Time Value of Money¶

You should never compare money across different time instants. We can only compare at the same instant.

When we take cashflow ___ in time	Name
forward	compounding
backward	discounting

Return for every investment is a compensation

Time
Inflation
Risk

In a finance interview, if you’re not sure of the answer, just say it’s compounding 😭😂

Keywords¶

	Denotion	Expressed as	Value of something at
Present Value	PV	Currency	$t = 0$ (not even $t \approx 0$)
Future Value	FV	Currency	$t > 0$
Interest Rate Discount Rate Compound Rate Opportunity cost of capital Required return	$r$	%	Exchange rate between present & future value
Number of Periods	$n$ or $t$
Timeline			Graphical reprsesentation of the timing of cash flows

Singular Cashflow Formula¶

\[ \begin{aligned} \text{FV} &= \text{PV} \times \underbrace{(1+r)^t}_{\text{Compound Factor}} \\ \implies \text{PV} &= \text{FV} \times \underbrace{\frac{1}{(1+r)^t}}_\text{Discount Factor} \end{aligned} \]

Multiple Cashflows¶

\[ \begin{aligned} \text{FV} &= \sum_{t=0} c_t (1+r)^t \\ \text{PV} &= \sum_{t=0} \frac{c_t}{(1+r)^t} \end{aligned} \]

where $c_t$ can be

Flow Type
Inflow	$c_t>0$
Outflow	$c_t<0$

Types of Interest¶

If $P =$ original principal amount

Type	FV
Simple	$P \times (1+r) \times t$
Compound (Default)	$P \times (1+r)^t$

Types of Cashflows¶

Infinite series of cashflows which has

eg: Preference share in a corporation

	Perpetuity	Annuity
Finiteness	Infinite	Finite
Term	Forever
Fixed Cashflow	✅	✅
Occurs every time period	✅	✅
Present Value	$\frac{c}{r}$	$\frac{c}{r} \left[ 1-\frac{1}{(1+r)^t} \right]$
Future Value	N/A	$\frac{c}{r} \left[ (1+r)^t - 1 \right]$

Conceptual understanding of long-term loan¶

Every [equal] installment is actually a combination of

interest payment
principal repayment

As time goes on, your installment will be constituting: less of interest repayment & more of principal repayment

I missed a few classes¶

Interest Rates¶

APR¶

Annual Percentage Rate

EAR¶

Effective Annual Rate

The actual interest rate you are paying

\[ \text{EAR } = \left( 1 + \frac{\text{APR}}{m} \right)^m - 1 \]

where $m =$ interest compounding frequency

This is the value of $r$ we use when calculating present/future value

Compounding Frequency¶

	$m$
Annual	1
Semi-Annual	2
Quarterly	4
Monthly	12
Daily	365
Hourly	365 * 24
Minutely	365 * 24 * 60
Second	365 * 24 * 60 * 60

As we go from annual compounding towards more frequent compounding frequency, we are moving from discrete compounding to continuous compounding

Compounding Cycle¶

Frequency of compounding

Let $m$ be the compounding cycle, ie number of compounding per year $$ \begin{aligned} \text{FV} &= \text{PV} \cdot (1+r)^t \ &= \text{PV} \left(1 + \dfrac{r}{m} \right)^{mt} & \text{(Discrete)} \ &= \text{PV} \times e^{rt} & \text{(Continuous)} \end{aligned} $$

IDK¶

If you are in the middle of time period, and certain cashflows have already been taken, $$ \text{PV}' = \text{PV} \times \dfrac{1}{(1+r)^{t_a/t_b}} $$

$t_a=$ Time elapsed in current time period
$t_b=$ Time Period

Last Updated: 2024-05-12 ; Contributors: AhmedThahir

	Denotion	Expressed as	Value of something at
Present Value	PV	Currency	\(t = 0\) (not even \(t \approx 0\))
Future Value	FV	Currency	\(t > 0\)
Interest Rate Discount Rate Compound Rate Opportunity cost of capital Required return	\(r\)	%	Exchange rate between present & future value
Number of Periods	\(n\) or \(t\)
Timeline			Graphical reprsesentation of the timing of cash flows

Type	FV
Simple	\(P \times (1+r) \times t\)
Compound (Default)	\(P \times (1+r)^t\)