Time Value of Money: Present and Future Value
Time Value of Money: Present and Future Value
Present Value (PV): Definition and Calculation
Definition
The concept of Present Value (PV) is fundamental to finance and investment. It represents the current worth of a sum of money that is to be received or paid in the future, or the current worth of a series of future cash flows. In simpler terms, it answers the question: "Given a specific rate of return, how much money must I invest today to have a certain amount at a future date?" or conversely, "What is the value today of an amount I expect to receive at some point in the future?".
The foundation of Present Value is the principle of the Time Value of Money (TVM). This principle asserts that a sum of money available today is worth more than the identical sum received at a future date. This is because money possessed today can be invested or utilized to earn interest or generate returns, thereby increasing its value over time. Consequently, money received in the future is worth less than the same amount received today. To find its equivalent value in the present, future money is 'discounted' back to the present using an appropriate rate of return, also known as the discount rate.
The process of calculating the present value is known as discounting. The rate used in this calculation is typically the required rate of return, cost of capital, or an interest rate that could be earned on an alternative investment of similar risk.
Calculation Formula and Derivation
The formula for calculating Present Value is derived directly from the formula for Future Value under compound interest. Recall the compound interest formula for the accumulated amount (which is the Future Value) after $n$ periods with a periodic interest rate $i$:
$FV = PV(1 + i)^n$
Where:
- $FV$ = Future Value (the amount at the future point in time).
- $PV$ = Present Value (the equivalent value today).
- $i$ = Periodic interest rate or discount rate per compounding/discounting period (expressed as a decimal). If the annual rate is $r$ and compounding/discounting is $m$ times per year, then $i = r/m$.
- $n$ = Total number of compounding/discounting periods. If the time is $t$ years and compounding/discounting is $m$ times per year, then $n = m \times t$.
Our goal is to find the formula for $PV$. We can rearrange the Future Value formula to solve for $PV$ by dividing both sides by $(1 + i)^n$:
$\frac{FV}{(1 + i)^n} = \frac{PV(1 + i)^n}{(1 + i)^n}$
This simplifies to the formula for Present Value:
$\mathbf{PV = \frac{FV}{(1 + i)^n}}$
Using properties of exponents, we can also write this formula using a negative exponent:
$\mathbf{PV = FV(1 + i)^{-n}}$
The term $\frac{1}{(1+i)^n}$ or $(1+i)^{-n}$ is crucial in PV calculations. It is called the discount factor or present value factor. It represents the present value of $\textsf{₹}\$ 1$ (or any unit currency) to be received after $n$ periods, discounted at a rate of $i$ per period. Multiplying a future value by this discount factor gives its present value.
Key Factors Affecting Present Value
Based on the formula $PV = FV(1 + i)^{-n}$, we can see how changes in the other variables affect the Present Value:
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Future Value (FV): A higher future value naturally results in a higher present value, assuming the discount rate and time period remain constant. The relationship is directly proportional.
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Discount Rate (i): This is inversely related to the Present Value. A higher discount rate means money today has a higher earning potential, so a future sum is worth *less* today. The higher the $i$, the smaller the discount factor $(1+i)^{-n}$, and thus the lower the $PV$.
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Number of Periods (n): The longer the time until the future value is received (the larger the $n$), the *lower* its present value. This is because the discounting effect is applied over more periods. The larger the $n$, the smaller the discount factor $(1+i)^{-n}$, and thus the lower the $PV$.
Worked Examples
Example 1. What is the present value of $\textsf{₹}\$ 15,000$ to be received 4 years from now, if the discount rate is 9% per annum compounded annually?
Answer:
Given:
- Future Value (FV) = $\textsf{₹}\$ 15,000$
- Time (t) = 4 years
- Annual Discount Rate (R) = 9%. Since compounded annually, the periodic rate $i = R/100 = 0.09$.
- Compounding: Annually, $m=1$. Total periods $n = m \times t = 1 \times 4 = 4$.
To Find:
- Present Value (PV).
Formula:
$PV = \frac{FV}{(1 + i)^n}$
Solution:
Substitute the given values into the formula:
$PV = \frac{15000}{(1 + 0.09)^4}$
$PV = \frac{15000}{(1.09)^4}$
Calculate $(1.09)^4$. Using a calculator:
$(1.09)^2 = 1.1881$
$(1.09)^4 = (1.09^2)^2 = (1.1881)^2 \approx 1.411581$
So,
$PV = \frac{15000}{1.411581}$
Performing the division:
$PV \approx 10626.37$
Rounding to two decimal places, the present value is approximately $\textsf{₹}\$ 10,626.37$. This means that $\textsf{₹}\$ 10,626.37$ invested today at an annual compound interest rate of 9% would grow to approximately $\textsf{₹}\$ 15,000$ in 4 years.
Example 2. Find the present value of $\textsf{₹}\$ 5,000$ due in 3 years if the interest rate is 8% p.a. compounded quarterly.
Answer:
Given:
- Future Value (FV) = $\textsf{₹}\$ 5,000$
- Time (t) = 3 years
- Nominal annual rate (R) = 8%. Convert to decimal: $r = \frac{8}{100} = 0.08$.
- Compounding frequency: Quarterly, so $m=4$.
To Find:
- Present Value (PV).
Calculate Periodic Discount Rate (i) and Total Number of Periods (n):
Periodic rate $i = \frac{r}{m} = \frac{0.08}{4} = 0.02$. (This is the discount rate per quarter).
Total number of periods $n = m \times t = 4 \times 3 = 12$. (There are 12 quarters in 3 years).
Formula:
$PV = \frac{FV}{(1 + i)^n}$
Solution:
Substitute the calculated values of FV, i, and n into the formula:
$PV = \frac{5000}{(1 + 0.02)^{12}} = \frac{5000}{(1.02)^{12}}$
Calculate $(1.02)^{12}$. Using a calculator (or financial tables):
$(1.02)^{12} \approx 1.26824179
So,
$PV = \frac{5000}{1.26824179}$
Performing the division:
$PV \approx 3942.57$
Rounding to two decimal places, the present value is approximately $\textsf{₹}\$ 3,942.57$.
Summary for Competitive Exams
Present Value (PV): The current worth of a future sum of money. Reflects Time Value of Money (TVM).
Concept: Discounting future cash flows back to the present using a discount rate.
Formula: $\mathbf{PV = \frac{FV}{(1 + i)^n} = FV(1 + i)^{-n}}$
- PV: Present Value
- FV: Future Value
- i: Periodic discount rate (decimal, $r/m$)
- n: Total number of periods ($mt$)
Discount Factor: $(1 + i)^{-n}$. Represents the value today of 1 unit of currency received in $n$ periods.
Factors: PV increases with FV, decreases with higher $i$, and decreases with longer $n$.
Time Value of Money: Future Value (FV): Definition and Calculation
Definition
The Future Value (FV) is the value of an investment or a sum of money at a specified point in time in the future, assuming a certain rate of return or growth (interest rate). It addresses the question: "If I invest a certain amount of money today at a given interest rate, how much will it be worth after a specific number of periods?" or "What will be the value of my current savings after some years?"
Future Value calculations are used to project the growth of money due to the application of interest, particularly compound interest. This process of calculating the future value is also known as accumulation, as it shows how the initial principal accumulates interest over time.
The concept of Future Value is a direct application of the Time Value of Money (TVM), demonstrating that money grows when invested or lent at a positive interest rate.
Calculation Formula
The formula for Future Value (FV) is the standard compound interest formula for the accumulated amount. If you have a Present Value (PV) invested today, its Future Value after $n$ periods at a periodic interest rate $i$ is given by:
$\mathbf{FV = PV(1 + i)^n}$
Where:
- FV = The Future Value of the investment or sum.
- PV = The Present Value, which is the initial principal amount invested or borrowed today.
- i = The periodic interest rate per compounding period (as a decimal). This is calculated by dividing the nominal annual rate ($r$) by the number of compounding periods per year ($m$), so $i = r/m$.
- n = The total number of compounding periods over the investment/loan term. This is calculated by multiplying the time in years ($t$) by the number of compounding periods per year ($m$), so $n = m \times t$.
If the nominal annual rate is $r$ compounded $m$ times per year over $t$ years, the formula can be written more explicitly as:
$\mathbf{FV = PV\left(1 + \frac{r}{m}\right)^{mt}}$
The term $(1+i)^n$ or $(1 + r/m)^{mt}$ is called the future value factor or accumulation factor. It represents the amount to which $\textsf{₹}\$ 1$ (or $1) invested today will grow after $n$ periods at an interest rate of $i$ per period. Multiplying the Present Value by this factor gives its Future Value.
Key Factors Affecting Future Value
Based on the formula $FV = PV(1 + i)^n$, the Future Value is influenced by:
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Present Value (PV): A larger initial investment (higher PV) will result in a higher future value, assuming rate and time are constant. This is a directly proportional relationship.
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Interest Rate (i or r): A higher interest rate leads to faster growth and a significantly higher future value over time. The relationship is exponential.
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Number of Periods (n or t): The longer the money is invested or allowed to compound (larger $n$ or $t$), the higher its future value. The relationship is exponential.
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Compounding Frequency (m): For a given nominal annual rate, a higher compounding frequency ($m$) means interest is added to the principal more often, leading to a higher overall future value than less frequent compounding.
Worked Examples
Example 1. If you deposit $\textsf{₹}\$ 35,000$ today in an account earning 8% per annum compounded annually, what will be the amount in the account after 5 years?
Answer:
Given:
- Present Value (PV) = $\textsf{₹}\$ 35,000$
- Time (t) = 5 years
- Annual Rate (R) = 8%. Convert to decimal: $r = \frac{8}{100} = 0.08$.
- Compounding: Annually, so $m=1$.
To Find:
- Future Value (FV) after 5 years.
Calculate Periodic Rate (i) and Total Number of Periods (n):
Periodic rate $i = r/m = 0.08/1 = 0.08$.
Total number of periods $n = m \times t = 1 \times 5 = 5$.
Formula:
$FV = PV(1 + i)^n$
Solution:
Substitute the given values into the formula:
$FV = 35000 (1 + 0.08)^5$
$FV = 35000 (1.08)^5$
Calculate $(1.08)^5$. Using a calculator (or financial tables):
$(1.08)^5 \approx 1.469328$
So,
$FV = 35000 \times 1.469328$
Performing the multiplication:
$FV \approx 51426.48$
Rounding to two decimal places, the amount in the account after 5 years will be approximately $\textsf{₹}\$ 51,426.48$.
Example 2. Calculate the future value of $\textsf{₹}\$ 10,000$ invested for 3 years at 6% per annum compounded quarterly.
Answer:
Given:
- Present Value (PV) = $\textsf{₹}\$ 10,000$
- Time (t) = 3 years
- Nominal annual rate (R) = 6%. Convert to decimal: $r = \frac{6}{100} = 0.06$.
- Compounding frequency: Quarterly, so $m=4$.
To Find:
- Future Value (FV) after 3 years.
Calculate Periodic Rate (i) and Total Number of Periods (n):
Periodic rate $i = \frac{r}{m} = \frac{0.06}{4} = 0.015$. (This is the interest rate per quarter).
Total number of periods $n = m \times t = 4 \times 3 = 12$. (There are 12 quarters in 3 years).
Formula:
$FV = PV(1 + i)^n$
Solution:
Substitute the given values into the formula:
$FV = 10000 (1 + 0.015)^{12}$
$FV = 10000 (1.015)^{12}$
Calculate $(1.015)^{12}$. Using a calculator (or financial tables):
$(1.015)^{12} \approx 1.19561817
So,
$FV = 10000 \times 1.19561817$
$FV \approx 11956.1817$
Rounding to two decimal places, the future value is approximately $\textsf{₹}\$ 11,956.18$.
Summary for Competitive Exams
Future Value (FV): The value of a current sum of money at a future date, assuming growth at a specific interest rate.
Concept: Accumulation of present value over time due to compounding.
Formula: $\mathbf{FV = PV(1 + i)^n = PV\left(1 + \frac{r}{m}\right)^{mt}}$
- FV: Future Value
- PV: Present Value
- i: Periodic interest rate (decimal, $r/m$)
- n: Total number of periods ($mt$)
- r: Nominal annual rate (decimal)
- m: Compounding frequency per year
- t: Time in years
Accumulation Factor: $(1 + i)^n$ or $(1 + r/m)^{mt}$. Represents the future value of 1 unit of currency invested for $n$ periods.
Factors: FV increases with PV, higher $i$ (or $r$), and longer $n$ (or $t$ & $m$).
Time Value of Money: Relationship between Present Value and Future Value
Inverse Operations: Discounting and Accumulation
Present Value (PV) and Future Value (FV) are two sides of the same coin within the concept of the Time Value of Money. They represent the value of the same underlying sum of money but at different points in time, connected by the passage of time and the effect of the interest rate (or discount rate).
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Accumulation (Compounding): This is the process of calculating the Future Value of a Present Value. You start with a sum today and project its growth forward in time by adding interest over successive periods. The formula is $FV = PV(1 + i)^n$. Here, you are essentially multiplying the PV by a factor greater than 1 (if $i>0, n>0$) to find its larger future worth.
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Discounting: This is the inverse process of calculating the Present Value of a Future Value. You start with a sum expected in the future and bring it back to the present by removing the interest component it would have earned. The formula is $PV = FV(1 + i)^{-n}$. Here, you are essentially multiplying the FV by a factor less than 1 (if $i>0, n>0$) to find its smaller present worth.
Accumulation moves money forward in time, while discounting moves money backward in time. They are perfectly symmetrical and are inverse operations.
The Core Relationship
The fundamental link between PV and FV is captured in the compound interest formula. Regardless of whether you are calculating FV from PV or PV from FV, the underlying relationship is the same:
$\mathbf{FV = PV(1 + i)^n}$
This equation shows that Future Value is the Present Value multiplied by the accumulation factor $(1+i)^n$.
Equivalently, rearranging this formula shows that Present Value is the Future Value divided by the accumulation factor, or multiplied by the discount factor:
$\mathbf{PV = \frac{FV}{(1 + i)^n} = FV(1 + i)^{-n}}$
These formulas mean that if you know any three of the four variables (PV, FV, periodic rate $i$, total periods $n$), you can always calculate the fourth.
Key Insights from the Relationship
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PV is always less than FV (for $i>0, n>0$): Because money earns interest over time, a sum today will grow to a larger sum in the future. Conversely, a sum in the future is worth less than that amount today because you could invest a smaller amount today and have it grow to the future sum.
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The Difference is Interest: The difference between the Future Value and the Present Value ($FV - PV$) represents the total compound interest earned or paid over the period.
$CI = FV - PV = PV(1+i)^n - PV = PV[(1+i)^n - 1]$
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Accumulation Factor vs. Discount Factor:
- The term $(1+i)^n$ is the Accumulation Factor. It's the factor by which PV is multiplied to get FV. It is always $\ge 1$ for $n \ge 0, i \ge 0$.
- The term $(1+i)^{-n} = \frac{1}{(1+i)^n}$ is the Discount Factor. It's the factor by which FV is multiplied to get PV. It is always $\le 1$ for $n \ge 0, i \ge 0$.
- The discount factor is simply the reciprocal of the accumulation factor for the same rate and number of periods.
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Impact of Rate and Time: Both the interest/discount rate ($i$) and the number of periods ($n$) have an exponential impact on the relationship. Small changes in the rate or time can lead to significant differences between PV and FV, especially over longer periods. Higher rates and longer times increase the difference between FV and PV.
Understanding the dynamic relationship between Present Value and Future Value is essential for evaluating investment opportunities, calculating loan repayments, valuing assets, and making any financial decision that involves cash flows occurring at different points in time. It allows financial analysts and individuals to compare the value of money consistently across time.
Summary for Competitive Exams
Core Principle: Time Value of Money (TVM) - Money today is worth more than money tomorrow.
Accumulation: Moving money FORWARD in time (PV to FV). Uses interest rate.
Discounting: Moving money BACKWARD in time (FV to PV). Uses discount rate.
Formula Linking PV and FV: $\mathbf{FV = PV(1 + i)^n}$ OR $\mathbf{PV = FV(1 + i)^{-n}}$
- PV: Present Value
- FV: Future Value
- i: Periodic rate (decimal)
- n: Total periods
Accumulation Factor: $(1+i)^n$. $FV = PV \times \text{Accumulation Factor}$.
Discount Factor: $(1+i)^{-n} = \frac{1}{(1+i)^n}$. $PV = FV \times \text{Discount Factor}$.
Relationship: PV < FV for $i>0, n>0$. Difference is Compound Interest.
Key Use: Comparing cash flows at different times, fundamental to all financial calculations.
Time Value of Money: Net Present Value (NPV): Definition, Calculation, and Decision Rule
Definition
The Net Present Value (NPV) is a sophisticated capital budgeting technique used to evaluate the profitability of an investment or project. It determines the value of all future cash flows, both positive (inflows) and negative (outflows), generated by a project, discounted back to their present value, and then subtracts the initial investment cost.
In essence, NPV measures the "net" benefit or wealth created (or lost) by undertaking a project today, considering that money has a time value. A positive NPV indicates that the project is expected to generate cash flows whose present value is greater than the initial cost, thereby adding value to the firm or investor in today's terms. A negative NPV suggests the project is expected to result in a loss of value in present terms.
The discount rate used in the NPV calculation is typically the required rate of return, cost of capital, or the opportunity cost of capital – the return that could be earned on an investment of similar risk elsewhere.
Calculation Formula
To calculate the Net Present Value (NPV), we need to identify all the cash flows associated with the project and the appropriate discount rate. The cash flows typically occur at different points in time.
Let:
- $C_0$ = The initial investment cost or outflow at the beginning of the project (Time = 0). This is usually a negative cash flow.
- $C_1, C_2, C_3, \dots, C_n$ = The net cash flows expected to be received or paid at the end of periods 1, 2, 3, ..., up to period $n$. These are often inflows (positive), but can be outflows (negative) in some periods.
- $i$ = The discount rate per period, expressed as a decimal. This rate reflects the required rate of return for the project's risk level. It must be consistent with the period length of the cash flows (e.g., if cash flows are annual, $i$ is the annual discount rate).
- $n$ = The total number of periods over the life of the project.
The formula for NPV is the sum of the present values of all future cash flows, minus the present value of the initial investment (which is already at present value):
$\mathbf{NPV = \frac{C_1}{(1+i)^1} + \frac{C_2}{(1+i)^2} + \dots + \frac{C_n}{(1+i)^n} - C_0}$
Using the summation notation, this formula can be written more compactly:
$\mathbf{NPV = \sum_{t=1}^{n} \frac{C_t}{(1+i)^t} - C_0}$
... (1)
Alternatively, if we consider $C_0$ as the cash flow at time $t=0$ (which is negative), the formula can be written as the sum of the present values of all cash flows, starting from $t=0$:
$NPV = \frac{C_0}{(1+i)^0} + \frac{C_1}{(1+i)^1} + \frac{C_2}{(1+i)^2} + \dots + \frac{C_n}{(1+i)^n}$
Since $(1+i)^0 = 1$, this becomes:
$\mathbf{NPV = C_0 + \sum_{t=1}^{n} \frac{C_t}{(1+i)^t}}$ (where $C_0$ is a negative value)
... (2)
Both formulas are equivalent. Formula (1) explicitly shows the initial cost being subtracted, while formula (2) treats the initial cost as a negative cash flow at time zero and sums all present values.
Decision Rule for NPV
The Net Present Value method provides a clear rule for accepting or rejecting investment projects. This rule is based on the principle that businesses should accept projects that increase the wealth of their owners (or investors).
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If NPV > 0 (NPV is positive): The present value of expected cash inflows is greater than the present value of expected cash outflows (including the initial cost). The project is expected to generate a return greater than the required rate of return (discount rate). Such a project is considered financially viable and should be accepted.
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If NPV < 0 (NPV is negative): The present value of expected cash inflows is less than the present value of expected cash outflows. The project is expected to generate a return less than the required rate of return. Such a project is considered financially unviable and should be rejected.
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If NPV = 0 (NPV is zero): The present value of expected cash inflows equals the present value of expected cash outflows. The project is expected to generate a return exactly equal to the required rate of return. Financially, the company is indifferent between accepting or rejecting the project. The decision might then depend on non-financial factors or if there are mutually exclusive alternatives.
When choosing among mutually exclusive projects (projects where selecting one automatically means you cannot select the others), the project with the highest positive NPV is preferred, as it is expected to add the most value.
Worked Example
Example 1. A company is considering a project that requires an initial investment of $\textsf{₹}\$ 1,00,000$. The project is expected to generate cash inflows of $\textsf{₹}\$ 30,000$ at the end of Year 1, $\textsf{₹}\$ 40,000$ at the end of Year 2, $\textsf{₹}\$ 50,000$ at the end of Year 3, and $\textsf{₹}\$ 20,000$ at the end of Year 4. The company's required rate of return (discount rate) is 12% per annum. Calculate the Net Present Value (NPV) of the project and state whether the project should be accepted or rejected.
Answer:
Given:
- Initial Investment ($C_0$) = $\textsf{₹}\$ 1,00,000$ (This is an outflow, so we treat it as -$\textsf{₹}\$ 1,00,000$ at $t=0$).
- Cash Inflow Year 1 ($C_1$) = $\textsf{₹}\$ 30,000$ (at $t=1$).
- Cash Inflow Year 2 ($C_2$) = $\textsf{₹}\$ 40,000$ (at $t=2$).
- Cash Inflow Year 3 ($C_3$) = $\textsf{₹}\$ 50,000$ (at $t=3$).
- Cash Inflow Year 4 ($C_4$) = $\textsf{₹}\$ 20,000$ (at $t=4$).
- Required Rate of Return (Discount Rate, $i$) = 12% per annum = 0.12.
To Find:
- Net Present Value (NPV).
- Decision regarding project acceptance.
Formula:
We will use the formula $NPV = \sum_{t=1}^{n} \frac{C_t}{(1+i)^t} - C_0$.
In this case, $n=4$.
$NPV = \frac{C_1}{(1+i)^1} + \frac{C_2}{(1+i)^2} + \frac{C_3}{(1+i)^3} + \frac{C_4}{(1+i)^4} - C_0$
Solution: Calculate Present Value (PV) of each cash inflow
We need to calculate the discount factors $(1+i)^{-t}$ for each year $t$ at $i=0.12$ and multiply them by the respective cash flows $C_t$.
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Year 1 (t=1): Discount factor $(1+0.12)^{-1} = (1.12)^{-1} = \frac{1}{1.12} \approx 0.892857$
$PV(C_1) = 30000 \times 0.892857 \approx \textsf{₹}\$ 26785.71$
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Year 2 (t=2): Discount factor $(1+0.12)^{-2} = (1.12)^{-2} = \frac{1}{(1.12)^2} = \frac{1}{1.2544} \approx 0.797194$
$PV(C_2) = 40000 \times 0.797194 \approx \textsf{₹}\$ 31887.76$
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Year 3 (t=3): Discount factor $(1+0.12)^{-3} = (1.12)^{-3} = \frac{1}{(1.12)^3} \approx \frac{1}{1.404928} \approx 0.711780$
$PV(C_3) = 50000 \times 0.711780 \approx \textsf{₹}\$ 35589.00$
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Year 4 (t=4): Discount factor $(1+0.12)^{-4} = (1.12)^{-4} \approx \frac{1}{1.573519} \approx 0.635518$
$PV(C_4) = 20000 \times 0.635518 \approx \textsf{₹}\$ 12710.36$
Calculate Total Present Value of Inflows:
Sum of the present values of all future cash inflows:
Total PV of Inflows = $PV(C_1) + PV(C_2) + PV(C_3) + PV(C_4)$
Total PV of Inflows $\approx 26785.71 + 31887.76 + 35589.00 + 12710.36$
Let's perform the addition:
$\begin{array}{cccccccc} & 2 & 6 & 7 & 8 & 5 & . & 7 1 \\ & 3 & 1 & 8 & 8 & 7 & . & 7 6 \\ & 3 & 5 & 5 & 8 & 9 & . & 0 0 \\ + & 1 & 2 & 7 & 1 & 0 & . & 3 6 \\ \hline 1 & 0 & 6 & 9 & 7 2 & . & 8 3 \\ \hline \end{array}$Total PV of Inflows $\approx \textsf{₹}\$ 1,06,972.83$
Calculate Net Present Value (NPV):
$NPV = (\text{Total PV of Inflows}) - (\text{Initial Investment})$
$NPV \approx \textsf{₹}\$ 1,06,972.83 - \textsf{₹}\$ 1,00,000$
Let's perform the subtraction:
$\begin{array}{cccccccc} & 1 & 0 & 6 & 9 & 7 2 & . & 8 3 \\ - & 1 & 0 & 0 & 0 & 0 0 & . & 0 0 \\ \hline & & 0 & 6 & 9 & 7 2 & . & 8 3 \\ \hline \end{array}$$NPV \approx \textsf{₹}\$ 6,972.83$
Decision:
Since the calculated Net Present Value (NPV) is approximately $\textsf{₹}\$ 6,972.83$, which is a positive value ($NPV > 0$), the project is expected to generate a return greater than the required rate of return of 12%. This indicates that the project is financially attractive and is expected to increase the company's wealth.
Therefore, according to the NPV decision rule, the project should be accepted.
Summary for Competitive Exams
Net Present Value (NPV): Present value of future cash flows minus initial investment cost. Measures value creation in today's terms.
Formula: $\mathbf{NPV = \sum_{t=1}^{n} \frac{C_t}{(1+i)^t} - C_0}$ or $\mathbf{NPV = C_0 + \sum_{t=1}^{n} \frac{C_t}{(1+i)^t}}$ (with $C_0$ as negative outflow).
- $C_t$: Net cash flow in period $t$.
- $C_0$: Initial investment (outflow at $t=0$).
- $i$: Discount rate per period (required return).
- $n$: Project life in periods.
Decision Rule:
- $\mathbf{NPV > 0: Accept}$ (Adds value)
- $\mathbf{NPV < 0: Reject}$ (Destroys value)
- $\mathbf{NPV = 0: Indifferent}$ (Meets required return)
For mutually exclusive projects, choose the one with the highest positive NPV.
Time Value of Money: Applications of Present Value and Future Value in Financial Decisions
Significance of PV and FV in Finance
The concepts of Present Value (PV) and Future Value (FV) are not merely academic exercises; they are the backbone of numerous financial calculations and decision-making processes for individuals, businesses, and governments. By providing a framework to compare the value of money across different points in time, they enable rational choices regarding investments, savings, borrowings, and asset valuation.
Key Applications
Here are some major applications of Present Value and Future Value concepts:
1. Investment Appraisal and Capital Budgeting
PV and FV are extensively used to evaluate the financial viability of potential investment projects (like buying new machinery, opening a new branch, etc.).
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Net Present Value (NPV): As discussed in the previous section, NPV calculates the current worth of a project's expected future cash flows minus the initial investment. A positive NPV indicates a profitable project.
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Internal Rate of Return (IRR): This technique finds the discount rate that makes the NPV of a project equal to zero. Comparing the IRR to the required rate of return helps in deciding whether to accept the project.
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Profitability Index (PI): Calculated as the ratio of the present value of future cash inflows to the initial investment. A PI greater than 1 indicates a positive NPV.
2. Valuation of Assets and Securities
The fair value of many financial assets and securities is determined by calculating the present value of the future cash flows they are expected to generate.
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Bond Valuation: The market price (value) of a bond is the sum of the present values of all its future coupon payments (interest payments) and the present value of its face value (principal repayment) at maturity. The discount rate used is the prevailing market yield for similar bonds.
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Stock Valuation (Discounted Cash Flow - DCF Model): One of the primary methods to estimate the intrinsic value of a stock is to calculate the present value of the future dividends the company is expected to pay or the present value of the company's expected future free cash flows. The discount rate is the investor's required rate of return.
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Real Estate Valuation: Income-generating properties can be valued by discounting the expected future rental income and the eventual sale price back to the present.
3. Loan Calculations and Management
PV and FV are fundamental to understanding and managing loans.
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Loan Amortisation: Calculating the Equated Monthly Installment (EMI) for a loan involves finding the periodic payment amount whose present value, discounted at the loan's interest rate, equals the initial loan principal. The outstanding loan balance at any point is the present value of the remaining future EMIs.
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Calculating Loan Principal: Determining how much can be borrowed today given a set of affordable future payments involves finding the present value of those payments.
4. Personal Financial Planning (Savings and Retirement)
Individuals use PV and FV extensively for setting and achieving financial goals.
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Retirement Planning: Calculating how much needs to be saved periodically (using Future Value of an Annuity concept, which is based on FV) to reach a desired retirement corpus (FV) by a certain age. Alternatively, calculating the present value of the income stream needed during retirement to determine how large the retirement fund needs to be today.
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Savings Goals: Determining how much a current lump sum or a series of regular savings deposits (using FV of annuity) will grow to for future expenses like a child's education, a down payment on a house, or a vacation.
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Comparing Financial Products: Using EAR (derived from PV/FV concepts) to compare different savings accounts or loan offers with varying nominal rates and compounding frequencies.
5. Comparing Cash Flows Occurring at Different Times
Perhaps the most basic application is simply bringing disparate cash flows to a common point in time for comparison. You cannot directly compare $\textsf{₹}\$ 1,000$ today with $\textsf{₹}\$ 1,100$ received a year from now without considering the time value of money. By calculating the FV of $\textsf{₹}\$ 1,000$ or the PV of $\textsf{₹}\$ 1,100$, you can make a direct, rational comparison based on a chosen interest rate.
6. Lease vs. Buy Decisions
Businesses often compare the cost of leasing an asset versus purchasing it. This involves calculating the present value of all future lease payments and comparing it to the purchase price (which is already a present value).
7. Insurance and Annuity Products
Pricing insurance policies and calculating payouts for annuities (a series of regular payments) heavily rely on calculating the present value of future payment streams and comparing them to the present value of premiums.
In conclusion, the ability to calculate and interpret Present Value and Future Value is an indispensable skill for making sound financial decisions, whether in personal finance, corporate finance, or investment management. These concepts provide the tools to account for the time value of money and compare financial opportunities on a consistent and rational basis.
Summary for Competitive Exams
PV and FV Applications: Used across finance to account for Time Value of Money.
Key Areas:
- Investment Appraisal: Evaluating projects using NPV, IRR, PI (all based on PV). Accept positive NPV projects.
- Valuation: Determining the fair price of assets (bonds, stocks, real estate) by discounting future cash flows (using PV formulas).
- Loan Calculations: Calculating EMIs (PV of annuity formula), outstanding balances (PV of remaining payments).
- Financial Planning: Setting savings goals (FV of current/future savings), retirement planning (FV of corpus, PV of future income needs).
- Cash Flow Comparison: Bringing money from different times to a common point (usually PV) for comparison.
- Lease vs. Buy: Comparing PV of lease payments to cost of buying.
- Insurance/Annuities: Pricing products based on PV of future cash flows.
These applications highlight the practical importance of PV and FV in making informed financial decisions.