 e^(^-^1^/^2^ x^) cos((\sqrt{} 3 /2)x) + c_2 e^(^-^1^/^2^ x) sin((\sqrt{} 3 /2)x) + (3/4)x^2 e^x[/tex], where [tex]c_1[/tex] and [tex]c_2[/tex] are arbitrary constants.
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A fundamental set of solutions for the differential equation (D-2)¹y = 0 is A. {e², ze², sin(2x), cos(2x)}, B. (e², ze², zsin(2x), z cos(2x)}. C. (e2, re2, 2²², 2³e²²}, D. {z, x², 1,2³}, E. None of these. 13. 3 points
The differential equation (D-2)¹y = 0 has a fundamental set of solutions {e²}. Therefore, the answer is None of these.
The given differential equation is (D - 2)¹y = 0. The general solution of this differential equation is given by:
(D - 2)¹y = 0
D¹y - 2y = 0
D¹y = 2y
Taking Laplace transform of both sides, we get:
L {D¹y} = L {2y}
s Y(s) - y(0) = 2 Y(s)
(s - 2) Y(s) = y(0)
Y(s) = y(0) / (s - 2)
Taking the inverse Laplace transform of Y(s), we get:
y(t) = y(0) e²t
Hence, the general solution of the differential equation is y(t) = c1 e²t, where c1 is a constant. Therefore, the fundamental set of solutions for the given differential equation is {e²}. Therefore, the answer is None of these.
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Convert to an exponential equation. logmV=-z The equivalent equation is (Type in exponential form.)
The given equation is log(mV) = -z. We need to convert it to exponential form. So, we have;log(mV) = -zRewriting the above logarithmic equation in exponential form, we get; mV = [tex]10^-z[/tex]
Therefore, the exponential equation equivalent to the given logarithmic equation is mV = [tex]10^-z[/tex]. So, the answer is option D.Explanation:To convert the logarithmic equation into exponential form, we need to understand that the logarithmic expression is an exponent. Therefore, we will have to use the logarithmic property to convert the logarithmic equation into exponential form.The logarithmic property states that;loga b = c is equivalent to [tex]a^c[/tex] = b, where a > 0, a ≠ 1, b > 0Example;log10 1000 = 3 is equivalent to [tex]10^3[/tex]= 1000
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Use the given conditions to write an equation for the line in standard form. Passing through (2,-5) and perpendicular to the line whose equation is 5x - 6y = 1 Write an equation for the line in standard form. (Type your answer in standard form, using integer coefficients with A 20.)
The equation of the line, in standard form, passing through (2, -5) and perpendicular to the line 5x - 6y = 1 is 6x + 5y = -40.
To find the equation of a line perpendicular to the given line, we need to determine the slope of the given line and then take the negative reciprocal to find the slope of the perpendicular line. The equation of the given line, 5x - 6y = 1, can be rewritten in slope-intercept form as y = (5/6)x - 1/6. The slope of this line is 5/6.
Since the perpendicular line has a negative reciprocal slope, its slope will be -6/5. Now we can use the point-slope form of a line to find the equation. Using the point (2, -5) and the slope -6/5, the equation becomes:
y - (-5) = (-6/5)(x - 2)
Simplifying, we have:
y + 5 = (-6/5)x + 12/5
Multiplying through by 5 to eliminate the fraction:
5y + 25 = -6x + 12
Rearranging the equation:
6x + 5y = -40 Thus, the equation of the line, in standard form, passing through (2, -5) and perpendicular to the line 5x - 6y = 1 is 6x + 5y = -40.
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if a = 1 3 5 and b equals to 1 3 5 find a into B and Plot the co-ordinate in graph paper
To find the result of multiplying vector a by vector b, we use the dot product or scalar product. The dot product of two vectors is calculated by multiplying the corresponding components and summing them up.
Given:
a = [1, 3, 5]
b = [1, 3, 5]
To find a · b, we multiply the corresponding components and sum them:
[tex]a . b = (1 * 1) + (3 * 3) + (5 * 5)\\ = 1 + 9 + 25\\ = 35[/tex]
So, a · b equals 35.
Now, let's plot the coordinate (35) on a graph paper. Since the coordinate consists of only one value, we'll plot it on a one-dimensional number line.
On the number line, we mark the point corresponding to the coordinate (35). The x-axis represents the values of the coordinates.
First, we need to determine the appropriate scale for the number line. Since the coordinate is 35, we can select a scale that allows us to represent values around that range. For example, we can set a scale of 5 units per mark.
Starting from zero, we mark the point at 35 on the number line. This represents the coordinate (35).
The graph paper would show a single point labeled 35 on the number line.
Note that since the coordinate consists of only one value, it can be represented on a one-dimensional graph, such as a number line.
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Consider The Function G:R→Rg:R→R Defined By G(X)=(∫0sin(X)E^(Sin(T))Dt)^2. Find G′(X)G′(X) And Determine The Values Of Xx For Which G′(X)=0g′(X)=0. Hint: E^X≥0for All X∈R
Consider the function g:R→Rg:R→R defined by
g(x)=(∫0sin(x)e^(sin(t))dt)^2.
Find g′(x)g′(x) and determine the values of xx for which g′(x)=0g′(x)=0.
Hint: e^x≥0for all x∈R
the values of x for which G'(x) = 0 and g'(x) = 0 are determined by the condition that the integral term (∫₀^(sin(x))e^(sin(t))dt) is equal to zero.
The derivative of the function G(x) can be found using the chain rule and the fundamental theorem of calculus. By applying the chain rule, we get G'(x) = 2(∫₀^(sin(x))e^(sin(t))dt)(cos(x)).
To determine the values of x for which G'(x) = 0, we set the derivative equal to zero and solve for x: 2(∫₀^(sin(x))e^(sin(t))dt)(cos(x)) = 0. Since the term cos(x) is never equal to zero for all x, the only way for G'(x) to be zero is if the integral term (∫₀^(sin(x))e^(sin(t))dt) is zero.
Now let's consider the function g(x) defined as g(x) = (∫₀^(sin(x))e^(sin(t))dt)^2. To find g'(x), we apply the chain rule and obtain g'(x) = 2(∫₀^(sin(x))e^(sin(t))dt)(cos(x)).
Similarly, to find the values of x for which g'(x) = 0, we set the derivative equal to zero: 2(∫₀^(sin(x))e^(sin(t))dt)(cos(x)) = 0. Again, since cos(x) is never equal to zero for all x, the integral term (∫₀^(sin(x))e^(sin(t))dt) must be zero for g'(x) to be zero.
In summary, the values of x for which G'(x) = 0 and g'(x) = 0 are determined by the condition that the integral term (∫₀^(sin(x))e^(sin(t))dt) is equal to zero.
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A cup of coffee from a Keurig Coffee Maker is 192° F when freshly poured. After 3 minutes in a room at 70° F the coffee has cooled to 170°. How long will it take for the coffee to reach 155° F (the ideal serving temperature)?
It will take approximately 2.089 minutes (or about 2 minutes and 5 seconds) for the coffee to reach 155° F (the ideal serving temperature).
The coffee from a Keurig Coffee Maker is 192° F when freshly poured. After 3 minutes in a room at 70° F the coffee has cooled to 170°.We are to find how long it will take for the coffee to reach 155° F (the ideal serving temperature).Let the time it takes to reach 155° F be t.
If the coffee cools to 170° F after 3 minutes in a room at 70° F, then the difference in temperature between the coffee and the surrounding is:192 - 70 = 122° F170 - 70 = 100° F
In general, when a hot object cools down, its temperature T after t minutes can be modeled by the equation: T(t) = T₀ + (T₁ - T₀) * e^(-k t)where T₀ is the starting temperature of the object, T₁ is the surrounding temperature, k is the constant of proportionality (how fast the object cools down),e is the mathematical constant (approximately 2.71828)Since the coffee has already cooled down from 192° F to 170° F after 3 minutes, we can set up the equation:170 = 192 - 122e^(-k*3)Subtracting 170 from both sides gives:22 = 122e^(-3k)Dividing both sides by 122 gives:0.1803 = e^(-3k)Taking the natural logarithm of both sides gives:-1.712 ≈ -3kDividing both sides by -3 gives:0.5707 ≈ k
Therefore, we can model the temperature of the coffee as:
T(t) = 192 + (70 - 192) * e^(-0.5707t)We want to find when T(t) = 155. So we have:155 = 192 - 122e^(-0.5707t)Subtracting 155 from both sides gives:-37 = -122e^(-0.5707t)Dividing both sides by -122 gives:0.3033 = e^(-0.5707t)Taking the natural logarithm of both sides gives:-1.193 ≈ -0.5707tDividing both sides by -0.5707 gives: t ≈ 2.089
Therefore, it will take approximately 2.089 minutes (or about 2 minutes and 5 seconds) for the coffee to reach 155° F (the ideal serving temperature).
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Let a = (-5, 3, -3) and 6 = (-5, -1, 5). Find the angle between the vector (in radians)
The angle between the vectors (in radians) is 1.12624. Given two vectors are a = (-5, 3, -3) and b = (-5, -1, 5). The angle between vectors is given by;`cos θ = (a.b) / (|a| |b|)`where a.b is the dot product of two vectors. `|a|` and `|b|` are the magnitudes of two vectors. We need to find the angle between two vectors in radians.
Dot Product of two vectors a and b is given by;
a.b = (-5 * -5) + (3 * -1) + (-3 * 5)
= 25 - 3 - 15
= 7
Magnitude of the vector a is;
|a| = √((-5)² + 3² + (-3)²)
= √(59)
Magnitude of the vector b is;
|b| = √((-5)² + (-1)² + 5²)
= √(51)
Therefore,` cos θ = (a.b) / (|a| |b|)`
=> `cos θ = 7 / (√(59) * √(51))
`=> `cos θ = 0.438705745`
The angle between the vectors in radians is
;θ = cos⁻¹(0.438705745)
= 1.12624 rad
Thus, the angle between the vectors (in radians) is 1.12624.
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Determine whether the series converges or diverges. [infinity]0 (n+4)! a) Σ 4!n!4" n=1 1 b) Σ√√n(n+1)(n+2)
(a)The Σ[tex](n+4)!/(4!n!4^n)[/tex] series converges, while (b) the Σ [tex]\sqrt\sqrt{(n(n+1)(n+2))}[/tex] series diverges.
(a) The series Σ[tex](n+4)!/(4!n!4^n)[/tex] as n approaches infinity. To determine the convergence or divergence of the series, we can apply the Ratio Test. Taking the ratio of consecutive terms, we get:
[tex]\lim_{n \to \infty} [(n+5)!/(4!(n+1)!(4^(n+1)))] / [(n+4)!/(4!n!(4^n))][/tex]
Simplifying the expression, we find:
[tex]\lim_{n \to \infty} [(n+5)/(n+1)][/tex] × (1/4)
The limit evaluates to 5/4. Since the limit is less than 1, the series converges.
(b) The series Σ [tex]\sqrt\sqrt{(n(n+1)(n+2))}[/tex] as n approaches infinity. To determine the convergence or divergence of the series, we can apply the Limit Comparison Test. We compare it to the series Σ[tex]\sqrt{n}[/tex] . Taking the limit as n approaches infinity, we find:
[tex]\lim_{n \to \infty} (\sqrt\sqrt{(n(n+1)(n+2))} )[/tex] / ([tex]\sqrt{n}[/tex])
Simplifying the expression, we get:
[tex]\lim_{n \to \infty} (\sqrt\sqrt{(n(n+1)(n+2))} )[/tex] / ([tex]n^{1/4}[/tex])
The limit evaluates to infinity. Since the limit is greater than 0, the series diverges.
In summary, the series in (a) converges, while the series in (b) diverges.
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Consider the function x²-4 if a < 2,x-1, x ‡ −2 (x2+3x+2)(x - 2) f(x) = ax+b if 2≤x≤5 ²25 if x>5 x 5 a) Note that f is not continuous at x = -2. Does f admit a continuous extension or correction at a = -2? If so, then give the continuous extension or correction. If not, then explain why not. b) Using the definition of continuity, find the values of the constants a and b that make f continuous on (1, [infinity]). Justify your answer. L - - 1
(a) f is continuous at x = -2. (b) In order for f to be continuous on (1, ∞), we need to have that a + b = L. Since L is not given in the question, we cannot determine the values of a and b that make f continuous on (1, ∞) for function.
(a) Yes, f admits a continuous correction. It is important to note that a function f admits a continuous extension or correction at a point c if and only if the limit of the function at that point is finite. Then, in order to show that f admits a continuous correction at x = -2, we need to calculate the limits of the function approaching that point from the left and the right.
That is, we need to calculate the following limits[tex]:\[\lim_{x \to -2^-} f(x) \ \ \text{and} \ \ \lim_{x \to -2^+} f(x)\]We have:\[\lim_{x \to -2^-} f(x) = \lim_{x \to -2^-} (x + 2) = 0\]\[\lim_{x \to -2^+} f(x) = \lim_{x \to -2^+} (x^2 + 3x + 2) = 0\][/tex]
Since both limits are finite and equal, we can define a continuous correction as follows:[tex]\[f(x) = \begin{cases} x + 2, & x < -2 \\ x^2 + 3x + 2, & x \ge -2 \end{cases}\][/tex]
Then f is continuous at x = -2.
(b) In order for f to be continuous on (1, ∞), we need to have that:[tex]\[\lim_{x \to 1^+} f(x) = f(1)\][/tex]
This condition ensures that the function is continuous at the point x = 1. We can calculate these limits as follows:[tex]\[\lim_{x \to 1^+} f(x) = \lim_{x \to 1^+} (ax + b) = a + b\]\[f(1) = a + b\][/tex]
Therefore, in order for f to be continuous on (1, ∞), we need to have that a + b = L. Since L is not given in the question, we cannot determine the values of a and b that make f continuous on (1, ∞).
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Include all topics that you learned with following points: Name of the topic • Explain the topic in your own words. You may want to include diagram/ graphs to support your explanations. • Create an example for all major topics. (Include question, full solution, and properly labelled diagram/graph.) Unit 5: Discrete Functions (Ch. 7 and 8). Arithmetic Sequences Geometric Sequences Recursive Sequences Arithmetic Series Geometric Series Pascal's Triangle and Binomial Expansion Simple Interest Compound Interest (Future and Present) Annuities (Future and Present)
Unit 5: Discrete Functions (Ch. 7 and 8)
1. Arithmetic Sequences: Sequences with a constant difference between consecutive terms.
2. Geometric Sequences: Sequences with a constant ratio between consecutive terms.
3. Recursive Sequences: Sequences defined in terms of previous terms using a recursive formula.
4. Arithmetic Series: Sum of terms in an arithmetic sequence.
5. Geometric Series: Sum of terms in a geometric sequence.
6. Pascal's Triangle and Binomial Expansion: Triangular arrangement of numbers used for expanding binomial expressions.
7. Simple Interest: Interest calculated based on the initial principal amount, using the formula [tex]\(I = P \cdot r \cdot t\).[/tex]
8. Compound Interest (Future and Present): Interest calculated on both the principal amount and accumulated interest. Future value formula: [tex]\(FV = P \cdot (1 + r)^n\)[/tex]. Present value formula: [tex]\(PV = \frac{FV}{(1 + r)^n}\).[/tex]
9. Annuities (Future and Present): Series of equal payments made at regular intervals. Future value and present value formulas depend on the type of annuity (ordinary or annuity due).
Please note that detailed explanations, examples, and diagrams/graphs are omitted for brevity.
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1. Short answer. At average, the food cost percentage in North
American restaurants is 33.3%. Various restaurants have widely
differing formulas for success: some maintain food cost percent of
25.0%,
The average food cost percentage in North American restaurants is 33.3%, but it can vary significantly among different establishments. Some restaurants are successful with a lower food cost percentage of 25.0%.
In North American restaurants, the food cost percentage refers to the portion of total sales that is spent on food supplies and ingredients. On average, restaurants allocate around 33.3% of their sales revenue towards food costs. This percentage takes into account factors such as purchasing, inventory management, waste reduction, and pricing strategies. However, it's important to note that this is an average, and individual restaurants may have widely differing formulas for success.
While the average food cost percentage is 33.3%, some restaurants have managed to maintain a lower percentage of 25.0% while still achieving success. These establishments have likely implemented effective cost-saving measures, negotiated favorable supplier contracts, and optimized their menu offerings to maximize profit margins. Lowering the food cost percentage can be challenging as it requires balancing quality, portion sizes, and pricing to meet customer expectations while keeping costs under control. However, with careful planning, efficient operations, and a focus on minimizing waste, restaurants can achieve profitability with a lower food cost percentage.
It's important to remember that the food cost percentage alone does not determine the overall success of a restaurant. Factors such as customer satisfaction, service quality, marketing efforts, and overall operational efficiency also play crucial roles. Each restaurant's unique circumstances and business model will contribute to its specific formula for success, and the food cost percentage is just one aspect of the larger picture.
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USE WORSKIN METHOD TO FIND THE GENERAL SOLUTION OF THE FOLLOWING SECOND ORDER LINEAR ORDINARY DIFFERNTIAL EQUATION? y²-10 y² + 25 Y ====2=²2
The general solution of the given second-order linear ordinary differential equation is y = (c1 + c2x)e^(5x) + 22/25, where c1 and c2 are arbitrary constants.
The given differential equation is y'' - 10y' + 25y = 22. To find the general solution, we first need to find the complementary function by solving the associated homogeneous equation, which is y'' - 10y' + 25y = 0.
Assuming a solution of the form y = e^(rx), we substitute it into the homogeneous equation and obtain the characteristic equation r^2 - 10r + 25 = 0. Solving this quadratic equation, we find that r = 5 is a repeated root.
Therefore, the complementary function is of the form y_c = (c1 + c2x)e^(5x), where c1 and c2 are arbitrary constants.
Next, we find a particular solution for the non-homogeneous equation y'' - 10y' + 25y = 22. Since the right-hand side is a constant, we can assume a constant solution y_p = a.
Substituting y_p = a into the differential equation, we find that 25a = 22, which gives a = 22/25.
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You own a sandwich shop in which customers progress through two service stations. At the first service station, customers order sandwiches. At the second station, customers pay for their sandwiches. Suppose that all service times are exponential. The average service time at the first station is 2 minutes. The average service time at the second station is 1 minute. There are 3 servers at the first station and 2 servers at the second station. The arrival process is Poisson with rate 80 per hour. (a) What is the average number of customers at each station? (b) What is the average total time that each customer spends in the system? (c) True or false: The arrival process to the second station is a Poisson process.
(a) The queue lengths at the two stations do not stabilize (b) The average total time that each customer spends in the system is 17/12 minutes. (c) output process of the first station is a Poisson process for sandwich
(a) Average number of customers at each station: Given, average service time at the first station is 2 minutes. Then the service rate is given as λ = 1/2 customers per minute. Since there are 3 servers, the effective service rate is 3λ = 3/2 customers per minute. The second station has 2 servers and the service rate is 1/1 minute/customer. Hence the effective service rate is 2λ = 1 minute/customer.The arrival process is Poisson with rate λ = 80 per hour. Thus, the arrival rate is λ = 80/60 = 4/3 customers per minute.The service rate at each station is greater than the arrival rate, i.e., 3/2 > 4/3 and 1 > 4/3. Therefore, the queue lengths at the two stations do not stabilize. So, it is not meaningful to compute the average number of customers at each station.
(b) Average total time that each customer spends in the system:Each customer experiences an exponential service time at the first and the second station. Therefore, the time that a customer spends at the first station is exponentially distributed with mean 1/λ = 2/3 minutes. Similarly, the time that a customer spends at the second station is exponentially distributed with mean 1/λ = 3/4 minutes. Therefore, the average total time that each customer spends in the system is 2/3 + 3/4 = 17/12 minutes.
(c) The arrival process to the second station is a Poisson process:True.Explanation: The arrival process is Poisson with rate 80 per hour, which is equivalent to λ = 4/3 customers per minute. The service rate at the second station is 1 customer per minute. Therefore, the service rate is greater than the arrival rate, i.e., 1 > 4/3. Hence, the queue length at the second station does not stabilize.The first station is the bottleneck for sandwich.
Therefore, the output process of the first station is a Poisson process. Since the arrival process is Poisson and the output process of the first station is Poisson, it follows that the arrival process to the second station is Poisson.
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Can you solve 17+4x<9
Answer:
x<-2
Step-by-step explanation:
17+4x<9
4x<-8
x<-2
The solution is:
↬ x < -2Work/explanation:
Recall that the process for solving an inequality is the same as the process for solving an equation (a linear equation in one variable).
Make sure that all constants are on the right:
[tex]\bf{4x < 9-17}[/tex]
[tex]\bf{4x < -8}[/tex]
Divide each side by 4:
[tex]\bf{x < -2}[/tex]
Hence, x < -2Suppose f(π/6) = 6 and f'(π/6) and let g(x) = f(x) cos x and h(x) = = g'(π/6)= = 2 -2, sin x f(x) and h'(π/6) =
The given information states that f(π/6) = 6 and f'(π/6) is known. Using this, we can calculate g(x) = f(x) cos(x) and h(x) = (2 - 2sin(x))f(x). The values of g'(π/6) and h'(π/6) are to be determined.
We are given that f(π/6) = 6, which means that when x is equal to π/6, the value of f(x) is 6. Additionally, we are given f'(π/6), which represents the derivative of f(x) evaluated at x = π/6.
To calculate g(x), we multiply f(x) by cos(x). Since we know the value of f(x) at x = π/6, which is 6, we can substitute these values into the equation to get g(π/6) = 6 cos(π/6). Simplifying further, we have g(π/6) = 6 * √3/2 = 3√3.
Moving on to h(x), we multiply (2 - 2sin(x)) by f(x). Using the given value of f(x) at x = π/6, which is 6, we can substitute these values into the equation to get h(π/6) = (2 - 2sin(π/6)) * 6. Simplifying further, we have h(π/6) = (2 - 2 * 1/2) * 6 = 6.
Therefore, we have calculated g(π/6) = 3√3 and h(π/6) = 6. However, the values of g'(π/6) and h'(π/6) are not given in the initial information and cannot be determined without additional information.
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Do detailed derivations of EM algorithm for GMM(Gaussian mixture model), in the case of arbitrary covariance matrices.
Gaussian mixture model is a family of distributions whose pdf is in the following form : K gmm(x) = p(x) = Σπ.(x|μ., Σκ), (1) k=1 where N(μ, E) denotes the Gaussian pdf with mean and covariance matrix Σ, and {₁,..., K} are mixing coefficients satisfying K Tk=p(y=k), TK = 1₁ Tk 20, k={1,..., K}. 2-1 (2) k=1
The E step can be computed using Bayes' rule and the formula for the Gaussian mixture model. The M step involves solving a set of equations for the means, covariances, and mixing coefficients that maximize the expected log-likelihood.
The Gaussian mixture model is a family of distributions with a pdf of the following form:
K gmm(x) = p(x) = Σπ.(x|μ., Σκ), (1)
k=1where N(μ, Σ) denotes the Gaussian pdf with mean and covariance matrix Σ, and {π1,..., πK} are mixing coefficients satisfying K Σ Tk=p(y=k),
TK = 1Σ Tk 20, k={1,..., K}.
Derivations of the EM algorithm for GMM for arbitrary covariance matrices:
Gaussian mixture models (GMMs) are widely used in a variety of applications. GMMs are parametric models that can be used to model complex data distributions that are the sum of several Gaussian distributions. The maximum likelihood estimation problem for GMMs with arbitrary covariance matrices can be solved using the expectation-maximization (EM) algorithm. The EM algorithm is an iterative algorithm that alternates between the expectation (E) step and the maximization (M) step. During the E step, the expected sufficient statistics are computed, and during the M step, the parameters are updated to maximize the likelihood. The EM algorithm is guaranteed to converge to a local maximum of the likelihood function.
The complete derivation of the EM algorithm for GMMs with arbitrary covariance matrices is beyond the scope of this answer, but the main steps are as follows:
1. Initialization: Initialize the parameters of the GMM, including the means, covariances, and mixing coefficients.
2. E step: Compute the expected sufficient statistics, including the posterior probabilities of the latent variables.
3. M step: Update the parameters of the GMM using the expected sufficient statistics.
4. Repeat steps 2 and 3 until convergence.
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Find an equation of the plane passing through the given points. (3, 7, −7), (3, −7, 7), (−3, −7, −7) X
An equation of the plane passing through the points (3, 7, −7), (3, −7, 7), (−3, −7, −7) is x + y − z = 3.
Given points are (3, 7, −7), (3, −7, 7), and (−3, −7, −7).
Let the plane passing through these points be ax + by + cz = d. Then, three planes can be obtained.
For the given points, we get the following equations:3a + 7b − 7c = d ...(1)3a − 7b + 7c = d ...(2)−3a − 7b − 7c = d ...(3)Equations (1) and (2) represent the same plane as they have the same normal vector.
Substitute d = 3a in equation (3) to get −3a − 7b − 7c = 3a. This simplifies to −6a − 7b − 7c = 0 or 6a + 7b + 7c = 0 or 2(3a) + 7b + 7c = 0. Divide both sides by 2 to get the equation of the plane passing through the points as x + y − z = 3.
Summary: The equation of the plane passing through the given points (3, 7, −7), (3, −7, 7), and (−3, −7, −7) is x + y − z = 3.
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Graph the following system of inequalities y<1/3x-2 x<4
From the inequality graph, the solution to the inequalities is: (4, -2/3)
How to graph a system of inequalities?There are different tyes of inequalities such as:
Greater than
Less than
Greater than or equal to
Less than or equal to
Now, the inequalities are given as:
y < (1/3)x - 2
x < 4
Thus, the solution to the given inequalities will be gotten by plotting a graph of both and the point of intersection will be the soilution which in the attached graph we see it as (4, -2/3)
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When we're dealing with compound interest we use "theoretical" time (e.g. 1 day = 1/365 year, 1 week = 1/52 year, 1 month = 1/12 year) and don't worry about daycount conventions. But if we're using weekly compounding, which daycount convention is it most similar to?
a. ACT/360
b. ACT/365
c. None of them!
d. ACT/ACT
e. 30/360
The day count convention used for the interest calculation can differ depending on the type of financial instrument and the currency of the transaction.
When we're dealing with compound interest we use\ "theoretical" time (e.g. 1 day = 1/365 year, 1 week = 1/52 year, 1 month = 1/12 year) and don't worry about day count conventions.
But if we're using weekly compounding, it is most similar to the ACT/365 day count convention.What is compound interest?Compound interest refers to the interest earned on both the principal balance and the interest that has accumulated on it over time. In other words, the sum you receive for an investment not only depends on the principal amount but also on the interest it generates over time.What are conventions?Conventions are practices or sets of agreements that are widely followed, established, and accepted within a given group, profession, or community. In finance, there are several conventions that govern various aspects of how we calculate prices, values, or risks.What is day count?In financial transactions, day count refers to the method used to calculate the number of days between two cash flows. In finance, the exact number of days between two cash flows is important because it affects the interest accrued over that period.
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Use a graph or level curves or both to find the local maximum and minimum values and saddle point(s) of the function. Then use calculus to find these values precisely. (Enter your answers as comma-separated lists. If an answer does not exist, enter ONE.) f(x, y)=sin(x)+sin(y) + sin(x + y) +6, 0≤x≤ 2, 0sys 2m. local maximum value(s) local minimum value(s). saddle point(s)
Previous question
Within the given domain, there is one local maximum value, one local minimum value, and no saddle points for the function f(x, y) = sin(x) + sin(y) + sin(x + y) + 6.
The function f(x, y) = sin(x) + sin(y) + sin(x + y) + 6 is analyzed to determine its local maximum, local minimum, and saddle points. Using both a graph and level curves, it is found that there is one local maximum value, one local minimum value, and no saddle points within the given domain.
To begin, let's analyze the graph and level curves of the function. The graph of f(x, y) shows a smooth surface with varying heights. By inspecting the graph, we can identify regions where the function reaches its maximum and minimum values. Additionally, level curves can be plotted by fixing f(x, y) at different constant values and observing the resulting curves on the x-y plane.
Next, let's employ calculus to find the precise values of the local maximum, local minimum, and saddle points. Taking the partial derivatives of f(x, y) with respect to x and y, we find:
∂f/∂x = cos(x) + cos(x + y)
∂f/∂y = cos(y) + cos(x + y)
To find critical points, we set both partial derivatives equal to zero and solve the resulting system of equations. However, in this case, the equations cannot be solved algebraically. Therefore, we need to use numerical methods, such as Newton's method or gradient descent, to approximate the critical points.
After obtaining the critical points, we can classify them as local maximum, local minimum, or saddle points using the second partial derivatives test. By calculating the second partial derivatives, we find:
∂²f/∂x² = -sin(x) - sin(x + y)
∂²f/∂y² = -sin(y) - sin(x + y)
∂²f/∂x∂y = -sin(x + y)
By evaluating the second partial derivatives at each critical point, we can determine their nature. If both ∂²f/∂x² and ∂²f/∂y² are positive at a point, it is a local minimum. If both are negative, it is a local maximum. If they have different signs, it is a saddle point.
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Find the nominal rate of interest compounded annually equivalent to 6.9% compounded semi-annually. The nominal rate of interest compounded annually is%. (Round the final answer to four decimal places as needed. Round all intermediate values to six decimal places as needed.)
The nominal rate of interest compounded annually equivalent to 6.9% compounded semi-annually is 6.7729%.
To find the nominal rate of interest compounded annually equivalent to a given rate compounded semi-annually, we can use the formula:
[tex]\[ (1 + \text{nominal rate compounded annually}) = (1 + \text{rate compounded semi-annually})^n \][/tex]
Where n is the number of compounding periods per year.
In this case, the given rate compounded semi-annually is 6.9%. To convert this rate to an equivalent nominal rate compounded annually, we have:
[tex]\[ (1 + \text{nominal rate compounded annually}) = (1 + 0.069)^2 \][/tex]
Simplifying this equation, we find:
[tex]\[ \text{nominal rate compounded annually} = (1.069^2) - 1 \][/tex]
Evaluating this expression, we get:
[tex]\[ \text{nominal rate compounded annually} = 0.1449 \][/tex]
Rounding this value to four decimal places, we have:
[tex]\[ \text{nominal rate compounded annually} = 0.1449 \approx 6.7729\% \][/tex]
Therefore, the nominal rate of interest compounded annually equivalent to 6.9% compounded semi-annually is 6.7729%.
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The time required for 5 tablets to completely dissolve in stomach acid were (in minutes) 2.5, 3.0, 2.7, 3.2, and 2.8. Assuming a normal distribution for these times, find a 95%
We are 95% confident that the true mean time required for 5 tablets to dissolve in stomach acid is between 2.62 minutes and 3.06 minutes.
We have been given the time required for 5 tablets to completely dissolve in stomach acid. We need to find a 95% confidence interval for the population mean time to dissolve.
We will use the sample mean and the sample standard deviation to compute the confidence interval.
Let us first find the sample mean and the sample standard deviation for the given data.
Sample mean, \bar{x}
= \frac{2.5 + 3.0 + 2.7 + 3.2 + 2.8}{5}
= \frac{14.2}{5}
= 2.84
Sample variance,s^2
= \frac{1}{4} [(2.5 - 2.84)^2 + (3 - 2.84)^2 + (2.7 - 2.84)^2 + (3.2 - 2.84)^2 + (2.8 - 2.84)^2]s^2
= \frac{1}{4} (0.2596 + 0.0256 + 0.0256 + 0.0576 + 0.0256)
= 0.0684
Sample standard deviation, s
= \sqrt{0.0684}
= 0.2617
Now, we can find the 95% confidence interval using the formula,\bar{x} - z_{\alpha/2}\frac{s}{\sqrt{n}} < \mu < \bar{x} + z_{\alpha/2}\frac{s}{\sqrt{n}}
Substituting the given values, we get,
2.84 - z_{0.025}\frac{0.2617}{\sqrt{5}} < \mu < 2.84 + z_{0.025}\frac{0.2617}{\sqrt{5}}
From the Z-table, we find that z_{0.025}
= 1.96
Therefore, the 95% confidence interval for the population mean time to dissolve is given by,
2.84 - 1.96 \frac{0.2617}{\sqrt{5}} < \mu < 2.84 + 1.96 \frac{0.2617}{\sqrt{5}}2.62 < \mu < 3.06
Therefore, we are 95% confident that the true mean time required for 5 tablets to dissolve in stomach acid is between 2.62 minutes and 3.06 minutes.
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Let B = -{Q.[3³]} = {[4).8} Suppose that A = → is the matrix representation of a linear operator T: R² R2 with respect to B. (a) Determine T(-5,5). (b) Find the transition matrix P from B' to B. (c) Using the matrix P, find the matrix representation of T with respect to B'. and B
The matrix representation of T with respect to B' is given by T' = (-5/3,-1/3; 5/2,1/6). Answer: (a) T(-5,5) = (-5,5)A = (-5,5)(-4,2; 6,-3) = (10,-20).(b) P = (-2,-3; 0,-3).(c) T' = (-5/3,-1/3; 5/2,1/6).
(a) T(-5,5)
= (-5,5)A
= (-5,5)(-4,2; 6,-3)
= (10,-20).(b) Let the coordinates of a vector v with respect to B' be x and y, and let its coordinates with respect to B be u and v. Then we have v
= Px, where P is the transition matrix from B' to B. Now, we have (1,0)B'
= (0,-1; 1,-1)(-4,2)B
= (-2,0)B, so the first column of P is (-2,0). Similarly, we have (0,1)B'
= (0,-1; 1,-1)(6,-3)B
= (-3,-3)B, so the second column of P is (-3,-3). Therefore, P
= (-2,-3; 0,-3).(c) The matrix representation of T with respect to B' is C
= P⁻¹AP. We have P⁻¹
= (-1/6,1/6; -1/2,1/6), so C
= P⁻¹AP
= (-5/3,-1/3; 5/2,1/6). The matrix representation of T with respect to B' is given by T'
= (-5/3,-1/3; 5/2,1/6). Answer: (a) T(-5,5)
= (-5,5)A
= (-5,5)(-4,2; 6,-3)
= (10,-20).(b) P
= (-2,-3; 0,-3).(c) T'
= (-5/3,-1/3; 5/2,1/6).
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Evaluate the definite integral. Provide the exact result. */6 6. S.™ sin(6x) sin(3r) dr
To evaluate the definite integral of (1/6) * sin(6x) * sin(3r) with respect to r, we can apply the properties of definite integrals and trigonometric identities to simplify the expression and find the exact result.
To evaluate the definite integral, we integrate the given expression with respect to r and apply the limits of integration. Let's denote the integral as I:
I = ∫[a to b] (1/6) * sin(6x) * sin(3r) dr
We can simplify the integral using the product-to-sum trigonometric identity:
sin(A) * sin(B) = (1/2) * [cos(A - B) - cos(A + B)]
Applying this identity to our integral:
I = (1/6) * ∫[a to b] [cos(6x - 3r) - cos(6x + 3r)] dr
Integrating term by term:
I = (1/6) * [sin(6x - 3r)/(-3) - sin(6x + 3r)/3] | [a to b]
Evaluating the integral at the limits of integration:
I = (1/6) * [(sin(6x - 3b) - sin(6x - 3a))/(-3) - (sin(6x + 3b) - sin(6x + 3a))/3]
Simplifying further:
I = (1/18) * [sin(6x - 3b) - sin(6x - 3a) - sin(6x + 3b) + sin(6x + 3a)]
Thus, the exact result of the definite integral is (1/18) * [sin(6x - 3b) - sin(6x - 3a) - sin(6x + 3b) + sin(6x + 3a)].
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According to data from an aerospace company, the 757 airliner carries 200 passengers and has doors with a mean height of 1.83 cm. Assume for a certain population of men we have a mean of 1.75 cm and a standard deviation of 7.1 cm. a. What mean doorway height would allow 95 percent of men to enter the aircraft without bending? 1.75x0.95 1.6625 cm b. Assume that half of the 200 passengers are men. What mean doorway height satisfies the condition that there is a 0.95 probability that this height is greater than the mean height of 100 men? For engineers designing the 757, which result is more relevant: the height from part (a) or part (b)? Why?
Based on the normal distribution table, the probability corresponding to the z score is 0.8577
Since the heights of men are normally distributed, we will apply the formula for normal distribution which is expressed as
z = (x - u)/s
Where x is the height of men
u = mean height
s = standard deviation
From the information we have;
u = 1.75 cm
s = 7.1 cm
We need to find the probability that the mean height of 1.83 cm is less than 7.1 inches.
Thus It is expressed as
P(x < 7.1 )
For x = 7.1
z = (7.1 - 1.75 )/1.83 = 1.07
Based on the normal distribution table, the probability corresponding to the z score is 0.8577
P(x < 7.1 ) = 0.8577
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