Determine the sums of the following geometric series when they are convergent. 2 + 2/3 + 2/9 + 2/27 + 2/81 + …
> Based on the information contained within this chapter, what are the critical linkages between the logistics management system and other functions such as operations and supply management?
> Think about a recent online order that you made. Did it have all of the components of a “perfect order”? Why or why not? If there was a problem with the order, which logistics activities most likely contributed to the problem? Why?
> When evaluating a supplier’s financial stability, what are some key indicators to consider? Why?
> Why don’t companies seek full partnerships with all of their suppliers?
> Consider Marriott or Hilton corporations, which have hotels around the world. What type of purchases should be local, national/regional, or global? Why?
> For an organization that you are familiar with, provide an example of each of the four categories of purchases shown in Figure 10-4. What sourcing strategy would you use for each? Why? Figure 10-4:
> How would you do a spend analysis if you were the supply manager for a large state university? What are likely to be the most important spend categories (excluding dining services and residence life)?
> Many universities have outsourced operations of residence halls. Do you think this is a good idea? Why or why not?
> A metric consists of three elements: the measure, the standard (what is expected), and the reward. Why are all three elements critical? What happens to the effectiveness of a metric when one of these three elements is missing?
> Review Fortune magazine’s “Most Admired” American companies for 1959, 1979, 1999, and the most current year. (The issue normally appears in August each year.) Which companies have remained on the top throughout this period? Which ones have disappeared? W
> Let a and r be given nonzero numbers. (a) Show that (1 - r)(a + ar + ar2 + … + arn) = a - arn+1, and from this conclude that, for r 1, a + ar + ar2 + … + arn = a/(1 – r) - arn+1/(1 – r). (b) Use the result of part (a) to explain why the geometric serie
> Determine the sums of the following infinite series: ∑k=1 ∞ (1/3)2k
> Determine the sums of the following infinite series: ∑k=0 ∞ (-1)k 3k+1/5k
> Determine the sums of the following infinite series: ∑j=0 ∞ (-1)j/3j
> Determine the sums of the following infinite series: ∑j=1 ∞ 5-2j
> Determine the sums of the following infinite series: ∑k=0 ∞ (7/10)k
> Determine the sums of the following infinite series: ∑k=0 ∞ (5/6)k
> The infinite series a1 + a2 + a3 + … has partial sums given by Sn = n – 1/n. (a) Find ∑k=110 ak. (b) Does the infinite series converge? If so, to what value does it converge?
> The infinite series a1 + a2 + a3 + … has partial sums given by Sn = 3 – 5/n. (a) Find ∑k=1 10 ak. (b) Does the infinite series converge? If so, to what value does it converge?
> A patient receives M mg of a certain drug daily. Each day, the body eliminates a fraction q of the amount of the drug present in the system. After extended treatment, estimate the total amount of the drug that should be present immediately after a dose i
> Determine all Taylor polynomials for f (x) = x2 + 2x + 1 at x = 0.
> A patient receives M mg of a certain drug each day. Each day the body eliminates 25% of the amount of drug present in the system. Determine the value of the maintenance dose M such that after many days approximately 20 mg of the drug is present immediate
> A patient receives 2 mg of a certain drug each day. Each day the body eliminates 20% of the amount of drug present in the system. After extended treatment, estimate the total amount of the drug present immediately before a dose is given.
> A patient receives 6 mg of a certain drug daily. Each day the body eliminates 30% of the amount of the drug present in the system. After extended treatment, estimate the total amount of the drug that should be present immediately after a dose is given.
> The coefficient of restitution of a ball, a number between 0 and 1, specifies how much energy is conserved when the ball hits a rigid surface. A coefficient of .9, for instance, means a bouncing ball will rise to 90% of its previous height after each bou
> A generous corporation not only gives its CEO a $1,000,000 bonus, but gives her enough money to cover the taxes on the bonus, the taxes on the additional taxes, the taxes on the taxes on the additional taxes, and so on. If she is in the 39.6% tax bracket
> Consider a perpetuity that promises to pay P dollars at the end of each month. (The first payment will be received in 1 month.) If the interest rate per month is r, the present value of P dollars in k months is P(1 + r)-k. Find a simple formula for the c
> Consider a perpetuity that promises to pay $100 at the beginning of each month. If the interest rate is 12% compounded monthly, the present value of $100 in k months is 100(1.01)-k. (a) Express the capital value of the perpetuity as an infinite series. (
> Compute the effect of a $20-billion federal income tax cut when the population’s marginal propensity to consume is 98%. What is the “multiplier” in this case?
> Compute the total new spending created by a $10-billion federal income tax cut when the population’s marginal propensity to consume is 95%. Compare your result with that of Example 3, and note how a small change in the MPC makes a dramatic change in the
> Compute the value of .12121̅2̅1̅2̅ as a geometric series with a = .1212 and r = .0001. Compare your answer with the result of Example 2.
> Determine the nth Taylor polynomial for f (x) = ex at x = 0.
> Sum an appropriate infinite series to find the rational number whose decimal expansion is given. Show that .999̅ = 1.
> Sum an appropriate infinite series to find the rational number whose decimal expansion is given. 5.444̅
> Sum an appropriate infinite series to find the rational number whose decimal expansion is given. 4.011̅0̅1̅1̅ (= 4 + .011011)
> Sum an appropriate infinite series to find the rational number whose decimal expansion is given. .15151̅5̅
> Sum an appropriate infinite series to find the rational number whose decimal expansion is given. .222̅
> Sum an appropriate infinite series to find the rational number whose decimal expansion is given. .17317̅3̅
> Sum an appropriate infinite series to find the rational number whose decimal expansion is given. .27272̅7̅
> Determine the sums of the following geometric series when they are convergent. 53/3 – 55/34 + 57/37 - 59/310 + 511/313 - …
> Determine the sums of the following geometric series when they are convergent. 5 + 4 + 3.2 + 2.56 + 2.048 + …
> Determine the sums of the following geometric series when they are convergent. 32/25 + 34/28 + 36/211 + 38/214 + 310/217 + …
> Sketch the graphs of f (x) = sin x and its first three Taylor polynomials at x = 0.
> Determine the sums of the following geometric series when they are convergent. 2/54 - 24/55 + 27/56 - 210/57 + 213/58 - …
> Determine the sums of the following geometric series when they are convergent. 6 - 1.2 + .24 - .048 + .0096 - …
> Determine the sums of the following geometric series when they are convergent. 3 - 32/7 + 33/72 - 34/73 + 35/74 - …
> Determine the sums of the following geometric series when they are convergent. 1/32 - 1/33 + 1/34 - 1/35 + 1/36 - …
> Determine the sums of the following geometric series when they are convergent. 1/5 + 1/54 + 1/57 + 1/510 + 1/513 + …
> Determine the sums of the following geometric series when they are convergent. 3 + 6/5 + 12/25 + 24/125 + 48/625 + …
> Determine the sums of the following geometric series when they are convergent. 1 + 1/23 + 1/26 + 1/29 + 1/212 + …
> Determine the sums of the following geometric series when they are convergent. 1 – 1/32 + 1/34 – 1/36 + 1/38 - …
> Determine the sums of the following geometric series when they are convergent. 1 + ¾ + (3/4)2 + (3/4)3+ (3/4)4+ …
> Sketch the graphs of f (x) = 1/(1 – x) and its first three Taylor polynomials at x = 0.
> Use three repetitions of the Newton–Raphson algorithm to approximate the following: √7
> Use three repetitions of the Newton–Raphson algorithm to approximate the following: √5
> Graph the function f (x) = x2 /(1 + x2), [-2, 2] by [-.5, 1]. The function has 0 as a zero. By looking at the graph, guess at a value of x0 for which x1 will be exactly 0 when the Newton– Raphson algorithm is invoked. Then, test your guess by carrying ou
> Draw the graph of f (x) = x4 - 2x2, [-2, 2] by [-2, 2]. The function has zeros at x = -12, x = 0, and x = 12. By looking at the graph, guess which zero will be approached when you apply the Newton–Raphson algorithm to each of the following initial approx
> Apply the Newton–Raphson algorithm to the function f (x) = x3 - 5x with x0 = 1. After observing the behavior, graph the function along with the tangent lines at x = 1 and x = -1, and explain geometrically what is happening.
> The functions f (x) = x2 - 4 and g (x) = (x - 2)2 both have a zero at x = 2. Apply the Newton–Raphson algorithm to each function with x0 = 3, and determine the value of n for which xn appears on the screen as exactly 2. Graph the two functions and explai
> Apply the Newton–Raphson algorithm to the function whose graph is drawn in Fig. 10(b). Use x0 = 1. Figure 10:
> Apply the Newton–Raphson algorithm to the function f (x) = x1/3 whose graph is drawn in Fig. 10(a). Use x0 = 1. Figure 10:
> What happens when the first approximation, x0, is actually a zero of f (x)?
> What special occurrence takes place when the Newton–Raphson algorithm is applied to the linear function f (x) = mx + b with m ≠ 0?
> Determine the fourth Taylor polynomial of f (x) = ln(1 - x) at x = 0, and use it to estimate ln(.9).
> Figure 9 contains the graph of the function f (x) = x3 - 12x. The function has zeros at x = - √12, 0, and √12. Which zero of f (x) will be approximated by the Newton–Raphson method starting with x0 =
> Figure 8 contains the graph of the function f (x) = x2 - 2. The function has zeros at x = √2 and x = - √2. When the Newton–Raphson algorithm is applied to find a zero, what values of x0 lead to the ze
> Suppose that the graph of the function f (x) has slope -2 at the point (1, 2). If the Newton–Raphson algorithm is used to find a root of f (x) = 0 with the initial guess x0 = 1, what is x1?
> Suppose that the line y = 4x + 5 is tangent to the graph of the function f (x) at x = 3. If the Newton–Raphson algorithm is used to find a root of f (x) = 0 with the initial guess x0 = 3, what is x1?
> Redo Exercise 17 with x0 = 1. Exercise 17: A function f (x) has the graph given in Fig. 7. Let x1 and x2 be the estimates of a root of f (x) obtained by applying the Newton–Raphson algorithm using an initial approximation of x0 = 5. Dr
> A function f (x) has the graph given in Fig. 7. Let x1 and x2 be the estimates of a root of f (x) obtained by applying the Newton–Raphson algorithm using an initial approximation of x0 = 5. Draw the appropriate tangent lines and estimat
> A mortgage of $100,050 is repaid in 240 monthly payments of $900. Determine the monthly rate of interest.
> A $663 flat-screen TV is purchased with a down payment of $100 and a loan of $563 to be repaid in five monthly installments of $116. Determine the monthly rate of interest on the loan.
> An investor buys a bond for $1000. She receives $10 at the end of each month for 2 months and then sells the bond at the end of the second month for $1040. Determine the internal rate of return on this investment.
> Suppose that an investment of $500 yields returns of $100, $200, and $300 at the end of the first, second, and third months, respectively. Determine the internal rate of return on this investment.
> Determine the fourth Taylor polynomial of f (x) = ex at x = 0, and use it to estimate e0.01.
> Use the Newton–Raphson algorithm to find an approximate solution to e5-x = 10 - x.
> Use the Newton–Raphson algorithm to find an approximate solution to e-x = x2.
> Sketch the graph of y = x3 + x - 1, and use the Newton–Raphson algorithm (three repetitions) to approximate all x-intercepts.
> Sketch the graph of y = x3 + 2x + 2, and use the Newton–Raphson algorithm (three repetitions) to approximate all x-intercepts.
> Use three repetitions of the Newton–Raphson algorithm to approximate the following: The zero of ex + 10x - 3 near x0 = 0
> Use three repetitions of the Newton–Raphson algorithm to approximate the following: The zero of sin x + x2 - 1 near x0 = 0
> Use three repetitions of the Newton–Raphson algorithm to approximate the following: The zero of x2 + 3x - 11 between -5 and -6
> Use three repetitions of the Newton–Raphson algorithm to approximate the following: The zero of x2 - x - 5 between 2 and 3
> Use three repetitions of the Newton–Raphson algorithm to approximate the following: 3√11
> Use three repetitions of the Newton–Raphson algorithm to approximate the following: 3√6
> Determine the third Taylor polynomial of the given function at x = 0. f (x) = √(1 – x)
> Graph the function Y1 = cos x and its second Taylor polynomial in the window ZDecimal. Find an interval of the form [- b, b] over which the Taylor polynomial is a good fit to the function. What is the greatest difference between the two functions on this
> Graph the function Y1 = ex and its fourth Taylor polynomial in the window [0, 3] by [-2, 20]. Find a number b such that graphs of the two functions appear identical on the screen for x between 0 and b. Calculate the difference between the function and it
> Repeat Exercise 31 for the function Y1 = 1/(1 – x) and its seventh Taylor polynomial. Exercise 31: Graph the function Y1 = 1/(1 – x) and its fourth Taylor polynomial in the window [-1, 1] by [-1, 5]. Find a number b such that graphs of the two functions
> Graph the function Y1 = 1/(1 – x) and its fourth Taylor polynomial in the window [-1, 1] by [-1, 5]. Find a number b such that graphs of the two functions appear identical on the screen for x between 0 and b. Calculate the difference between the function
> Let p2 (x) be the second Taylor polynomial of f (x) = ln x at x = 1, as in Exercise 22. (a) Show that | f (3)(c) | < 4 if c ≥ .8. (b) Show that the error in using p2(.8) as an approximation for ln .8 is at most 16/3 * 10-3 < .0054. Exercise 22: Use the
> Determine the third Taylor polynomial of the given function at x = 0. f (x) = √(4x + 1)
> Determine the third Taylor polynomial of the given function at x = 0. f (x) = cos(π - 5x)
> Determine the third Taylor polynomial of the given function at x = 0. f (x) = 5e2x
> Determine the third Taylor polynomial of the given function at x = 0. f (x) = e-x/2
> Determine the third Taylor polynomial of the given function at x = 0. f (x) = sin x
> Find the fifth Taylor polynomial of x3 - 7x2 + 8 at x = 0.
> Find the fourth Taylor polynomial of (2x + 1)3/2 at x = 0.
> Find the second Taylor polynomial of x(x + 1)3/2 at x = 0.
> Suppose that, when you die, the proceeds of a life insurance policy will be deposited into a trust fund that will earn 8% interest, compounded continuously. According to the terms of your will, the trust fund must pay to your descendants and their heirs
