Presentation is loading. Please wait.

Presentation is loading. Please wait.

14-1 Chapter 14 Risk and Managerial Options in Capital Budgeting © 2001 Prentice-Hall, Inc. Fundamentals of Financial Management, 11/e Created by: Gregory.

Published byRobert Evans Modified over 8 years ago

Similar presentations

Presentation on theme: "14-1 Chapter 14 Risk and Managerial Options in Capital Budgeting © 2001 Prentice-Hall, Inc. Fundamentals of Financial Management, 11/e Created by: Gregory."— Presentation transcript:

1 14-1 Chapter 14 Risk and Managerial Options in Capital Budgeting © 2001 Prentice-Hall, Inc. Fundamentals of Financial Management, 11/e Created by: Gregory A. Kuhlemeyer, Ph.D. Carroll College, Waukesha, WI

2 14-2 Risk and Managerial Options in Capital Budgeting u The Problem of Project Risk u Total Project Risk u Contribution to Total Firm Risk: Firm-Portfolio Approach u Managerial Options u The Problem of Project Risk u Total Project Risk u Contribution to Total Firm Risk: Firm-Portfolio Approach u Managerial Options

3 14-3 An Illustration of Total Risk (Discrete Distribution) ANNUAL CASH FLOWS: YEAR 1 PROPOSAL A ProbabilityCash Flow State Probability Cash Flow Deep Recession.05 $ -3,000 Mild Recession.25 1,000 Normal.40 5,000 Minor Boom.25 9,000 Major Boom.05 13,000 ANNUAL CASH FLOWS: YEAR 1 PROPOSAL A ProbabilityCash Flow State Probability Cash Flow Deep Recession.05 $ -3,000 Mild Recession.25 1,000 Normal.40 5,000 Minor Boom.25 9,000 Major Boom.05 13,000

4 14-4 Probability Distribution of Year 1 Cash Flows.40.05.25 Probability -3,000 1,000 5,000 9,000 13,000 Cash Flow ($) Proposal A

5 14-5 CF 1 P 1 CF 1 )(P 1 ) CF 1 P 1 (CF 1 )(P 1 ) $ -3,000.05 $ -150 1,000.25 250 5,000.40 2,000 9,000.25 2,250 13,000.05 650  1.00 CF 1 $5,000  =1.00 CF 1 =$5,000 CF 1 P 1 CF 1 )(P 1 ) CF 1 P 1 (CF 1 )(P 1 ) $ -3,000.05 $ -150 1,000.25 250 5,000.40 2,000 9,000.25 2,250 13,000.05 650  1.00 CF 1 $5,000  =1.00 CF 1 =$5,000 Expected Value of Year 1 Cash Flows (Proposal A)

6 14-6 CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 (P 1 ) (CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 (P 1 ) 2 (.05) $ -150 ( -3,000 - 5,000) 2 (.05) 2 (.25) 250 ( 1,000 - 5,000) 2 (.25) 2 (.40) 2,000 ( 5,000 - 5,000) 2 (.40) 2 (.25) 2,250 ( 9,000 - 5,000) 2 (.25) 2 (.05) 650 (13,000 - 5,000) 2 (.05) $5,000 CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 (P 1 ) (CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 (P 1 ) 2 (.05) $ -150 ( -3,000 - 5,000) 2 (.05) 2 (.25) 250 ( 1,000 - 5,000) 2 (.25) 2 (.40) 2,000 ( 5,000 - 5,000) 2 (.40) 2 (.25) 2,250 ( 9,000 - 5,000) 2 (.25) 2 (.05) 650 (13,000 - 5,000) 2 (.05) $5,000 Variance of Year 1 Cash Flows (Proposal A)

7 14-7 Variance of Year 1 Cash Flows (Proposal A) CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 *(P 1 ) (CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 *(P 1 ) $ -150 3,200,000 250 4,000,000 2,000 0 2,250 4,000,000 650 3,200,000 $5,000 14,400,000 CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 *(P 1 ) (CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 *(P 1 ) $ -150 3,200,000 250 4,000,000 2,000 0 2,250 4,000,000 650 3,200,000 $5,000 14,400,000

8 14-8 Summary of Proposal A standard deviation $3,795 The standard deviation = SQRT (14,400,000) = $3,795 expected cash flow $5,000 The expected cash flow = $5,000

9 14-9 An Illustration of Total Risk (Discrete Distribution) ANNUAL CASH FLOWS: YEAR 1 PROPOSAL B ProbabilityCash Flow State Probability Cash Flow Deep Recession.05 $ -1,000 Mild Recession.25 2,000 Normal.40 5,000 Minor Boom.25 8,000 Major Boom.05 11,000 ANNUAL CASH FLOWS: YEAR 1 PROPOSAL B ProbabilityCash Flow State Probability Cash Flow Deep Recession.05 $ -1,000 Mild Recession.25 2,000 Normal.40 5,000 Minor Boom.25 8,000 Major Boom.05 11,000

10 14-10 Probability Distribution of Year 1 Cash Flows.40.05.25 Probability -3,000 1,000 5,000 9,000 13,000 Cash Flow ($) Proposal B

11 14-11 Expected Value of Year 1 Cash Flows (Proposal B) CF 1 P 1 CF 1 )(P 1 ) CF 1 P 1 (CF 1 )(P 1 ) $ -1,000.05 $ -50 2,000.25 500 5,000.40 2,000 8,000.25 2,000 11,000.05 550  1.00 CF 1 $5,000  =1.00 CF 1 =$5,000 CF 1 P 1 CF 1 )(P 1 ) CF 1 P 1 (CF 1 )(P 1 ) $ -1,000.05 $ -50 2,000.25 500 5,000.40 2,000 8,000.25 2,000 11,000.05 550  1.00 CF 1 $5,000  =1.00 CF 1 =$5,000

12 14-12 CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 (P 1 ) (CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 (P 1 ) 2 (.05) $ -50 ( -1,000 - 5,000) 2 (.05) 2 (.25) 500 ( 2,000 - 5,000) 2 (.25) 2 (.40) 2,000 ( 5,000 - 5,000) 2 (.40) 2 (.25) 2,000 ( 8,000 - 5,000) 2 (.25) 2 (.05) 550 (11,000 - 5,000) 2 (.05) $5,000 CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 (P 1 ) (CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 (P 1 ) 2 (.05) $ -50 ( -1,000 - 5,000) 2 (.05) 2 (.25) 500 ( 2,000 - 5,000) 2 (.25) 2 (.40) 2,000 ( 5,000 - 5,000) 2 (.40) 2 (.25) 2,000 ( 8,000 - 5,000) 2 (.25) 2 (.05) 550 (11,000 - 5,000) 2 (.05) $5,000 Variance of Year 1 Cash Flows (Proposal B)

13 14-13 Variance of Year 1 Cash Flows (Proposal B) CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 (P 1 ) (CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 (P 1 ) $ -50 1,800,000 500 2,250,000 2,000 0 2,000 2,250,000 550 1,800,000 $5,000 8,100,000 CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 (P 1 ) (CF 1 )(P 1 ) (CF 1 - CF 1 ) 2 (P 1 ) $ -50 1,800,000 500 2,250,000 2,000 0 2,000 2,250,000 550 1,800,000 $5,000 8,100,000

14 14-14 Summary of Proposal B Proposal B < Proposal A. ( $2,846 < $3,795 ) The standard deviation of Proposal B < Proposal A. ( $2,846 < $3,795 ) standard deviation $2,846 The standard deviation = SQRT (8,100,000)= $2,846 expected cash flow $5,000 The expected cash flow = $5,000

15 14-15 Total Project Risk Projects have risk that may change from period to period. Projects are more likely to have continuous, rather than discrete distributions. Cash Flow ($) 123 1 2 3 Year

16 14-16 Probability Tree Approach A graphic or tabular approach for organizing the possible cash-flow streams generated by an investment. The presentation resembles the branches of a tree. Each complete branch represents one possible cash-flow sequence.

17 14-17 Probability Tree Approach initial cost $900 Year 1 Basket Wonders is examining a project that will have an initial cost today of $900. Uncertainty surrounding the first year cash flows creates three possible cash-flow scenarios in Year 1. -$900

18 14-18 Probability Tree Approach $1,200 Node 1: 20% chance of a $1,200 cash-flow. $450 Node 2: 60% chance of a $450 cash-flow. -$600 Node 3: 20% chance of a -$600 cash-flow. -$900 $1,200 (.20) $1,200 -$600 (.20) -$600 $450 (.60) $450 Year 1 1 2 3

19 14-19 Probability Tree Approach Year 2 branch Each node in Year 2 represents a branch of our probability tree. conditional probabilities The probabilities are said to be conditional probabilities. -$900.20$1,200 (.20) $1,200.20-$600 (.20) -$600 60$450 (.60) $450 Year 1 1 2 3 $1,200 (.60) $1,200 $ 900 (.30) $ 900 $2,200 (.10) $2,200 $ 900 (.35) $ 900 $ 600 (.40) $ 600 $ 300 (.25) $ 300 $ 500 (.10) $ 500 -$ 100 (.50) -$ 100 -$ 700 (.40) -$ 700 Year 2

20 14-20 Joint Probabilities [P(1,2)].02 Branch 1.12 Branch 2.06 Branch 3.21 Branch 4.24 Branch 5.15 Branch 6.02 Branch 7.10 Branch 8.08 Branch 9 -$900.20$1,200 (.20) $1,200.20-$600 (.20) -$600 60$450 (.60) $450 Year 1 1 2 3 $1,200 (.60) $1,200 $ 900 (.30) $ 900 $2,200 (.10) $2,200 $ 900 (.35) $ 900 $ 600 (.40) $ 600 $ 300 (.25) $ 300 $ 500 (.10) $ 500 -$ 100 (.50) -$ 100 -$ 700 (.40) -$ 700 Year 2

21 14-21 Project NPV Based on Probability Tree Usage risk-free The probability tree accounts for the distribution of cash flows. Therefore, discount all cash flows at only the risk-free rate of return. NPV for branch i The NPV for branch i of the probability tree for two years of cash flows is NPV i P i NPV =  (NPV i )(P i ) NPV i NPV i = CF 1 R f 1 (1 + R f ) 1 R f 2 (1 + R f ) 2 CF 2 ICO - ICO + i = 1 z

22 14-22 NPV for Each Cash-Flow Stream at 5% Risk-Free Rate $ 2,238.32 $ 1,331.29 $ 1,059.18 $ 344.90 $ 72.79 -$ 199.32 -$ 1,017.91 -$ 1,562.13 -$ 2,106.35 -$900.20$1,200 (.20) $1,200.20-$600 (.20) -$600 60$450 (.60) $450 Year 1 1 2 3 $1,200 (.60) $1,200 $ 900 (.30) $ 900 $2,200 (.10) $2,200 $ 900 (.35) $ 900 $ 600 (.40) $ 600 $ 300 (.25) $ 300 $ 500 (.10) $ 500 -$ 100 (.50) -$ 100 -$ 700 (.40) -$ 700 Year 2

23 14-23 NPV on the Calculator Remember, we can use the cash flow registry to solve these NPV problems quickly and accurately!

24 14-24 Actual NPV Solution Using Your Financial Calculator Solving for Branch #3: Step 1:PressCF key Step 2:Press2 nd CLR Workkeys Step 3: For CF0 Press -900 Enter  keys Step 4: For C01 Press 1200 Enter  keys Step 5: For F01 Press 1 Enter  keys Step 6: For C02 Press 900 Enter  keys Step 7: For F02 Press 1 Enter  keys

25 14-25 Actual NPV Solution Using Your Financial Calculator Solving for Branch #3: Step 8: Press   keys Step 9: PressNPV key Step 10: For I=, Enter 5Enter  keys Step 11: PressCPT key Result:Net Present Value = $1,059.18 You would complete this for EACH branch!

26 14-26 Calculating the Expected Net Present Value (NPV) NPV i Branch NPV i Branch 1 $ 2,238.32 Branch 2 $ 1,331.29 Branch 3 $ 1,059.18 Branch 4 $ 344.90 Branch 5 $ 72.79 Branch 6 -$ 199.32 Branch 7 -$ 1,017.91 Branch 8-$ 1,562.13 Branch 9 -$ 2,106.35 P(1,2) NPV i P(1,2) P(1,2) NPV i * P(1,2).02 $ 44.77.12 $159.75.06 $ 63.55.21 $ 72.43.24 $ 17.47.15 -$ 29.90.02 -$ 20.36.10 -$156.21.08 -$168.51 Expected Net Present Value -$ 17.01 Expected Net Present Value = -$ 17.01

27 14-27 Calculating the Variance of the Net Present Value NPV i NPV i $ 2,238.32 $ 1,331.29 $ 1,059.18 $ 344.90 $ 72.79 -$ 199.32 -$ 1,017.91 -$ 1,562.13 -$ 2,106.35 P(1,2) (NPV i NPVP(1,2) P(1,2) (NPV i - NPV ) 2 [P(1,2)].02 $ 101,730.27.12 $ 218,149.55.06 $ 69,491.09.21 $ 27,505.56.24 $ 1,935.37.15 $ 4,985.54.02 $ 20,036.02.10 $ 238,739.58.08 $ 349,227.33 Variance $1,031,800.31 Variance = $1,031,800.31

28 14-28 Summary of the Decision Tree Analysis standard deviation $1,015.78 The standard deviation = SQRT ($1,031,800) = $1,015.78 expected NPV -$ 17.01 The expected NPV = -$ 17.01

29 14-29 Simulation Approach An approach that allows us to test the possible results of an investment proposal before it is accepted. Testing is based on a model coupled with probabilistic information.

30 14-30 Simulation Approach Market analysis u Market analysis u Market size, selling price, market growth rate, and market share Investment cost analysis u Investment cost analysis u Investment required, useful life of facilities, and residual value Operating and fixed costs u Operating and fixed costs u Operating costs and fixed costs Factors we might consider in a model:

31 14-31 Simulation Approach Each variable is assigned an appropriate probability distribution. The distribution for the selling price of baskets created by Basket Wonders might look like: $20 $25 $30 $35 $40 $45 $50.02.08.22.36.22.08.02 The resulting proposal value is dependent on the distribution and interaction of EVERY variable listed on slide 14-30.

32 14-32 Simulation Approach internal rate of return distribution Each proposal will generate an internal rate of return. The process of generating many, many simulations results in a large set of internal rates of return. The distribution might look like the following: INTERNAL RATE OF RETURN (%) PROBABILITY OF OCCURRENCE

33 14-33 diversification Combining projects in this manner reduces the firm risk due to diversification. Contribution to Total Firm Risk: Firm-Portfolio Approach CASH FLOW TIME Proposal A Proposal B Combination of Proposals A and B

34 14-34 NPV P =  ( NPV j ) NPV P is the expected portfolio NPV, NPV j is the expected NPV of the jth NPV that the firm undertakes, m is the total number of projects in the firm portfolio. NPV P =  ( NPV j ) NPV P is the expected portfolio NPV, NPV j is the expected NPV of the jth NPV that the firm undertakes, m is the total number of projects in the firm portfolio. Determining the Expected NPV for a Portfolio of Projects m j=1

35 14-35  P  P =   jk  jk is the covariance between possible NPVs for projects j and k   r  jk =  j  k r  jk.  j is the standard deviation of project j,  k is the standard deviation of project k, r jk is the correlation coefficient between projects j and k.  P  P =   jk  jk is the covariance between possible NPVs for projects j and k   r  jk =  j  k r  jk.  j is the standard deviation of project j,  k is the standard deviation of project k, r jk is the correlation coefficient between projects j and k. Determining Portfolio Standard Deviation m j=1 m k=1

36 14-36 E: Existing Projects 8 Combinations EEE EE EE EE + 1 E + 1 + 2 E + 2 E + 1 + 3 E + 3 E + 2 + 3 E E + 1 + 2 + 3 ABC dominating A, B, and C are dominating combinations from the eight possible. Combinations of Risky Investments A B C E Standard Deviation Expected Value of NPV

37 14-37 Managerial (Real) Options Management flexibility to make future decisions that affect a project’s expected cash flows, life, or future acceptance. Project Worth = NPV + Option(s) Value

38 14-38 Managerial (Real) Options Expand (or contract) u Allows the firm to expand (contract) production if conditions become favorable (unfavorable).Abandon u Allows the project to be terminated early.Postpone u Allows the firm to delay undertaking a project (reduces uncertainty via new information).

39 14-39 Previous Example with Project Abandonment $200 Assume that this project can be abandoned at the end of the first year for $200. project worth What is the project worth? -$900.20$1,200 (.20) $1,200.20-$600 (.20) -$600 60$450 (.60) $450 Year 1 1 2 3 $1,200 (.60) $1,200 $ 900 (.30) $ 900 $2,200 (.10) $2,200 $ 900 (.35) $ 900 $ 600 (.40) $ 600 $ 300 (.25) $ 300 $ 500 (.10) $ 500 -$ 100 (.50) -$ 100 -$ 700 (.40) -$ 700 Year 2

40 14-40 Project Abandonment Node 3 Node 3: 500 -100 -700 (500/1.05)(.1)+ (-100/1.05)(.5)+ (-700/1.05)(.4)= ($476.19)(.1)+ -($ 95.24)(.5)+ -($666.67)(.4)=-($266.67) -$900.20$1,200 (.20) $1,200.20-$600 (.20) -$600 60$450 (.60) $450 Year 1 1 2 3 $1,200 (.60) $1,200 $ 900 (.30) $ 900 $2,200 (.10) $2,200 $ 900 (.35) $ 900 $ 600 (.40) $ 600 $ 300 (.25) $ 300 $ 500 (.10) $ 500 -$ 100 (.50) -$ 100 -$ 700 (.40) -$ 700 Year 2

41 14-41 Project Abandonment -$900.20$1,200 (.20) $1,200.20-$600 (.20) -$600 60$450 (.60) $450 Year 1 1 2 3 $1,200 (.60) $1,200 $ 900 (.30) $ 900 $2,200 (.10) $2,200 $ 900 (.35) $ 900 $ 600 (.40) $ 600 $ 300 (.25) $ 300 $ 500 (.10) $ 500 -$ 100 (.50) -$ 100 -$ 700 (.40) -$ 700 Year 2 Year 1 $200 The optimal decision at the end of Year 1 is to abandon the project for $200. $200 $200 >-($266.67) “new” What is the “new” project value?

42 14-42 Project Abandonment $ 2,238.32 $ 1,331.29 $ 1,059.18 $ 344.90 $ 72.79 -$ 199.32 -$ 1,280.95 -$900.20$1,200 (.20) $1,200.20-$400* (.20) -$400* 60$450 (.60) $450 Year 1 1 2 3 $1,200 (.60) $1,200 $ 900 (.30) $ 900 $2,200 (.10) $2,200 $ 900 (.35) $ 900 $ 600 (.40) $ 600 $ 300 (.25) $ 300 $ 0 (1.0) $ 0 Year 2 *-$600 + $200 abandonment

43 14-43 Summary of the Addition of the Abandonment Option * For “True” Project considering abandonment option standard deviation* $857.56 The standard deviation*= SQRT (740,326) = $857.56 expected NPV* $ 71.88 The expected NPV* = $ 71.88 NPV* Abandonment Option NPV* = Original NPV + Abandonment Option Thus, $71.88 Option Thus, $71.88 = -$17.01 + Option Abandonment Option $ 88.89 Abandonment Option = $ 88.89

Download ppt "14-1 Chapter 14 Risk and Managerial Options in Capital Budgeting © 2001 Prentice-Hall, Inc. Fundamentals of Financial Management, 11/e Created by: Gregory."

Similar presentations

14-1 Chapter 14 Risk and Managerial (Real) Options in Capital Budgeting © Pearson Education Limited 2004 Fundamentals of Financial Management, 12/e Created.

14-1 Chapter 14 Risk and Managerial (Real) Options in Capital Budgeting © Pearson Education Limited 2004 Fundamentals of Financial Management, 12/e Created.
13.1 Van Horne and Wachowicz, Fundamentals of Financial Management, 13th edition. © Pearson Education Limited 2009. Created by Gregory Kuhlemeyer. Chapter.

13.1 Van Horne and Wachowicz, Fundamentals of Financial Management, 13th edition. © Pearson Education Limited Created by Gregory Kuhlemeyer. Chapter.
CHAPTER 14 Real Options.

CHAPTER 14 Real Options.
Lecture 8 - Capital Budgeting: Estimating Cash Flows and Analyzing Risk.

Lecture 8 - Capital Budgeting: Estimating Cash Flows and Analyzing Risk.
Chapter 8: Strategy and Analysis Using NPV

Chapter 8: Strategy and Analysis Using NPV
Real Options The Right to do Something Real. Introduction The classical DCF valuation method involves a comparison between the cost of an investment project.

Real Options The Right to do Something Real. Introduction The classical DCF valuation method involves a comparison between the cost of an investment project.
CHAPTER 13 Other Topics in Capital Budgeting Evaluating projects with unequal lives Identifying embedded options Valuing real options in projects.

CHAPTER 13 Other Topics in Capital Budgeting Evaluating projects with unequal lives Identifying embedded options Valuing real options in projects.
®2002 Prentice Hall Publishing 1 Chapter 7 Risk and Real Options in Capital Budgeting.

®2002 Prentice Hall Publishing 1 Chapter 7 Risk and Real Options in Capital Budgeting.
Chapter 12 Risk Topics and Real Options in Capital Budgeting and Cash Flow Estimation.

Chapter 12 Risk Topics and Real Options in Capital Budgeting and Cash Flow Estimation.
13 - 1 Copyright © 2001 by Harcourt, Inc.All rights reserved. CHAPTER 13 Other Topics in Capital Budgeting Evaluating projects with unequal lives Evaluating.

Copyright © 2001 by Harcourt, Inc.All rights reserved. CHAPTER 13 Other Topics in Capital Budgeting Evaluating projects with unequal lives Evaluating.
13b.1 Van Horne and Wachowicz, Fundamentals of Financial Management, 13th edition. © Pearson Education Limited 2009. Created by Gregory Kuhlemeyer. Chapter.

13b.1 Van Horne and Wachowicz, Fundamentals of Financial Management, 13th edition. © Pearson Education Limited Created by Gregory Kuhlemeyer. Chapter.
Incremental Cash Flows

Incremental Cash Flows
Real Options and Other Topics in Capital Budgeting

Real Options and Other Topics in Capital Budgeting
10- 1 McGraw Hill/Irwin Copyright © 2009 by The McGraw-Hill Companies, Inc. All rights reserved Fundamentals of Corporate Finance Sixth Edition Richard.

10- 1 McGraw Hill/Irwin Copyright © 2009 by The McGraw-Hill Companies, Inc. All rights reserved Fundamentals of Corporate Finance Sixth Edition Richard.
4. Project Investment Decision-Making

4. Project Investment Decision-Making
13-1 Chapter 13 Capital Budgeting Techniques © 2001 Prentice-Hall, Inc. Fundamentals of Financial Management, 11/e Created by: Gregory A. Kuhlemeyer, Ph.D.

13-1 Chapter 13 Capital Budgeting Techniques © 2001 Prentice-Hall, Inc. Fundamentals of Financial Management, 11/e Created by: Gregory A. Kuhlemeyer, Ph.D.
Chapter 11 Cash Flow Estimation & Risk Analysis. 2 Topics Estimating cash flows: Relevant cash flows Working capital treatment Risk analysis: Sensitivity.

Chapter 11 Cash Flow Estimation & Risk Analysis. 2 Topics Estimating cash flows: Relevant cash flows Working capital treatment Risk analysis: Sensitivity.
Engineering Economic Analysis Canadian Edition

Engineering Economic Analysis Canadian Edition
Hanoi April 20001 Capital budgeting decisions with the Net Present Value rule 2. Cost of capital Professor André Farber Solvay Business School University.

Hanoi April Capital budgeting decisions with the Net Present Value rule 2. Cost of capital Professor André Farber Solvay Business School University.
Financial Analysis, Planning and Forecasting Theory and Application By Alice C. Lee San Francisco State University John C. Lee J.P. Morgan Chase Cheng.

Financial Analysis, Planning and Forecasting Theory and Application By Alice C. Lee San Francisco State University John C. Lee J.P. Morgan Chase Cheng.

Similar presentations

Ads by Google