@wikipedia
A popular mechanism of measuring the discounted cash flow value of the profit
LaTeX Math Block |
---|
|
NPV = \sum_{i=0}^n \frac{R_{t_i}}{(1+r)^{t_i}} = R_0 + \sum_{i=1}^n \frac{R_{t_i}}{(1+r)^{t_i}} |
where
| total number of time steps (usually time step is one year) |
---|
| time passed since the first investment ( assuming that ) |
---|
LaTeX Math Inline |
---|
body | r = \rm \frac{Cash_{out} - Cash_{in}}{Cash_{in}} |
---|
|
| discount rate |
---|
LaTeX Math Inline |
---|
body | R_{t_i} = \rm Cash_{in}(t_i) - \rm Cash_{out}(t_i) |
---|
|
| the net cash flow at time step |
---|
LaTeX Math Inline |
---|
body | R_0 = - \rm Cash_{out}(t=0) |
---|
|
| the volume of cash investment at initial time moment |
---|
Usually
, where
and
is number of years past.
The main idea of NPV is that value of cash today is higher than value of cash tomorrow because immediate cash can be invested readily available investment market opportunities and start brining some profit.
NPV dictates that commercial project should not only be just profitable but instead should be on par with or more profitable than easily available investment alternatives
The corporate investment policy usually dictates that:
investment projects with negative NPV should be rejected
investment projects with higher NPV should have a financing priority over the projects with lower NPV
See also
Economics