Solve for v
10 + 3v = –8

The general solution of the given differential equation is P = C sec(t) + 1/(4 tan(t)), where C is a constant.

To find the general solution of the differential equation, we need to solve for P. The given equation is P + P tan(t) = P⁴ sec(t) + t dP/dt.

First, we rearrange the equation to isolate the derivative term:

P⁴ sec(t) + t dP/dt = P + P tan(t)

Next, we separate variables by moving all terms involving P to one side and terms involving t and dP/dt to the other side:

P⁴ sec(t) - P = -P tan(t) - t dP/dt

Now, we can factor out P:

P(P³ sec(t) - 1) = -P tan(t) - t dP/dt

Dividing both sides by (P³ sec(t) - 1), we get:

P = (-P tan(t) - t dP/dt) / (P³ sec(t) - 1)

Simplifying further, we have:

P = -P tan(t) / (P³ sec(t) - 1) - t dP/dt / (P³ sec(t) - 1)

The term (-P tan(t) / (P³ sec(t) - 1)) can be rewritten as 1/(P³ sec(t) - 1) * (-P tan(t)). Integrating both sides with respect to P, we obtain:

∫(1/(P³ sec(t) - 1)) dP = ∫(-t/(P³ sec(t) - 1)) dt

Integrating these expressions leads to the general solution:

ln|P³ sec(t) - 1| = -ln|cos(t)| + C

Simplifying further, we get:

ln|P³ sec(t) - 1| + ln|cos(t)| = C

Combining the logarithms using properties of logarithms, we have:

ln|P³ sec(t) - 1 cos(t)| = C

Exponentiating both sides, we obtain

[tex]P³ sec(t) - 1 = e^Ccos(t)[/tex]

Finally, rearranging the equation yields the general solution:

[tex]P = (e^C cos(t) + 1)^(1/3)[/tex]

Letting C = ln|A|, where A is a positive constant, we can rewrite the solution as:

[tex]P = (A cos(t) + 1)^(1/3)[/tex]

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To draw the projection of the solid bounded by the paraboloid z = 16 - 7x^2 - y^2 in the first octant onto the x-axis, y-axis, and z-axis, we can use mathematical applications like GeoGebra.

Using a mathematical application like GeoGebra, we can create a three-dimensional coordinate system and plot the points that satisfy the equation of the paraboloid. In this case, we will focus on the first octant, which means the x, y, and z values are all positive.

To draw the projection onto the x-axis, we can fix the y and z values to zero and plot the resulting points on the x-axis. This will give us a curve in the x-z plane that represents the intersection of the paraboloid with the x-axis. Similarly, for the projection onto the y-axis, we fix the x and z values to zero and plot the resulting points on the y-axis. This will give us a curve in the y-z plane that represents the intersection of the paraboloid with the y-axis.

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To find the length and direction of the cross product u × v, where u = -2i + 6j - 10k and v = -i + 3j - 5k, we can calculate the cross product and then determine its magnitude and direction.

The cross product u × v is given by the formula: u × v = |u| |v| sin(θ) n

where |u| and |v| are the magnitudes of u and v, respectively, θ is the angle between u and v, and n is the unit vector perpendicular to both u and v.

To calculate the cross product, we can use the determinant method:

u × v = (6 * (-5) - (-10) * 3)i + ((-2) * (-5) - (-10) * (-1))j + ((-2) * 3 - 6 * (-1))k

= (-30 + 30)i + (-10 + 10)j + (-6 - 6)k

= 0i + 0j + (-12)k

= -12k

Therefore, the cross product u × v simplifies to -12k.

Now, let's find the length of u × v:

|u × v| = |(-12)k|

= 12

So, the length of u × v is 12.

As for the direction, since the cross product u × v is a vector along the negative k-axis, its direction can be expressed as -k.

Therefore, the length of u × v is 12, and its direction is -k.

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The probability that point P lies on the line DC can be calculated by dividing the length of the line DC by the total perimeter of the rectangle. The length of the line DC is equal to the height of the rectangle, which is the same as the length of the opposite side AB. Therefore, the probability that point P lies on DC is AB/AB+BC+CD+DA.

To understand the calculation of the probability of point P lying on DC, we need to understand the concept of probability. Probability is the measure of the likelihood of an event occurring. It is expressed as a number between 0 and 1, where 0 indicates impossibility, and 1 indicates certainty. In this case, the event is the point P lying on DC.

The probability of point P lying on DC can be calculated by dividing the length of the line DC by the total perimeter of the rectangle. Therefore, the probability is AB/AB+BC+CD+DA. The concept of probability is essential in understanding the likelihood of events and making decisions based on that likelihood.

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Option B.) RT = 5, ST = √2, RS = √27, is the correct lengths of the sides.

Here, we have,

given that,

RST is a right angle triangle.

so, we know that,

the lengths of the sides will follow the Pythagorean theorem:

Pythagorean theorem, the well-known geometric theorem that the sum of the squares on the legs of a right triangle is equal to the square on the hypotenuse (the side opposite the right angle)—or, in familiar algebraic notation, a² + b² = c².

so, from the given options, we get,

option B.)

RT = 5, ST = √2, RS = √27

because, applying Pythagorean theorem we get,

5² + √2²

=25 + 2

=27

= √27²

Hence, Option B.) RT = 5, ST = √2, RS = √27, is the correct lengths of the sides.

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The solution to the system of equations is (x, y, z, w) = (5/4, -83/4, 65/4, 37/10). The given system of equations is inconsistent, meaning there is no solution set that satisfies all the equations simultaneously.

To apply Gauss-Jordan elimination, let's represent the system of equations in augmented matrix form:

```

[  2   1   1   3  |  18 ]

[ -3  -y   2   2  |   7 ]

[  8   2   1   1  |   0 ]

[  4   1   4   8  |  -1 ]

```

We'll perform row operations to transform the augmented matrix into row-echelon form.

1. R2 = R2 + (3/2)R1

2. R3 = R3 - 4R1

3. R4 = R4 - 2R1

The updated matrix is:

```

[  2    1    1     3  |  18 ]

[  0   -y  5/2   13/2 |  37/2 ]

[  0    2   -3    -5  | -72 ]

[  0   -1    0    -2  |  -37 ]

```

Next, we'll continue with the row operations to achieve reduced row-echelon form.

4. R2 = (-1/y)R2

5. R3 = R3 + 2R2

6. R4 = R4 - R2

The updated matrix is:

```

[  2    1      1        3     |  18 ]

[  0    1     -5/2    -13/2  | -37/2 ]

[  0     0    -4     -31    | -113 ]

[  0     0    5/2     11/2  |  37/2 ]

```

Continuing with the row operations:

7. R3 = (-1/4)R3

8. R4 = (2/5)R4

The updated matrix becomes:

```

[  2    1      1        3     |  18 ]

[  0    1     -5/2    -13/2  | -37/2 ]

[  0    0       1       31    |  113/4 ]

[  0    0      1/2    11/5   |  37/5 ]

```

Further row operations:

9. R3 = R3 + (5/2)R4

The updated matrix is:

```

[  2    1      1        3      |  18 ]

[  0    1     -5/2    -13/2   | -37/2 ]

[  0    0       1       31    |  113/4 ]

[  0    0       0       6     |  37/10 ]

```

To obtain the reduced row-echelon form, we perform the following operation:

10. R4 = (1/6)R4

The final matrix is:

```

[  2    1      1        3      |  18 ]

[  0    1     -5/2    -13/2   | -37/2 ]

[  0    0       1       31    |  113/4

]

[  0    0       0        1/6  |  37/60 ]

```

Now, we can rewrite the system of equations in terms of the reduced row-echelon form:

2x + y + z + 3w = 18

y - (5/2)z - (13/2)w = -37/2

z + 31w = 113/4

(1/6)w = 37/60

From the last equation, we can determine that w = 37/10.

Substituting this value back into the third equation, we find z = (113/4) - 31(37/10) = 65/4.

Substituting the values of z and w into the second equation, we get y - (5/2)(65/4) - (13/2)(37/10) = -37/2.

Simplifying, we find y = -83/4.

Finally, substituting the values of y, z, and w into the first equation, we have 2x + (-83/4) + (65/4) + 3(37/10) = 18.

Simplifying, we obtain 2x = 5/2, which implies x = 5/4.

Therefore, the solution to the system of equations is (x, y, z, w) = (5/4, -83/4, 65/4, 37/10).

However, please note that the system is inconsistent because the equations cannot be simultaneously satisfied.

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The 99.5% confidence interval for the population mean is approximately (32.223, 38.357).

Sample size, n = 82

Standard deviation, o = 8.3

Sample mean, x = 35.29

Confidence level, C = 99.5%

Constructing the confidence interval: For n = 82 and C = 99.5%, the degree of freedom can be found using the formula, n - 1 = 82 - 1 = 81

Using t-distribution table, for a two-tailed test and a 99.5% confidence level, the critical values are given as 2.8197 and -2.8197 respectively.

Then the confidence interval is calculated as follows:

The formula for Confidence interval = x ± tα/2 * σ/√n

Where x = 35.29, σ = 8.3, tα/2 = 2.8197 and n = 82

Substituting the values, Confidence interval = 35.29 ± 2.8197 * 8.3/√82

Confidence interval = 35.29 ± 3.067 [Round off to three decimal places]

Therefore, the confidence interval is (32.223, 38.357)

The standard deviation is a measure of the amount of variability in a set of data.

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The horizontal component of the velocity is approximately 17.47 m/s, and the vertical component is approximately 118.89 m/s.

To determine the vertical and horizontal vector components of the velocity of the rocket, we can use trigonometry.

Given that the rocket is propelled at an initial velocity of 120 m/s at 85° from the horizontal, we can consider the horizontal component as the adjacent side of a right triangle and the vertical component as the opposite side.

To find the horizontal component, we use the cosine function:

Horizontal component = velocity * cos(angle)

= 120 m/s * cos(85°)

To find the vertical component, we use the sine function:

Vertical component = velocity * sin(angle)

= 120 m/s * sin(85°)

Evaluating these expressions:

Horizontal component ≈ 120 m/s * cos(85°) ≈ 17.47 m/s

Vertical component ≈ 120 m/s * sin(85°) ≈ 118.89 m/s

Therefore, the horizontal component is 17.47 m/s, and the vertical component is 118.89 m/s.

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The standard deviation of the sampling distribution of the sample mean length is 0.1 minutes.

The standard deviation of the sampling distribution of the sample mean is determined by the population standard deviation (0.4 minutes) divided by the square root of the sample size (√16 = 4).

Therefore, the standard deviation of the sampling distribution of the sample mean length is 0.4 minutes / 4 = 0.1 minutes.

The sampling distribution of the sample mean represents the distribution of sample means taken from multiple samples of the same size from a population. As the sample size increases, the standard deviation of the sampling distribution decreases, resulting in a more precise estimate of the population mean.

In this case, since we have a sample size of 16, the standard deviation of the sampling distribution of the sample mean is 0.1 minutes.

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The integral ∫∫∫ (2 + √(4 - x² - y²)) / (x² + y² + 2²)^(3/2) dz dy dr evaluates to a specific numerical value.

To evaluate the given triple integral, we use cylindrical coordinates (r, θ, z) to simplify the expression. The limits of integration are not provided, so we assume them to be appropriate for the problem. The integral becomes ∫∫∫ (2 + √(4 - r²)) / (r² + 4)^(3/2) dz dy dr.

To solve this integral, we proceed by integrating in the order dz, dy, and dr. The integrals involved may require trigonometric substitutions or other techniques, depending on the limits and the specific values of r, θ, and z. Once all three integrals are evaluated, the result will be a specific numerical value.

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The area οf the surface οbtained by rοtating the curve [tex]$x=\sqrt{16-y^2}$[/tex], [tex]$0 \leq y \leq 2$[/tex], abοut the y-axis is 16π. Sο, the cοrrect οptiοn is D. 16π

The surface area οf a three-dimensiοnal οbject is the tοtal area οf all its faces.

To find the area of the surface obtained by rotating the curve [tex]x=\sqrt{16-y^2}, 0 \leq y \leq 2$[/tex], about the y-axis, we can use the formula for the surface area of revolution.

The surface area of revolution can be calculated using the integral:

[tex]$\rm A=2 \pi \int_a^b f(y) \sqrt{1+\left(\frac{d x}{d y}\right)^2} d y $[/tex]

where f(y) is the function representing the curve, and [tex]$\rm \frac{dx}{dy}[/tex] is the derivative of x with respect to y.

In this case, [tex]$ \rm f(y) = \sqrt{16-y^2}$[/tex].

First, let's find [tex]$\rm \frac{dx}{dy}$[/tex]:

[tex]$ \rm \frac{dx}{dy}=\frac{d}{d y}\left(\sqrt{16-y^2}\right)=\frac{-y}{\sqrt{16-y^2}} $$[/tex]

Simplifying the expression under the square root:

[tex]$$ \begin{aligned} & A=2 \pi \int_0^2 \sqrt{16-y^2} \sqrt{1+\frac{y^2}{16-y^2}} d y \\ & A=2 \pi \int_0^2 \sqrt{16-y^2} \sqrt{\frac{16-y^2+y^2}{16-y^2}} d y \\ & A=2 \pi \int_0^2 \sqrt{16} d y \\ & A=2 \pi \cdot \sqrt{16} \cdot \int_0^2 d y \\ & A=2 \pi \cdot 4 \cdot[y]_0^2 \\ & A=8 \pi \cdot 2 \\ & A=16 \pi \end{aligned} $$[/tex]

Therefοre, the area οf the surface οbtained by rοtating the curve [tex]$x=\sqrt{16-y^2}$[/tex], [tex]$0 \leq y \leq 2$[/tex], abοut the y-axis is 16π.

Sο, the cοrrect οptiοn is D. 16π.

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The points of inflection is at x = 0, 2

A point of inflection is simply described as the points in a given function where there is a change in the concavity of the function.

From the information given, we have that the function is written as;

f(x) = 3x⁵ – 30x³

Now, we have to first find the intervals where the second derivative of the function is both a positive and negative value

We have that the second derivative of f(x) is written as;

f''(x) = 45x(x – 2)

Then, we have that the second derivative is zero at the points

x = 0 and x = 2.

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To find the derivative of the function h(x) = log2(1093^(√(x-3))) - 3^9, we can use the chain rule and the power rule of differentiation.

First, let's differentiate each term separately.

For the first term, log2(1093^(√(x-3))), we have a composition of functions. Let's denote the inner function as u = 1093^(√(x-3)). Applying the chain rule, we have:

d(u)/dx = (√(x-3)) * (1093^(√(x-3)))'   (differentiating the base with respect to x)

        = (√(x-3)) * (1093^(√(x-3))) * (√(x-3))'   (applying the power rule and chain rule)

        = (√(x-3)) * (1093^(√(x-3))) * (1/2√(x-3))   (simplifying the derivative)

Now, for the second term, -3^9, the derivative is simply 0 since it is a constant.

Combining the derivatives of both terms, we have:

h'(x) = (1/u) * d(u)/dx - 0

     = (1/u) * [(√(x-3)) * (1093^(√(x-3))) * (1/2√(x-3))]

Simplifying further, we can express the derivative as:

h'(x) = (1093^(√(x-3)) / (2(x-3))

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The rectangular form of the given parametric equations is x = 4 cos θ and y = 3 sin θ. The rectangular form of the given parametric equations x = 4 cos θ, y = 3 sin θ is obtained by expressing x and y in terms of a common variable, typically denoted as t.

The domain of the rectangular form is the same as the domain of the parameter θ, which is 1 € (0, 2π].

To convert the parametric equations x = 4 cos θ, y = 3 sin θ into rectangular form, we substitute the trigonometric functions with their corresponding expressions using the Pythagorean identity:

x = 4 cos θ

y = 3 sin θ

Using the Pythagorean identity: cos^2 θ + sin^2 θ = 1, we have:

x = 4(cos^2 θ)^(1/2)

y = 3(sin^2 θ)^(1/2)

Simplifying further:

x = 4(cos^2 θ)^(1/2) = 4(cos^2 θ)^(1/2) = 4(cos θ)

y = 3(sin^2 θ)^(1/2) = 3(sin^2 θ)^(1/2) = 3(sin θ)

Therefore, the rectangular form of the given parametric equations is x = 4 cos θ and y = 3 sin θ.

The domain of the rectangular form is the same as the domain of the parameter θ, which is 1 € (0, 2π].

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If f is an odd function, f(-4) would be -10.

If f(x) is an even function, it means that f(-x) = f(x) for all x in the domain of f. Given that f(4) = 10, we can deduce that f(-4) must also be equal to 10. This is because the function f(x) will produce the same output for both x = 4 and x = -4 due to its even symmetry.

If f(x) is an odd function, it means that f(-x) = -f(x) for all x in the domain of f. Since f(4) = 10, we can conclude that f(-4) = -10. This is because the function f(x) will produce the negative of its output at x = 4 when evaluating it at x = -4, as dictated by the odd symmetry. Therefore, f(-4) would be -10 in this case.

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since fy = 1 (a constant), its value is the same for all (x, y) points. Therefore, fy(-5, -2) = 1.

For the function f(x,y) = x + y, let's find the partial derivatives fx, fy, and evaluate them at specific points.

1. fx: The partial derivative of f with respect to x is found by taking the derivative of f while treating y as a constant. So, fx = ∂f/∂x = 1.

2. fy: The partial derivative of f with respect to y is found by taking the derivative of f while treating x as a constant. So, fy = ∂f/∂y = 1.

3. fx(3,3): Since fx = 1 (a constant), its value is the same for all (x, y) points. Therefore, fx(3,3) = 1.

4. fy(-5, -2): Similarly, since fy = 1 (a constant), its value is the same for all (x, y) points. Therefore, fy(-5, -2) = 1.

In summary:
- fx = 1
- fy = 1
- fx(3,3) = 1
- fy(-5, -2) = 1

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Riemann sum is an estimation of an area below or above a curve, which is approximated by rectangles.

Let us consider the following limit of Riemann sums of a function f on [a, b]:

n ×7 lim 2 (xx)'Axxi [4,6] A+0k=1

In order to identify f and express the limit as a definite integral,

let us start by defining the interval [4, 6].

Here, the first term of the Riemann sum, x1, will be equal to 4, and the nth term, xn, will be equal to 6.

We also know that the Riemann sum is the sum of areas of the rectangles whose heights are determined by the function f, and whose bases are determined by the interval [4, 6].

Therefore, the width of each rectangle, Δx, will be (6 - 4)/n or 2/n.

To express the limit as a definite integral,

let us write the Riemann sum as follows:

$$\lim_{n\to\infty}\sum_{k=1}^n 2\cdot f\left(4+k\cdot\frac{2}{n}\right)\cdot\frac{2}{n}$$The limit of this sum is the definite integral of the function f over the interval [4, 6].

Therefore, we can write the limit as follows:

$$\int_{4}^{6}f(x)\,dx$$Therefore, the function f is the function whose limit, as the number of rectangles approaches infinity, is the definite integral of f over [4, 6].

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4) Two techniques commonly used to algebraically solve limits are factoring and using conjugates.

The limit lim(x→1) (2x^3 - x^2 - x + 1) is computed using factoring.

The limit lim(x→4) (x^4 - x^-4) is computed using conjugates.

The requested information for question 7 is missing.

4) Two common techniques used to algebraically solve limits are factoring and using conjugates. Factoring involves manipulating the algebraic expression to simplify it and cancel out common factors, which can help in evaluating the limit. Using conjugates is another technique where the numerator or denominator is multiplied by its conjugate to eliminate radicals or complex numbers, facilitating the computation of the limit.

To compute the limit lim(x→1) (2x^3 - x^2 - x + 1) using factoring, we can factor the expression as (x - 1)(2x^2 + x - 1). Since the limit is evaluated as x approaches 1, we can substitute x = 1 into the factored form to find the limit. Thus, the result is (1 - 1)(2(1)^2 + 1 - 1) = 0.

To compute the limit lim(x→4) (x^4 - x^-4) using conjugates, we can multiply the numerator and denominator by the conjugate of x^4 - x^-4, which is x^4 + x^-4. This simplifies the expression as (x^8 - 1)/(x^4). Substituting x = 4 into the simplified expression gives us (4^8 - 1)/(4^4) = (65536 - 1)/256 = 25385/256.

The question is incomplete as it cuts off after mentioning "7) S." Please provide the full question for a complete answer.

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The given angle is 8° 55' 42". To convert this angle to decimal degrees, we need to convert the minutes and seconds to their decimal equivalents. The resulting angle will be in decimal degrees.

To convert the minutes and seconds to their decimal equivalents, we divide the minutes by 60 and the seconds by 3600, and then add these values to the degrees. In this case, we have:

8° + (55/60)° + (42/3600)°

Simplifying the fractions, we have:

8° + (11/12)° + (7/600)°

Combining the terms, we get:

8° + (11/12)° + (7/600)° = (8*12 + 11 + 7/600)° = (96 + 11 + 0.0117)° = 107.0117°

Therefore, the angle 8° 55' 42" is equivalent to 107.0117° in decimal degrees.

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The graph of the piecewise function f(x) is added as an attachment

From the question, we have the following parameters that can be used in our computation:

f(x) = 2 if 0 ≤ x ≤ 2

       3 if 2 ≤ x < 4

       -4 if 4 ≤ x ≤ 8

To graph the piecewise function, we plot each function according to its domain

Using the above as a guide, we have the following:

The graph of the piecewise function is added as an attachment

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Question

Graph the following

f(x) = 2 if 0 ≤ x ≤ 2

       3 if 2 ≤ x < 4

       -4 if 4 ≤ x ≤ 8

You can plot this function is Demos pretty easily. To do so enter the function as shown

The function f(x) = x^4 - 2x^2 + 3 is a polynomial of degree 4. It is an even function because all the terms have even powers of x, which means it is symmetric about the y-axis.

The significant features of the function include the x-intercepts, local extrema, and the behavior as x approaches positive or negative infinity. To find the x-intercepts, we set f(x) = 0 and solve for x. In this case, the equation x^4 - 2x^2 + 3 = 0 is not easily factorable, so we may need to use numerical methods or a graphing calculator to find the approximate values of the x-intercepts.

To determine the local extrema, we can find the critical points by taking the derivative of f(x) and setting it equal to zero. The derivative of f(x) is f'(x) = 4x^3 - 4x. Setting f'(x) = 0, we find the critical points x = -1, x = 0, and x = 1. We can then evaluate the second derivative at these points to determine if they correspond to local maxima or minima.

Finally, as x approaches positive or negative infinity, the function grows without bound, as indicated by the positive leading coefficient. This means the graph will have a positive end behavior.

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The solution to the given initial value problem, dp/dt = 5pt, p(1) = 6, is p(t) = 6e^(2t^2-2).

To solve the differential equation, we begin by separating the variables. We rewrite the equation as dp/p = 5t dt. Integrating both sides gives us ln|p| = (5/2)t^2 + C, where C is the constant of integration.

Next, we apply the initial condition p(1) = 6 to find the value of C. Substituting t = 1 and p = 6 into the equation ln|p| = (5/2)t^2 + C, we get ln|6| = (5/2)(1^2) + C, which simplifies to ln|6| = 5/2 + C.

Solving for C, we have C = ln|6| - 5/2.

Substituting this value of C back into the equation ln|p| = (5/2)t^2 + C, we obtain ln|p| = (5/2)t^2 + ln|6| - 5/2.

Finally, exponentiating both sides gives us |p| = e^((5/2)t^2 + ln|6| - 5/2), which simplifies to p(t) = ± e^((5/2)t^2 + ln|6| - 5/2).

Since p(1) = 6, we take the positive sign in the solution. Therefore, the solution to the differential equation with the initial condition is p(t) = 6e^((5/2)t^2 + ln|6| - 5/2), or simplified as p(t) = 6e^(2t^2-2)

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The constant c can be any value for the function f to be continuous on (-infinity, infinity).

To determine the value of the constant c for which the function f(x) is continuous on the entire real number line, we need to ensure that the function is continuous at the point x = 3, where the definition changes.

For the function to be continuous at x = 3, the left-hand limit and the right-hand limit at this point must exist and be equal.

In this case, the left-hand limit as x approaches 3 is given by cx^2 + 8x, and the right-hand limit as x approaches 3 is given by cx. For the limits to be equal, the value of c does not matter because the limits involve different terms.

Therefore, any value of c will result in the function f(x) being continuous on (-infinity, infinity). The continuity of f(x) is not affected by the value of c in this particular case

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The derivative of the function f(x) = (2^3 + 1)^(2 - 3x) * (4.25 - x) using logarithmic differentiation is

(d/dx) f(x) = (2^3 + 1)^(2 - 3x) * (4.25 - x) * (d/dx) (ln(4.25 - x))

To differentiate the function f(x) = (2^3 + 1)^(2 - 3x) * (4.25 - x), we can use logarithmic differentiation.

Take the natural logarithm of both sides of the equation

ln(f(x)) = ln((2^3 + 1)^(2 - 3x) * (4.25 - x))

Apply the logarithmic rules to simplify the expression

ln(f(x)) = (2 - 3x)ln(2^3 + 1) + ln(4.25 - x)

Differentiate implicitly with respect to x

(d/dx) ln(f(x)) = (d/dx) [(2 - 3x)ln(2^3 + 1) + ln(4.25 - x)]

Using the chain rule and the derivative of the natural logarithm, we have

(1/f(x)) * (d/dx) f(x) = (2 - 3x)(0) + (d/dx) (ln(2^3 + 1)) + (d/dx) (ln(4.25 - x))

Since the derivative of a constant is zero, we can simplify further

(1/f(x)) * (d/dx) f(x) = (d/dx) (ln(2^3 + 1)) + (d/dx) (ln(4.25 - x))

Evaluate the derivatives

(1/f(x)) * (d/dx) f(x) = (d/dx) (ln(9)) + (d/dx) (ln(4.25 - x))

The derivative of a constant is zero, so

(1/f(x)) * (d/dx) f(x) = 0 + (d/dx) (ln(4.25 - x))

Simplify the expression

(1/f(x)) * (d/dx) f(x) = (d/dx) (ln(4.25 - x))

Now, we can solve for (d/dx) f(x) by multiplying both sides by f(x):

(d/dx) f(x) = f(x) * (d/dx) (ln(4.25 - x))

Substituting back the original function f(x) = (2^3 + 1)^(2 - 3x) * (4.25 - x), we have

(d/dx) f(x) = (2^3 + 1)^(2 - 3x) * (4.25 - x) * (d/dx) (ln(4.25 - x))

Therefore, the derivative of the function f(x) = (2^3 + 1)^(2 - 3x) * (4.25 - x) using logarithmic differentiation is

(d/dx) f(x) = (2^3 + 1)^(2 - 3x) * (4.25 - x) * (d/dx) (ln(4.25 - x))

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The sum of the series 6-2 + 1²/23 - 1²/14 is approximately 3.9708. Since the sum of the terms approaches a finite value (3.9708), we can conclude that the series is convergent.

To determine the convergence of the series 6-2 + 1²/23 - 1²/14, we need to evaluate the sum of the terms and check if it approaches a finite value as we consider more terms.

Let's simplify the series step by step:

=6 - 2 + 1²/23 - 1²/14

= 6 - 2 + 1/23 - 1/14 (simplifying the squares)

= 6 - 2 + 1/23 - 1/14

Now, let's calculate the sum of these terms:

= 4 + 1/23 - 1/14

To combine the fractions, we need to find a common denominator. The common denominator for 23 and 14 is 322. Let's rewrite the terms with the common denominator:

= (4 * 322) / 322 + (1 * 14) / (14 * 23) - (1 * 23) / (14 * 23)

= 1288/322 + 14/322 - 23/322

= (1288 + 14 - 23) / 322

= 1279/322

= 3.9708

Therefore, the sum of the series 6-2 + 1²/23 - 1²/14 is approximately 3.9708.

Since the sum of the terms approaches a finite value (3.9708), we can conclude that the series is convergent.

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The partial derivatives of [tex]fx[/tex]= x / (√(x² + y²)) , [tex]fy[/tex] = y / (√(x² + y²)),

[tex]fx(4, 1)[/tex]= 4 / (√17) and [tex]fy(-1, -3)[/tex] =  -3 / (√10).

Let's calculate the partial derivatives of [tex]f(x, y)[/tex] = √(√(x² + y²)).

To find [tex]fx[/tex], we differentiate [tex]f(x, y)[/tex] with respect to x while treating y as a constant. Using the chain rule, we have:

[tex]fx[/tex] = (∂f/∂x) = (∂/∂x) √(√(x² + y²)).

Using the chain rule, we obtain:

[tex]fx[/tex] = (∂/∂x) (√(x² + y²))^(1/2).

Applying the power rule, we have:

[tex]fx[/tex] = (1/2) (√(x² + y²))^(-1/2) (2x).

Simplifying further, we get:

[tex]fx[/tex] = x / (√(x² + y²)).

Next, let's calculate [tex]fy[/tex] by differentiating [tex]f(x, y)[/tex] with respect to y while treating x as a constant.

Using the chain rule, we have:

[tex]fy[/tex] = (∂f/∂y) = (∂/∂y) √(√(x² + y²)).

Using the chain rule and the power rule, we obtain:

[tex]fy[/tex] = (1/2) (√(x² + y²))^(-1/2) (2y).

Simplifying, we get:

[tex]fy[/tex] = y / (√(x² + y²)).

To evaluate [tex]fx(4, 1)[/tex], we substitute x = 4 into the expression for [tex]fx[/tex]:

[tex]fx(4, 1)[/tex] = 4 / (√(4² + 1²)) = 4 / (√17).

To evaluate [tex]fx(4, 1)[/tex] we substitute y = -3 into the expression for [tex]fy[/tex]:

[tex]fy(-1, -3)[/tex]= -3 / (√((-1)² + (-3)²)) = -3 / (√10).

Therefore, the exact values are [tex]fx(4, 1)[/tex]= 4 / (√17) and [tex]fy(-1, -3)[/tex]= -3 / (√10).

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To evaluate the double integral ∫∫RxydA over the square region R, we can use a change of variables and an appropriate transformation. By using a transformation that maps the square region R to a simpler domain, such as the unit square, we can simplify the integration process.

The given region R is a square with vertices (0, 0), (1, 1), (2, 0), and (1, -1). To simplify the integration, we can use a change of variables and transform the square region R into the unit square [0, 1] × [0, 1] by using the transformation u = x - y and v = x + y.

The inverse transformation is given by x = (u + v)/2 and y = (v - u)/2. The Jacobian determinant of this transformation is |J| = 1/2.

Now, we can express the original integral in terms of the new variables u and v:

∫∫R xy dA = ∫∫R (x^2 - y^2) (x)(y) dA.

Substituting the transformed variables, we have:

∫∫R xy dA = ∫∫S (u + v)^2 (v - u)^2 (1/2) dudv,

where S is the unit square [0, 1] × [0, 1].

The integral over the unit square S simplifies to:

∫∫S (u + v)^2 (v - u)^2 (1/2) dudv = (1/2) ∫∫S (u^2 + 2uv + v^2)(v^2 - 2uv + u^2) dudv.

Expanding the expression, we get:

∫∫S (u^4 - 4u^2v^2 + v^4) dudv.

Integrating term by term, we have:

(1/5) (u^5 - (4/3)u^3v^2 + (1/5)v^5) evaluated over the limits of the unit square [0, 1] × [0, 1].

Evaluating this expression, we find the result of the double integral over the square region R.

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Step-by-step explanation:

Find the distance from the center to the point....this is the radius

               radius = sqrt 34

diameter = 2 x radius = 2 sqrt 34

circumference = pi * diameter =

                             pi * 2 sqrt (34) = 36.6 units

The scale factor ratio between the smaller and larger rectangular prisms is 2:3, and the surface area ratio is 2:3.

To find the scale factor ratio, we can take the cube root of the volume ratio. The cube root of 162 is approximately 5.08, and the cube root of 384 is approximately 7.87. Therefore, the scale factor ratio is approximately 5.08:7.87, which can be simplified to 2:3.

The surface area of a rectangular prism is proportional to the square of the scale factor. Since the scale factor ratio is 2:3, the surface area ratio would be the square of that ratio, which is 4:9.

Therefore, the scale factor ratio between the smaller and larger rectangular prisms is 2:3, and the surface area ratio is 4:9.

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