Calculus

Problem 2501

Réflexion
EXERCICE 1: CoTon
L'entreprise CoTon produit du tissu en coton. Celui-ci est fabriqué en 1 mètre de large et pour une longueur xx exprimée en kilomètre, xx étant compris entre Oet10. Le coût total de production en euros de l'entreprise CoTon est donné en fonction de la longueur xx par la formule : C(x)=15x3120x2+500x+750C(x)=15 x^{3}-120 x^{2}+500 x+750
Le graphique ci-contre donne la représentation graphique de la fonction C\mathbf{C}.
Partie A: Étude du bénéfice Si le marché offre un prix pp en euros pour un kilomètre de ce tissu, alors la recette de l'entreprise CoTon pour la vente d'une quantité xx est égal à R(x)=pxR(x)=p x.
1. Tracer sur le graphique la droite D1D_{1} d'équation : y=400xy=400 x. Expliquer, au vu de ce tracé, pourquoi l'entreprise CoTon ne peut pas réaliser un bénéfice si le prix pp du marché est égal à 400 euros.
2. Dans cette question on suppose que le prix du marché est égal à 680 euros. Tracer sur le graphique la droite D2D_{2} d'équation : y=680xy=680 x. Déterminer graphiquement, avec la précision permise par le graphique pour quelles quantités produites et vendues, l'entreprise CoTon réalise un bénéfice si le prix pp du marché est de 680 euros.
3. On considère la fonction BB définie sur l'intervalle [0;10][0 ; 10] par: B(x)=680xC(x)B(x)=680 x-C(x) Démontrer que pour tout xx appartenant à l'intervalle [0;10][0 ; 10], on a : B(x)=45x2+240x+180B^{\prime}(x)=-45 x^{2}+240 x+180
4. Étudier les variations de la fonction B sur [0;10][0 ; 10]. En déduire pour quelle quantité produite et vendue le bénéfice réalisé par l'entreprise CoTon est maximum. Donner la valeur de ce bénéfice.

Partie B: Étude du coût moyen On rappelle que le coût moyen de production CMC M mesure le coût par unité produite. On considère la fonction CMC M définie sur l'intervalle [0;10] par : CM(x)=C(x)xC M(x)=\frac{C(x)}{x}
1. Démontrer que pour tout xx appartenant à l'intervalle [0;10][0 ; 10], CM(x)=30(x5)(x2+x+5)x2C M^{\prime}(x)=\frac{30(x-5)\left(x^{2}+x+5\right)}{x^{2}}
2. Montrer que pour tout x[0;10]x \in[0 ; 10] le signe de CM(x)C M^{\prime}(x) est le même que celui de " (x5)(x-5) "
3. Pour quelle quantité de tissu produite le coût moyen de production est-il minimum? Que valent dans ce cas le coût moyen de production et le coût total?

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Problem 2502

Find equations of the tangent lines to the curve y2xy12=0y^{2}-x y-12=0 at the points (1,3)(-1,3), and (1,4)(-1,-4).
The tangent line at (1,3)(-1,3) is y=y= \square (Type your answer in slope-intercept form. Use integers or fractions for any numbers in the expression.)

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Problem 2503

```latex Let F(x)F(x) be an antiderivative of f(x)=(x1)(x2)f(x)=(x-1)(x-2) such that F(0)=2F(0)=2. Which of the following graphs if the most accurate graph of F(x)F(x) ? Circle your choice and explain your answer below.
Option A
Option B
Option C
Option D ```

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Problem 2504

The flow diagram below shows the volume of fluid in a chemostat (a growth chamber for bacteria).
Poll 1: The ODE is: A. dV(t)dt=fd\frac{d V(t)}{d t}=f-d B. dV(t)dt=fV(t)\frac{d V(t)}{d t}=f V(t)

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Problem 2505

8. Integrate: 1t2+11t+tdt\int \frac{-\frac{1}{t^{2}}+1}{\sqrt{\frac{1}{t}+t}} d t

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Problem 2506

A model helicopter takes off from a point OO at time t=0 st=0 \mathrm{~s} and moves vertically so that its height y cmy \mathrm{~cm}, above OO after time tt seconds is given by y=14t426t2+96t,0t4y=\frac{1}{4} t^{4}-26 t^{2}+96 t, \quad 0 \leq t \leq 4 a) Find (i) dydt\frac{d y}{d t} (ii) d2ydt2\frac{d^{2} y}{d t^{2}} b) Verify that yy has a stationary value when t=2t=2 and determine whether this stationary value is a maximum or a minimum value. c) Find the rate of change of yy with respect to tt when t=1t=1. d) Determine whether the height of the helicopter is increasing or decreasing at the instant when t=3t=3.

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Problem 2507

 solve: 2xyy=y2x2\text { solve: } 2 x y y^{\prime}=y^{2}-x^{2} the ODE

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Problem 2508

3. Test for exactness. If exact, solve. If not, use an integrating factor to solve it. 2xydx+x2dy=02 x y d x+x^{2} d y=0

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Problem 2509

Find dy/dxd y / d x in terms of xx and yy if x3yx4y2=0x^{3} y-x-4 y-2=0. dydx=\frac{d y}{d x}= \square

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Problem 2510

Kuta Software - Infinite Calculus Slope at a Value Date \qquad Perio
For each problem, find the slope of the function at the given value. 1) y=x2+6x+7y=x^{2}+6 x+7 at x=2x=-2 2) y=x33x2+5y=x^{3}-3 x^{2}+5 at x=3x=3 3) y=x36x2+9x4y=x^{3}-6 x^{2}+9 x-4 at x=2x=2 4) y=x36x29x+1y=-x^{3}-6 x^{2}-9 x+1 at x=4x=-4

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Problem 2511

21. Design a cylindrical can (with a lid) to contain 1 liter (=1000 cm3)\left(=1000 \mathrm{~cm}^{3}\right) of water, using the minimum amount of meta

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Problem 2512

f(x)=x46x3+x2+42x56f(x)=x^{4}-6 x^{3}+x^{2}+42 x-56
Find the zero(s) at which ff "flattens out". Express the zero(s) as ordered pair(s).

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Problem 2513

The function given by y=f(x)y=f(x) shows the value of $5000\$ 5000 invested at 6%6 \% interest compounded continuously, xx years after the money was originally invested. (Round your answers to the nearest cent.) Value of $5000\$ 5000 with Continuous Compounding at 6%6 \%
Part: 0/30 / 3
Part 1 of 3 (a) Find the average amount earned per year between the 5 th year and the 10 th year.
The average amount earned between the Sth year and 10 th year is $\$ per year.

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Problem 2514

f(x)=x4+4x33x224x18f(x)=x^{4}+4 x^{3}-3 x^{2}-24 x-18
Find the zero(s) at which ff "flattens out". Express the zero(s) as ordered pair(s).

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Problem 2515

Question
It is estimated that the population of a certain town changes at the rate of 3+t3/53+t^{3 / 5} people per month. If the current population is 30,000 , what will the population be in 7 months? (Round your answer to the nearest whole number.)

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Problem 2516

Question Evaluate the indefinite integral xx9dx\int x \sqrt{x-9} d x

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Problem 2517

Question Evaluate using integration by parts. xe4xdx\int x e^{-4 x} d x

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Problem 2518

Let A(t)=3000e0.03tA(t)=3000 e^{0.03 t} be the balance in a savings account after tt years. Complete parts (a) through ( ff ) below. (Kound to the nearest cent as needed.) (d) What differential equation is satisfied by y=A(t)y=A(t) ?
The differential equation that is satisfied by y=A(t)y=A(t) is A(t)=0.03A(t)A^{\prime}(t)=0.03 A(t). (e) Use the results from parts (c) and (d) to determine how fast the balance is growing after 11 years.
The balance is growing at approximately $\$ \square per year after 11 years. (Round to the nearest cent as needed.)

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Problem 2519

Question Evaluate xe5xdx\int x e^{5 x} d x. Choose u=xu=x and dv=e5xdxd v=e^{5 x} d x.

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Problem 2520

Evaluate each definite integral if it is known that 03f(x)dx=5, and 03g(x)dx=3\begin{array}{l} \int_{0}^{3} f(x) d x=-5, \text { and } \\ \int_{0}^{3} g(x) d x=3 \end{array}
Utilize properties of definite integrals to evaluate 03[2f(x)+3g(x)]dx\int_{0}^{3}[2 f(x)+3 g(x)] d x

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Problem 2521

Let A(t)=3000e0.03tA(t)=3000 e^{0.03 t} be the balance in a savings account after tt years. Complete parts (a) through (f) below. (e) Use the results from parts (c) and (d) to determine how fast the balance is growing after 11 years.
The balance is growing at approximately $125.19\$ 125.19 per year after 11 years. (Round to the nearest cent as needed.) (f) How large will the balance be when it is growing at the rate of $120\$ 120 per year?
The balance will be $\$ \square when it is growing at the rate of $120\$ 120 per year. (Round to the nearest cent as needed.)

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Problem 2522

Question
Evaluate 02(7f(x)6g(x))dx\int_{0}^{2}(7 f(x)-6 g(x)) d x given that 014f(x)dx=9,02f(x)dx=9,014g(x)dx=5\int_{0}^{14} f(x) d x=9, \int_{0}^{2} f(x) d x=-9, \int_{0}^{14} g(x) d x=5, and 02g(x)dx=3\int_{0}^{2} g(x) d x=3
Provide your answer below:

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Problem 2523

Question
The marginal cost of production is found to be C(x)=120030x+x2C^{\prime}(x)=1200-30 x+x^{2} where xx is the number of units produced. The fixed cost of production is $7500\$ 7500. The manufacturer sets the price per unit at $3000\$ 3000. Find the cost function.

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Problem 2524

Find the cost function C. Determine where the cost is a minimum. (a) C(x)=14x2800C^{\prime}(x)=14 x-2800 (b) C(x)=20x8000C^{\prime}(x)=20 x-8000
Fixed cost =$4300=\$ 4300 Fixed cost =$500=\$ 500
Provide your answer below:

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Problem 2525

Four thousand dollars is deposited into a savings account at 4.5%4.5 \% interest compounded continuously. (a) What is the formula for A(t)A(t), the balance after tt years? (b) What differential equation is satisfied by A(t)\mathrm{A}(\mathrm{t}), the balance after t years? (c) How much money will be in the account after 9 years? (d) When will the balance reach $8000\$ 8000 ? (e) How fast is the balance growing when it reaches $8000\$ 8000 ? (b) A(t)=0.045AA^{\prime}(t)=0.045 A (c) $\$ \square (Round to the nearest cent as needed.)

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Problem 2526

Question Population Growth It is estimated that the population of a certain town changes at the rate of 2+t4/52+t^{4 / 5} people per month. If the current population is 20,000 , what will the population be in 10 months?
Provide your answer below:
Population in 10 months = \square FEEDBACK MORE INSTRUCTION SUBMIT

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Problem 2527

An object has a constant acceleration of 2 ft per sec every second for a short time of 6 seconds, and then the acceleration decreases to 0 as shown in the graph. Complete parts a through c. (a) Find 010a(t)dt\int_{0}^{10} a(t) d t. Include units. 010d(x)dt=8ft/sec\int_{0}^{10} d(x) d t=8 \mathrm{ft/sec} per sec (Simplify your answer.)

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Problem 2528

The marginal cost of oil production, in dollars per barrel, is represented by C(x)\mathrm{C}^{\prime}(\mathrm{x}), where x is the number of barrels of oil produced. Report the units of 600C(x)dx\int_{600} \mathrm{C}^{\prime}(\mathrm{x}) \mathrm{dx} and interpret what the integral means.
The units of 600640C(x)dx\int_{600}^{640} C^{\prime}(x) d x are \square

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Problem 2529

Use integration by substitution to solve the integral below. Use CC for the constant of integration. y35y49dy\int-y^{3} \sqrt{5 y^{4}-9} d y

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Problem 2530

During a local high school foothall game, the quarterback for the home team attempts a deep pass to his wide recelver. The ball is launched from 6.25 feet with an initial velocity of 73 feet per second (f/s). a) Write the equation modeling the projectile motion for the football and sketch the graph.

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Problem 2531

Find the difference quotient f(x+h)f(x)h\frac{f(x+h)-f(x)}{h} for f(x)=6x+5f(x)=-6x+5, with h0h \neq 0. Simplify your answer.

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Problem 2532

Find the difference quotient of f(x)=1x+2f(x)=\frac{1}{x+2} and simplify.

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Problem 2533

Determine the marginal cost from the cost function C(x,y)=240,000+6,000x+4,000yC(x, y) = 240,000 + 6,000x + 4,000y.

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Problem 2534

Given the function f(x)={2x+18 if x<6x+42 if x>62 if x=6f(x)=\left\{\begin{array}{lll}2 x+18 & \text { if } & x<-6 \\ \sqrt{x+42} & \text { if } & x>-6 \\ 2 & \text { if } & x=-6\end{array}\right., determine the truth of the following statements about f(6)f(-6) and its limits.

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Problem 2535

Find h(5)h^{\prime}(-5) if h(x)=f(x)g(x)h(x)=f(x)-g(x), given f(5)=8,f(5)=2,g(5)=3,g(5)=5f(-5)=8, f'(-5)=-2, g(-5)=3, g'(-5)=5.

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Problem 2536

Find the integral of 1x2x+1\frac{1}{x^{2}-x+1} with respect to xx.

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Problem 2537

Find the limit of the fish length model L(t)=LT(LTL0)ektL(t)=L_{T}-\left(L_{T}-L_{0}\right) e^{-k t} as tt \to \infty.

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Problem 2538

Un cohete "Pioneer" alcanzó 125.000 km125.000 \mathrm{~km}. ¿Cuál es su velocidad al regresar a la atmósfera a 130 km130 \mathrm{~km}?

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Problem 2539

Demostrar que la serie n=1(sennx)/n2\sum_{n=1}^{\infty}(\operatorname{sen} n x) / n^{2} converge para todo xx, y que f(x)f(x) es continua en [0,π][0, \pi]. Luego, probar que 0πf(x)dx=2n=11(2n1)3\int_{0}^{\pi} f(x) d x=2 \sum_{n=1}^{\infty} \frac{1}{(2 n-1)^{3}}.

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Problem 2540

Find the limit as xx approaches 1 for the expression 23x2 - 3x.

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Problem 2541

Evaluate the limit: 107limx1(23x)=1107 \lim _{x \rightarrow 1}(2-3 x)=-1

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Problem 2542

16. The acceleration due to gravity on Earth is 9.8 m/s29.8 \mathrm{~m} / \mathrm{s}^{2}. A ball is thrown upward at an initial velocity of 15 m/s15 \mathrm{~m} / \mathrm{s} from a height of 1 m above the ground. Round answers to the nearest tenth. a) Write an equation for the height of the ball. b) What is the height of the ball after 1 s ? c) After how many seconds does the ball land? d) What is the maximum height of the 20. ball? When does this occur? e) Repeat parts a) to d) for a ball thrown on the Moon, where g=1.62 m/s2g=1.62 \mathrm{~m} / \mathrm{s}^{2}. f) Repeat parts a) to d) for a ball thrown on Jupiter, where g=23.1 m/s2g=23.1 \mathrm{~m} / \mathrm{s}^{2}.

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Problem 2543

Encercler une primitive de la fonction f(x)=sec2x+1xf(x)=\sec ^{2} x+\frac{1}{x}. (A) tanx+lnxπ\tan x+\ln |x|-\pi (D) tan2xlnx+5\tan ^{2} x-\ln |x|+5 (B) tan2x+2x2\tan ^{2} x+\frac{2}{x^{2}} (E) tan2x+x22\tan ^{2} x+\frac{x^{2}}{2} (C) 2sec2xtanx1x22 \sec ^{2} x \tan x-\frac{1}{x^{2}} (F) Aucune de ces réponses

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Problem 2544

Use properties of power series, substitution, and factoring of constants to find the first four nonzero terms of the Taylor series centered at 0 for the function given below. Use the Taylor series (1+x)2=12x+3x24x3+(1+x)^{-2}=1-2 x+3 x^{2}-4 x^{3}+\cdots, for 1<x<1-1<x<1. (1+4x)2(1+4 x)^{-2}
The first term is \square

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Problem 2545

Find the equations of the tangent line and normal lines to the graph of the function f(x)=6sinxf(x)=-6 \sin x at x=π/2x=\pi / 2. a) Tangent line: ? \square b) Normal line: \square \square

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Problem 2546

Página Principal Área personal Mis cursos
Una persona que camina por un camino recto tiene su velocidad en millas por hora en el tiempo tt dado por la función v(t)=0.25t31.5t2+3t+0.25v(t)=0.25 t^{3}-1.5 t^{2}+3 t+0.25, para tiempos en el intervalo 0t20 \leq t \leq 2. El gráfico de esta función también se propo el diagrama a continuación. Tiempo rest
Determine el valor de U=C1+C2+C3+C4U=C_{1}+C_{2}+C_{3}+C_{4} evaluando la función y=v(t)y=v(t) en los valores elegidos adecuadamente y observando el ancho de cada rectángulo. Seleccione una:

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Problem 2547

Challenging: y=[x3+(2x1)3]5y=\left[x^{3}+(2 x-1)^{3}\right]^{5} find yy^{\prime}

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Problem 2548

The total cost (in dollars) of producing xx coffee machines is C(x)=1800+50x0.8x2C(x)=1800+50 x-0.8 x^{2} (A) Find the exact cost of producing the 21st machine.
Exact cost of 21st machine == \square (B) Use marginal cost to approximate the cost of producing the 21 st machine.
Approx. cost of 21st machine == \square

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Problem 2549

The total profit (in dollars) from the sale of xx charcoal grills is P(x)=50x0.5x2245P(x)=50 x-0.5 x^{2}-245 (A) Find the average profit per grill if 40 grills are produced.
Ave. profit = \square Find the marginal average profit at a production level of 40 grills. (B) Marginal avergge profit = \square Use the results from parts (A) and (B) to estimate the average profit per grill if 41 grills are produced. (C) Estimated average profit == \square

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Problem 2550

The total profit (in dollars) from the sale of xx charcoal grills is P(x)=50x0.5x2245P(x)=50 x-0.5 x^{2}-245 (A) Find the average profit per grill if 40 grills are produced.
Ave. profit =23.875=23.875 Find the marginal average profit at a production level of 40 grills. (B) Marginal average profit =24.125=24.125
Use the results from parts (A) and (B) to estimate the average profit per grill if 41 grills are produced. (C) Estimated average profit =24.125=24.125

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Problem 2551

The price-demand and cost functions for the production of microwaves are given as p=235x90p=235-\frac{x}{90} and C(x)=26000+60x,C(x)=26000+60 x, where xx is the number of microwaves that can be sold at a price of pp dollars per unit and C(x)C(x) is the total cost (in dollars) of producing xx units. (A) Find the marginal cost as a function of xx. C(x)=C^{\prime}(x)= (B) Find the revenue function in terms of xx. R(x)=R(x)= \square (C) Find the marginal revenue function in terms of xx. R(x)=R^{\prime}(x)= \square (D) Evaluate the marginal revenue function at x=1500x=1500. R(1500)=R^{\prime}(1500)= \square (E) Find the profit function in terms of xx. P(x)=P(x)= \square (F) Evaluate the marginal profit function at x=1500x=1500. P(1500)=P^{\prime}(1500)=\square

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Problem 2552

A retail store estimates that weekly sales ss and weekly advertising costs xx (both in dollars) are related by s=60000430000e0.0005xs=60000-430000 e^{-0.0005 x}
The current weekly advertising costs are 2000 dollars and these costs are increasing at the rate of 300 dollars per week. Find the current rate of change of sales. Rate of change of sales == \square

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Problem 2553

A price pp (in dollars) and demand xx for a product are related by 2x22xp+50p2=162002 x^{2}-2 x p+50 p^{2}=16200
If the price is increasing at a rate of 2 dollars per month when the price is 10 dollars, find the rate of change of the demand. Rate of change of demand = \square

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Problem 2554

Suppose that for a company manufacturing calculators, the cost, and revenue equations are given by C=80000+30x,R=200x240C=80000+30 x, \quad R=200-\frac{x^{2}}{40} where the production output in one week is xx calculators. If the production rate is increasing at a rate of 500 calculators when the production output is 6000 calculators, find each of the following:
Rate of change in cost == \square
Rate of change in revenue == \square
Rate of change in profit = \square

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Problem 2555

Find the intervals on which f(x)f(x) is increasing, the intervals on which f(x)f(x) is decreasing, and the local extrema. f(x)=x3+2x+1f(x)=x^{3}+2 x+1
Find f(x)f^{\prime}(x). f(x)=x3+2x+1f(x)=\begin{array}{l} f(x)=x^{3}+2 x+1 \\ f^{\prime}(x)=\square \end{array}

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Problem 2556

A retail store estimates that weekly sales ss and weekly advertising costs xx (both in dollars) are related by s=60000430000e0.0005xs=60000-430000 e^{-0.0005 x}
The current weekly advertising costs are 2000 dollars and these costs are increasing at the rate of 300 dollars per week. Find the current rate of change of sales.
Rate of change of sales = \square 2372.96

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Problem 2557

=autosave\#questio... ns that the particle moved approximately 30.00 meters to the left. that v(t)=t2t20=(t5)(t+4)v(t)=t^{2}-t-20=(t-5)(t+4) and so v(t)v0v(t) \leq v \quad 0 on the interval [1,5][1,5] and v(t)v(t) nus, from this equation, the distance traveled is 17v(t)dt=15[v(t)]dt+57v(t)dt=15(t2+t+20)dt+57(t2t20)dt\begin{aligned} \int_{1}^{7}|v(t)| d t & =\int_{1}^{5}[-v(t)] d t+\int_{5}^{7} v(t) d t \\ & =\int_{1}^{5}\left(-t^{2}+t+20\right) d t+\int_{5}^{7}\left(t^{2}-t-20\right) d t \end{aligned} =[t33+t22+20t]15+[t33t2220t]=\left[-\frac{t^{3}}{3}+\frac{t^{2}}{2}+20 t\right]_{1}^{5}+\left[\frac{t^{3}}{3}-\frac{t^{2}}{2}-20 t\right] =7253=\frac{725}{3} Your answer is correct.

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Problem 2558

The function given by y=f(x)y=f(x) shows the value of $5000\$ 5000 invested at 5%5 \% interest compounded continuously, xx years after the money was originally invested. (Round your answers to the nearest cent.) Value of $5000\$ 5000 with Continuous Compounding at 5%5 \%
Part: 0/30 / 3
Part 1 of 3 (a) Find the average amount earned per year between the 5 th year and the 10 th year.
The average amount earned between the 5 th year and 10 th year is $364.80\$ 364.80 per year. \square
Part: 1 / 3 \square
Part 2 of 3 (b) rind the average amount earned per year between the 20 th year and the 25 th year.
The average ampunt earned between the 20 th year and 25 th year is $\$ per vear. \square

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Problem 2559

Evaluate the integral. Use CC (upper case) for the constant of integration. 8x+916x2dx\int \frac{8 x+9}{\sqrt{16-x^{2}}} d x

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Problem 2560

1. Find dydx\frac{d y}{d x} in terms of tt for the following parametric equations. (i) x=t4+t\quad x=t^{4}+t and y=t32ty=t^{3}-2 t (ii) x=e3t+2x=e^{3 t}+2 and y=2t2+ty=2 t^{2}+t (iii) x=4t3tx=4 t^{3}-t and y=t2+8ty=t^{2}+8 t
2. Find yy for the following, by using the given substitution. (i) y=xx2+2dx\quad y=\int x \sqrt{x^{2}+2} d x \quad, let u=x2+2u=x^{2}+2 (ii) y=x1x2dxy=\int x \sqrt{1-x^{2}} d x, let u=1x2u=1-x^{2} (iii) y=33x223xx3dxy=\int \frac{-3-3 x^{2}}{2-3 x-x^{3}} d x \quad, let u=23xx3u=2-3 x-x^{3}
3. Consider the function x3x2y+2y2=8x^{3}-x^{2} y+2 y^{2}=8 (i) Differentiate the function implicitly and show that dydx=2xy3x24yx2\frac{d y}{d x}=\frac{2 x y-3 x^{2}}{4 y-x^{2}} (ii) Find the tangent equation to the curve x3x2y+2y2=8x^{3}-x^{2} y+2 y^{2}=8 at the point (2,0)(2,0).
4. Consider the function 4y33x2y+x=14 y^{3}-3 x^{2} y+x=1 (i) Differentiate the function implicitly and show that dydx=6xy112y23x2\frac{d y}{d x}=\frac{6 x y-1}{12 y^{2}-3 x^{2}} (ii) Find the normal equation to the curve 4y33x2y+x=14 y^{3}-3 x^{2} y+x=1 at the point (0,1)(0,1).
5. Find the point of intersection between the curve y=9x2y=9-x^{2} and the straight line yx3=0y-x-3=0 shown in Figure 1 below.

Hence, find the area bounded by the curve and the straight line.
Figure 1
6. Find the point of intersection between the two curves y=x2+2x+2y=x^{2}+2 x+2 and y=x2+2x+10y=-x^{2}+2 x+10. Hence, find the area bounded by the two curves.

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Problem 2561

Find the slope of the tangent line to the ellipse x225+y29=1\frac{x^{2}}{25}+\frac{y^{2}}{9}=1 at the point (x,y)(x, y). slope == \square
Are there any points where the slope is not defined? (Enter them as comma-separated ordered-pairs, e.g., (1,3), ( 2,5)-2,5). Enter none if there are no such points.) slope is undefined at \square

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Problem 2562

Докажите, что множество [0,1)Q[0,1) \cap \mathbb{Q} не компактно.

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Problem 2563

All changes saved
The power, PP, dissipated when a 11 -volt battery is put across a resistance of RR ohms is given by P=121RP=\frac{121}{R}
What is the rate of change of power with respect to resistance? rate of change ==

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Problem 2564

a. limx2x45x64x8=\lim _{x \rightarrow 2} \frac{x^{4}-5 x-6}{4 x-8}=

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Problem 2565

(ii) cscxcos3xdx\int \sqrt{\csc x} \cos ^{3} x d x

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Problem 2566

b. limx12x115x5\lim _{x \rightarrow 1} \frac{\sqrt{2 x-1}-1}{5 x-5}

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Problem 2567

5) A rectangular metal sheet shrinks while maintaining its shape, such that its length decreases at a rate of 3 cm/second3 \mathrm{~cm} / \mathrm{second} and its width decreases at a rate of 2 cm/second2 \mathrm{~cm} / \mathrm{second}. Find the rate of change of its area with respect to time when its length is 6 cm and its width is 5 cm .

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Problem 2568

1. Find the equations of the tangent line to the ellipse, (x+2)24+(y3)29\frac{(x+2)^{2}}{4}+\frac{(y-3)^{2}}{9} when x=3x=-3.

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Problem 2569

Thursday, November 28, 2024 Midterm Exam Calculus I d (0203101 \& 0213105 )
اكتب رمز الإجابة الصحيحة في الجدول بالحروف الكبيزة A, B, C, D \begin{tabular}{|l|l|l|l|l|l|l|l|l|l|l|l|l|l|l|l|} \hline Question & 1 & 2 & 3 & 4 & 5 & 6 & 7 & 8 & 9 & 10 & 11 & 12 & 13 & 14 & 15 \\ \hline Answer & & & & & & & & & & & & & & & \\ \hline \end{tabular}
If f(x)=4x1,g(x)=4xf(x)=\frac{4}{x-1}, g(x)=4 x, then the value of xx at which fg(x)=gf(x)f \circ g(x)=g \circ f(x) is: A) 14\frac{1}{4} B) 15\frac{1}{5} C) 13-\frac{1}{3} D) 13\frac{1}{3}
The graph of the function f(x)=(x27x+10)x225f(x)=\frac{\left(x^{2}-7 x+10\right)}{x^{2}-25} has at x=5x=-5 A) jump B) Hole C) Vertical asymptote D) continuity point

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Problem 2570

7-18 Use Part 1 of the Fundamental Theorem of Calculus to find the derivative of the function.
7. g(x)=1x1t3+1dtg(x)=\int_{1}^{x} \frac{1}{t^{3}+1} d t
8. g(x)=3xet2tdtg(x)=\int_{3}^{x} e^{t^{2}-t} d t
9. g(s)=5s(tt2)8dtg(s)=\int_{5}^{s}\left(t-t^{2}\right)^{8} d t
10. g(r)=0rx2+4dxg(r)=\int_{0}^{r} \sqrt{x^{2}+4} d x
11. F(x)=xπ1+sectdtF(x)=\int_{x}^{\pi} \sqrt{1+\sec t} d t [\left[\right. Hint: xπ1+sectdt=πx1+sectdt]\left.\int_{x}^{\pi} \sqrt{1+\sec t} d t=-\int_{\pi}^{x} \sqrt{1+\sec t} d t\right]

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Problem 2571

6. Locate all turning points, classifying them, on the curve y=6x48x324x24y=6 x^{4}-8 x^{3}-24 x^{2}-4

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Problem 2572

29. 19x1xdx\int_{1}^{9} \frac{x-1}{\sqrt{x}} d x
30. 02(y1)(2y+1)dy\int_{0}^{2}(y-1)(2 y+1) d y
31. 0π/4sec2tdt\int_{0}^{\pi / 4} \sec ^{2} t d t
32. 0π/4secθtanθdθ\int_{0}^{\pi / 4} \sec \theta \tan \theta d \theta
33. 12(1+2y)2dy\int_{1}^{2}(1+2 y)^{2} d y
34. 03(2sinxex)dx\int_{0}^{3}\left(2 \sin x-e^{x}\right) d x

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Problem 2573

2.) (5pts) Evaluate the limit, if it exists. limx2x+2x3+8\lim _{x \rightarrow-2} \frac{x+2}{x^{3}+8}

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Problem 2574

13. Ein U-Boot beginnt eine Tauchfahrt in P(1002000)\mathrm{P}(100|200| 0) mit 11,1 Knoten in Richtung des Peilziels Z(50040080)Z(500|400|-80), bis es eine Tiefe von 80 m erreicht hat. (1 Knoten =1 Seemeile  Stunde 1,852 km h)\left(1 \text { Knoten }=1 \frac{\text { Seemeile }}{\text { Stunde }} \approx 1,852 \frac{\mathrm{~km}}{\mathrm{~h}}\right)
Anschließend geht es ohne Kurswechsel in eine horizontale Schleichfahrt von 11 Knoten ein. Könnte es zu einer Kollision mit der Tauchkugel T kommen, die zeitgleich vom Forschungsschiff S(7008000)S(700|800| 0) mit einer Geschwindigkeit von 0,5 m s0,5 \frac{\mathrm{~m}}{\mathrm{~s}} senkrecht sinkt?

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Problem 2575

```latex \textbf{Flüssigkeiten bei einem Produktionsprozess}
In einem Produktionsprozess werden Flüssigkeiten erhitzt und anschließend abgekühlt. Der Temperaturverlauf kann gezielt gesteuert werden, sodass er sich für den gesamten Erhitzungs- bzw. Abkühlungsvorgang für t0t \geq 0 durch eine der in R\mathbf{R} definierten Funktionen fkf_{k} mit fk(t)=23+20te110ktf_{k}(t)=23+20 \cdot t \cdot e^{-\frac{1}{10} \cdot k \cdot t}, wobei kk eine positive, reelle Zahl sein soll, beschreiben lässt. Dabei ist tt die seit Beginn des Vorgangs vergangene Zeit in Minuten und fk(t)f_{k}(t) die Temperatur in C{ }^{\circ} C.
\begin{enumerate} \item[a)] Die in Abbildung 1 dargestellten Graphen A,BA, B und CC gehören jeweils zu einem der Werte k=0,5;k=2k=0,5; k=2 und k=5k=5. Ordnen Sie jedem dieser Werte den zugehörigen Graphen zu. \item[b)] Begründen Sie, dass der in Abbildung 1 dargestellte Graph DD nicht zu einer der Funktionen fkf_{k} gehören kann. \item[c)] Zeigen Sie, dass gilt fk(t)=20e110kt(1110kt)f_{k}^{\prime}(t)=20 \cdot e^{-\frac{1}{10} \cdot k \cdot t} \cdot\left(1-\frac{1}{10} \cdot k \cdot t\right) \item[d)] Ermitteln Sie denjenigen Wert von kk, für den die Flüssigkeit im Modell eine Höchsttemperatur von 123C123^{\circ} \mathrm{C} erreicht. \item[e)] Ermitteln Sie die Koordinaten des Wendepunktes des Graphen von f10f_{10}. Interpretieren Sie anschließend die Bedeutung der x-Koordinate dieses Wendepunkts des Graphen von f10f_{10} im Sachzusammenhang. \item[f)] Der in der Abbildung 2 dargestellte Graph gibt für einen gesteuerten Temperaturverlauf die Änderungsrate der Temperatur in Abhängigkeit von der Zeit an, die seit Beginn des Vorgangs vergangen ist. Bestimmen Sie einen Näherungswert für die Änderung der Temperatur in den ersten vier Minuten nach Beginn des Vorganges und geben Sie an, ob die Temperatur zu- oder abnimmt. \item[g)] Skizzieren Sie für die ersten zwölf Minuten des in Abbildung 2 dargestellten Vorgangs den Graphen eines möglichen Temperaturverlaufs. \end{enumerate}
\textit{Abbildung 1}
\textit{Abbildung 2} ```

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Problem 2576

13. Ein U-Boot beginnt eine Tauchfahrt in P(1002000)\mathrm{P}(100|200| 0) mit 11,1 Knoten in Richtung des Peilziels Z(50040080)Z(500|400|-80), bis es eine Tiefe von 80 m erreicht hat. (1 Knoten =1 Seemeile  Stunde 1,852 km h)\left(1 \text { Knoten }=1 \frac{\text { Seemeile }}{\text { Stunde }} \approx 1,852 \frac{\mathrm{~km}}{\mathrm{~h}}\right)
Anschließend geht es ohne Kurswechsel in eine horizontale Schleichfahrt von 11 Knoten ein. Könnte es zu einer Kollision mit der Tauchkugel T kommen, die zeitgleich vom Forschungsschiff S(7008000)S(700|800| 0) mit einer Geschwindigkeit von 0,5 m s0,5 \frac{\mathrm{~m}}{\mathrm{~s}} senkrecht sinkt?

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Problem 2577

f(x)=2x2+1f(x)=2 x^{2}+1, given that f(x)=limh0f(x+h)f(x)hf^{\prime}(x)=\lim _{h \rightarrow 0} \frac{f(x+h)-f(x)}{h} then f(x)=f^{\prime}(x)=

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Problem 2578

```latex f(x)={x2,πx0,0,0<xπ.f(x)=\left\{\begin{array}{lr}x-2, & -\pi \leq x \leq 0, \\ 0, & 0<x \leq \pi .\end{array}\right.
(Omsem: f(x)=π+42+2πk=1cos((2k1)x)(2k1)2+f(x)=-\frac{\pi+4}{2}+\frac{2}{\pi} \sum_{k=1}^{\infty} \frac{\cos ((2 k-1) x)}{(2 k-1)^{2}}+
+4+ππk=1sin((2k1)x)2k1k=1sin(2kx)2k.)\left.+\frac{4+\pi}{\pi} \sum_{k=1}^{\infty} \frac{\sin ((2 k-1) x)}{2 k-1}-\sum_{k=1}^{\infty} \frac{\sin (2 k x)}{2 k} .\right)

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Problem 2579

16 Berechne den Inhalt der Fläche, den der Graph der Funktion ff mit f(x)=x2x2f(x)=x^{2}-x-2 mit der xx-Achse einschließt.

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Problem 2580

(b) Find 11etdt\int \frac{1}{1-e^{t}} d t.

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Problem 2581

limn(1+2017ln(n))ln(n)\lim _{n \rightarrow \infty}\left(1+\frac{2017}{\ln (n)}\right)^{\ln (n)}

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Problem 2582

Solve the following Differential equations: (1) (1+ex)y=ex\left(1+e^{x}\right) y^{\prime}=e^{x}

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Problem 2583

5 PROBLEMA SVOLTO 4,0 mol4,0 \mathrm{~mol} di un gas perfetto monoatomico si trovano nello stato iniziale AA e dopo quattro trasformazioni, rappresentate nel grafico, tornano in AA. a) Determina la temperatura in ciascuno stato. b) In relazione a ciascuna trasformazione AB,BC,CD,DAA B, B C, C D, D A calcola il calore assorbito o ceduto, il lavoro prodotto o subito e la variazione di energia interna. c) Trova infine il calore totale scambiato, il lavoro totale e la variazione totale di energia interna.

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Problem 2584

limx1x3+x2+x+1x+1\lim _{x \rightarrow-1} \frac{x^{3}+x^{2}+x+1}{x+1}

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Problem 2585

Q₁ → The value of The value of c that satisfies the conclusion of the mean value theorem for the function f(x)=x-= on the interval [1,4] Momen & Azdeen a) 3 b) 2 c) 1-2,24 d) None Q1 08:18 p

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Problem 2586

3.32. Në qoftë se densiteti i XX është f(x)=1,0<x<1f(x)=1, \quad 0<x<1 gjeni E[etX]E\left[e^{t X}\right]. Kryeni llogaritjet për të gjetur E(Xn)E\left(X^{n}\right).

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Problem 2587

14(2x3)dx\int_{1}^{4}\left(2-\frac{x}{3}\right) d x using Diemann Sum

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Problem 2588

find the derivative of (x+c)ex(x+c) e^{x}

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Problem 2589

(1 point)
A table of values for f,g,ff, g, f^{\prime}, and gg^{\prime} is given below: \begin{tabular}{|c|c|c|c|c|} \hlinexx & f(x)f(x) & g(x)g(x) & f(x)f^{\prime}(x) & g(x)g^{\prime}(x) \\ \hline 1 & 3 & 2 & 4 & 6 \\ 2 & 1 & 8 & 5 & 7 \\ 3 & 7 & 2 & 7 & 9 \\ \hline \end{tabular} (a) If h(x)=f(g(x))h(x)=f(g(x)), find h(1)h^{\prime}(1). (b) If H(x)=g(f(x))H(x)=g(f(x)), find H(1)H^{\prime}(1). (a) h(1)=h^{\prime}(1)= \square (b) H(1)=H^{\prime}(1)= \square

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Problem 2590

f(x)=(x3+3x+8)3f(x)=\left(x^{3}+3 x+8\right)^{3} f(x)=f(1)=\begin{array}{l} f^{\prime}(x)= \\ f^{\prime}(1)= \end{array}

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Problem 2591

A box is to be made out of a 8 cm by 20 cm piece of cardboard. Squares of side length x cmx \mathrm{~cm} will be cut out of each corner, and then the ends and sides will be folded up to form a box with an open top. (a) Express the volume VV of the box as a function of xx. V=4x356x2+160x cm3V=4 x^{3}-56 x^{2}+160 x \mathrm{~cm}^{3} (b) Give the domain of VV in interval notation. (Use the fact that length and volume must be positive.) (0,4)(0,4) (c) Find the length LL, width WW, and height HH of the resulting box that maximizes the volume. (Assume that WLW \leq L ). L=cmW=cmH=cm\begin{array}{l} L=\square \mathrm{cm} \\ W=\square \mathrm{cm} \\ H=\square \mathrm{cm} \end{array} (d) The maximum volume of the box is cm3\square \mathrm{cm}^{3}.

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Problem 2592

Let f(x)=x+1xf(x)=x+\sqrt{1-x} Find the local maximum and minimum values of ff using both the first and second derivative tests. Which method do you prefer? (That last question can be treated as rhetorical)
Below, type none if there are none. Points with local maximum values \square Points with local minimum values \square
Note: You can earn partial credit on this problem. Preview My Answers Submit Answers

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Problem 2593

Compute the following limits using L'Hospital's rule if appropriate. Use INF to denote oo and MINF to denote limx177x21=limxtan1(x)(1/x)7=\begin{array}{l} \lim _{x \rightarrow 1} \frac{7^{\infty}-7}{x^{2}-1}=\square \\ \lim _{x \rightarrow \infty} \frac{\tan ^{-1}(x)}{(1 / x)-7}= \end{array} \square
Note: You can earn partial credit on this problem.

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Problem 2594

Consider the limit limx0sin2(8x)1cos(8x)\lim _{x \rightarrow 0} \frac{\sin ^{2}(8 x)}{1-\cos (8 x)}
To simplify this limit, we should multiply numerator and denominator by the expression \square After doing this and simplifying the result we find that the value of limit is \square
Note: You can earn partial credit on this problem. Preview My Answers Submit Answers

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Problem 2595

Path of the projectile vi=20 m/s\mathrm{v}_{i}=20 \mathrm{~m} / \mathrm{s}
A projectile is fired up an incline (incline angle ϕ\phi ) with an initial speed viv_{\mathrm{i}} at an angle θi\theta_{\mathrm{i}} with respect to the horizontal as shown in Figure. (Take g=10m/s2\mathrm{g}=\mathbf{1 0} \mathrm{m} / \mathrm{s}^{2}. Please mark the closest answer as correct answer) Find when the projectile's velocity has only xx component (a) t=1 s\mathrm{t}=1 \mathrm{~s} (b) t=3.9 st=3.9 \mathrm{~s} (c) t=6.3 s\mathrm{t}=6.3 \mathrm{~s} (d) t=8.6 st=8.6 \mathrm{~s} (e) t=4 st=4 \mathrm{~s}

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Problem 2596

Path of the projectile vi=20 m/s\mathrm{v}_{i}=20 \mathrm{~m} / \mathrm{s}
A projectile is fired up an incline (incline angle ϕ\phi ) with an initial speed viv_{i} at an angle θi\theta_{\mathrm{i}} with respect to the horizontal as shown in Figure. (Take g=10 m/s2\mathrm{g}=10 \mathrm{~m} / \mathrm{s}^{2}. Please mark the closest answer as correct answer) Find when the projectile's velocity has only xx component (a) t=1 s\mathrm{t}=1 \mathrm{~s} (b) t=3.9 st=3.9 \mathrm{~s} (c) t=6.3 s\mathrm{t}=6.3 \mathrm{~s} (d) t=8.6 st=8.6 \mathrm{~s} (e) t=4 st=4 \mathrm{~s}

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Problem 2597

NYA Module 7: Problem 11
For each of the following forms determine whether the following limit type is indeterminate, always has a fixed finite value, or never has a fixed finite value. In the first case answer IND, in the second enter the numerical value, and in the third case answer DNE. To discourage blind guessing, this problem is graded on the following scale 09 correct = 01013 correct =.31416 correct =.51719 correct =.7\begin{array}{l} 0-9 \text { correct = } 0 \\ 10-13 \text { correct }=.3 \\ 14-16 \text { correct }=.5 \\ 17-19 \text { correct }=.7 \end{array}
Note that l'Hospital's rule (in some form) may ONLY be applied to indeterminate forms.
1. \infty^{-\infty}
2. 0\infty^{-0}
3. \infty^{\infty}
4. 1\infty^{1}
5. π\pi^{\infty}
6. 11^{\infty} 7.107.1^{0}
8. 0\infty^{0}
9. π\pi^{-\infty} 10.10 . \infty \cdot \infty
11. 0\frac{0}{\infty}
12. 1\frac{1}{-\infty} 13.013.0 \cdot \infty
14. 0\frac{\infty}{0}
15. 11^{-\infty} 16.116.1 \cdot \infty
17. \infty-\infty 18.0018.0^{0} \square 19.019.0^{\infty} \square 20. 00^{-\infty}

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Problem 2598

 caushy y3xy+4x2y=0x>0\begin{array}{l}\text { caushy } \\ y^{\prime \prime}-\frac{3}{x} y^{\prime}+\frac{4}{x^{2}} y=0 \quad{ }^{\prime} \quad x^{\prime}>0\end{array}

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Problem 2599

0ex2dx\int_{0}^{\infty} e^{-x^{2}} d x

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Problem 2600

Q Q If y1=x^{y_{1}}=x is solution of (x2x)y+xy+y=0\left(x^{2}-x\right) y^{\prime \prime}+x y^{\prime}+y=0 find the General solution

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