This **compound interest calculator** is a tool to help you **estimate how much money you will earn on your deposit**. In order to make smart financial decisions, you need to be able to foresee the final result. That's why it's worth knowing how to calculate compound interest. The most common real-life application of the compound interest formula is a regular savings calculation.

Read on to find answers to the following questions:

- What is the interest rate definition?
- What is the compound interest definition, and what is the compound interest formula?
- What is the difference between simple and compound interest rates?
- How to calculate compound interest?
- What are the most common compounding frequencies?

## How to use the compound interest calculator

Our compound interest calculator is a versatile tool that helps you forecast the growth of your investments over time. To effectively use it, follow these instructions:

**Enter initial balance**: Start by inputting the amount you have initially invested or saved.**Input interest rate**: Type in the annual interest rate your investment will earn.**Set the term**: Determine the number of years and months over which you want the investment to grow.**Select Compounding Frequency**: Choose how often the interest will be compounded. Options range from annually to daily.**Additional deposits**: Decide if you'll make additional deposits. If so, specify the amount, how often, whether these are at the beginning or end of the compounding period, and their annual growth rate.**Review results**: The calculator will display the final balance, total compound interest, and the breakdown of interest earned on the initial balance and additional deposits. It will also show the total principal amount and the sum of additional deposits made over the term.**Visualization**: You can choose to represent your balance growth visually by selecting a bar graph, pie chart, table, or a combined chart and table view.

For example, with an initial balance of $1,000 and an 8% interest rate compounded monthly over 20 years without additional deposits, the calculator shows a final balance of $4,926.80. The total compound interest earned is $3,926.80.

Whether for personal savings, retirement planning, or educational investments, this calculator offers the foresight needed to make informed financial decisions.

Read on to learn more about the magic of compound interest and how it's calculated.

## Interest rate definition

In finance, the interest rate is defined as the **amount charged by a lender to a borrower for the use of an asset**. So, for the borrower, the interest rate is the cost of the debt, while for the lender, it is the rate of return.

Note that in the case where you make a deposit into a bank (e.g., put money in your savings account), you have, from a financial perspective, lent money to the bank. In such a case, the interest rate reflects your profit.

The interest rate is commonly expressed as a percentage of the principal amount (outstanding loan or value of deposit). Usually, it is presented on an annual basis, which is known as the annual percentage yield (APY) or effective annual rate (EAR).

## What is the compound interest definition?

Generally, compound interest is defined as **interest that is earned not solely on the initial amount invested but also on any further interest**. In other words, compound interest is the interest on both the initial principal *and* the interest that has been accumulated on this principal so far. Therefore, the fundamental characteristic of compound interest is that **interest itself earns interest**. This concept of adding a carrying charge makes a deposit or loan grow at a faster rate.

You can use the compound interest equation to find the value of an investment after a specified period or estimate the rate you have earned when buying and selling some investments. It also allows you to answer some other questions, such as how long it will take to double your investment.

We will answer these questions in the examples below.

## Simple vs. compound interest

You should know that **simple interest** is something different than the **compound interest**. It is calculated only on the initial sum of money. On the other hand, compound interest is the interest on the initial principal plus the interest which has been accumulated.

## Compounding frequency

Most financial advisors will tell you that compound frequency is the number of compounding periods in a year. But if you are not sure what compounding is, this definition will be meaningless to you… To understand this term, you should know that compounding frequency is an answer to the question *How often is the interest added to the principal each year?* In other words, **compounding frequency is the time period after which the interest will be calculated on top of the initial amount**.

For example:

**Annual (1/Yr)**compounding has a compounding frequency of**one**,**Quarterly (4/Yr)**compounding has a compounding frequency of**four**,**Monthly (12/Yr)**compounding has a compounding frequency of**twelve**.

Note that the greater the compounding frequency is, the greater the final balance. However, even when the frequency is unusually high, the final value can't rise above a particular limit.

As the main focus of the calculator is the compounding mechanism, we designed a chart where you can follow the progress of the annual interest balances visually. If you choose a higher than yearly compounding frequency, the diagram will display the resulting extra or *additional part of interest gained over yearly compounding by the higher frequency*. Thus, in this way, you can easily observe the real power of compounding.

## Compound interest formula

The compound interest formula is an equation that lets you estimate how much you will earn with your savings account. It's quite complex because it takes into consideration not only the annual interest rate and the number of years but also the number of times the interest is compounded per year.

The formula for annual compound interest is as follows:

$\mathrm{FV} = P\cdot\left(1+ \frac r m\right)^{m\cdot t},$FV=P⋅(1+mr)m⋅t,

where:

- $\mathrm{FV}$FV – Future value of the investment, in our calculator it is the
**final balance** - $P$P –
**Initial balance**(the value of the investment); - $r$r – Annual
**interest rate**(in decimal); - $m$m – Number of times the interest is compounded per year (
**compounding frequency**); and - $t$t –
**Numbers of years**the money is invested for.

It is worth knowing that when the compounding period is one ($m = 1$m=1), then the interest rate ($r$r) is called the CAGR (compound annual growth rate): you can learn about this quantity at our CAGR calculator.

## Compound interest examples

*Do you want to understand the compound interest equation?**Are you curious about the fine details of how to calculate the compound interest rate?**Are you wondering how our calculator works?**Do you need to know how to interpret the results of compound interest calculation?**Are you interested in all possible uses of the compound interest formula?*

The following examples are there to try and help you answer these questions. We believe that after studying them, you won't have any trouble with understanding and practical implementation of compound interest.

## Example 1 – basic calculation of the value of an investment

The first example is the simplest, in which we calculate the future value of an initial investment.

**Question**

*You invest $10,000 for 10 years at the annual interest rate of 5%. The interest rate is compounded yearly. What will be the value of your investment after 10 years?*

**Solution**

Firstly let’s determine what values are given and what we need to find. We know that you are going to invest $\$10000$$10000 – this is your initial balance $P$P, and the number of years you are going to invest money is $10$10. Moreover, the interest rate $r$r is equal to $5\%$5%, and the interest is compounded on a yearly basis, so the $m$m in the compound interest formula is equal to $1$1.

We want to calculate the amount of money you will receive from this investment. That is, we want to find the future value $\mathrm{FV}$FV of your investment.

To count it, we need to plug in the appropriate numbers into the compound interest formula:

$\begin{split}\mathrm{FV}& = 10,\!000 \cdot \left(1 + \frac{0.05}{1}\right) ^ {10\cdot1} \\&= 10,\!000 \cdot 1.628895 \\&= 16,288.95\end{split}$FV=10,000⋅(1+10.05)10⋅1=10,000⋅1.628895=16,288.95

**Answer**

The value of your investment after 10 years will be $16,288.95.

Your profit will be $\mathrm{FV} - P$FV−P. It is $\$16288.95 - \$10000.00 = \$6288.95$$16288.95−$10000.00=$6288.95.

Note that when doing calculations, you must be very careful with your rounding. You shouldn't do too much until the very end. Otherwise, your answer may be incorrect. The accuracy is dependent on the values you are computing. For standard calculations, six digits after the decimal point should be enough.

## Example 2 – complex calculation of the value of an investment

In the second example, we calculate the future value of an initial investment in which interest is compounded monthly.

**Question**

*You invest $10,000 at the annual interest rate of 5%. The interest rate is compounded monthly. What will be the value of your investment after 10 years?*

**Solution**

Like in the first example, we should determine the values first. The initial balance $P$P is $\$10000$$10000, the number of years you are going to invest money is $10$10, the interest rate $r$r is equal to $5\%$5%, and the compounding frequency $m$m is $12$12. We need to obtain the future value $\mathrm{FV}$FV of the investment.

Let's plug in the appropriate numbers in the compound interest formula:

$\begin{split}\mathrm{FV}& = 10,\!000 \cdot\left(1 + \frac{0.05}{12}\right) ^ {10\cdot12}\\[1em]& = 10,\!000 \cdot 1.004167 ^ {120}\\& = 10,\!000 \cdot 1.647009 \\&= 16,470.09\end{split}$FV=10,000⋅(1+120.05)10⋅12=10,000⋅1.004167120=10,000⋅1.647009=16,470.09

**Answer**

The value of your investment after 10 years will be $\$16470.09$$16470.09.

Your profit will be $\mathrm{FV} - P$FV−P. It is $\$16470.09 - \$10000.00 = \$6470.09$$16470.09−$10000.00=$6470.09.

Did you notice that this example is quite similar to the first one? Actually, the only difference is the compounding frequency. Note that only thanks to more frequent compounding this time you will earn $\$181.14$$181.14 more during the same period: $\$6470.09 - \$6288.95 = \$181.14$$6470.09−$6288.95=$181.14.

## Example 3 – Calculating the interest rate of an investment using the compound interest formula

Now, let's try a different type of question that can be answered using the compound interest formula. This time, some basic algebra transformations will be required. In this example, we will consider a situation in which we know the initial balance, final balance, number of years, and compounding frequency, but we are asked to calculate the interest rate. This type of calculation may be applied in a situation where you want to determine the rate earned when buying and selling an asset (e.g., property) that you are using as an investment.

**Data and question***You bought an original painting for $2,000. Six years later, you sold this painting for $3,000. Assuming that the painting is viewed as an investment, what annual rate did you earn?*

**Solution**

Firstly, let's determine the given values. The initial balance $P$P is $\$2000$$2000 and final balance $\mathrm{FV}$FV is $\$3000$$3000. The time horizon of the investment is $6$6 years, and the frequency of the computing is $1$1. This time, we need to compute the interest rate $r$r.

Let's try to plug these numbers into the basic compound interest formula:

$3,\!000 = 2,\!000 \cdot\left(1 + \frac r 1\right) ^{6\cdot1}$3,000=2,000⋅(1+1r)6⋅1

So:

$3,\!000 = 2,\!000 \cdot(1 + r) ^6$3,000=2,000⋅(1+r)6

We can solve this equation using the following steps:

Divide both sides by $2000$2000:

$\frac{3,\!000}{2,\!000}= (1 + r) ^ 6$2,0003,000=(1+r)6

Raise both sides to the 1/6^{th} power:

$\frac{3,\!000}{2,\!000}^ {\frac 1 6} = (1 + r)$2,0003,00061=(1+r)

Subtract $1$1 from both sides:

$\frac{3,\!000}{2,\!000} ^{\frac 1 6} – 1 = r$2,0003,00061–1=r

Finally solve for $r$r:

$\begin{split}r & = 1.5 ^ {0.166667 }– 1\\& = 1.069913 - 1 \\&= 0.069913 = 6.9913\%\end{split}$r=1.50.166667–1=1.069913−1=0.069913=6.9913%

**Answer**

In this example you earned $1,000 out of the initial investment of $2,000 within the six years, meaning that your annual rate was equal to 6.9913%.

As you can see this time, the formula is not very simple and requires a lot of calculations. That's why it's worth testing our compound interest calculator, which solves the same equations in an instant, saving you time and effort.

## Example 4 – Calculating the doubling time of an investment using the compound interest formula

Have you ever wondered how many years it will take for your investment to double its value? Besides its other capabilities, our calculator can help you to answer this question. To understand how it does it, let's take a look at the following example.

**Data and question**

*You put $1,000 in your savings account. Assuming that the interest rate is equal to 4% and it is compounded yearly, find the number of years after which the initial balance will double.*

**Solution**

The given values are as follows: the initial balance $P$P is $\$1000$$1000 and final balance $\mathrm{FV}$FV is $2 \cdot \$1000 = \$2000$2⋅$1000=$2000, and the interest rate $r$r is $4\%$4%. The frequency of the computing is $1$1. The time horizon of the investment $t$t is unknown.

Let's start with the basic compound interest equation:

$\mathrm{FV} = P\cdot \left(1 + \frac{r}{m}\right)^{mt}$FV=P⋅(1+mr)mt

Knowing that $m = 1$m=1, $r = 4\%$r=4%, and $\mathrm{FV} = 2 \cdot P$FV=2⋅P we can write:

$2P = P \cdot(1 + 0.04) ^ t$2P=P⋅(1+0.04)t

Which could be written as:

$2P = P\cdot (1.04) ^ t$2P=P⋅(1.04)t

Divide both sides by $P$P ($P$P mustn't be $0$0!):

$2 = 1.04 ^ t$2=1.04t

To solve for $t$t, you need take the natural log ($\ln$ln), of both sides:

$\ln(2) = t \cdot \ln(1.04)$ln(2)=t⋅ln(1.04)

So:

$t \!=\! \frac{\ln(2)}{\ln(1.04) }\!=\! \frac{0.693147}{0.039221 }\!= \! 17.67$t=ln(1.04)ln(2)=0.0392210.693147=17.67

**Answer**

In our example, it takes 18 years (18 is the nearest integer that is higher than 17.67) to double the initial investment.

Have you noticed that in the above solution, we didn't even need to know the initial and final balances of the investment? It is thanks to the simplification we made in the third step (*Divide both sides by $P$P*). However, when using our compound interest rate calculator, you will need to provide this information in the appropriate fields. Don't worry if you just want to find the time in which the given interest rate would double your investment; just type in any numbers (for example, $1$1 and $2$2).

It is also worth knowing that exactly the same calculations may be used to compute when the investment would triple (or multiply by any number, in fact). All you need to do is just use a different multiple of P in the second step of the above example. You can also do it with our calculator.

## Compound interest table

Compound interest tables were used every day before the era of calculators, personal computers, spreadsheets, and unbelievable solutions provided by Omni Calculator 😂. The tables were designed to make the financial calculations simpler and faster (yes, really…). They are included in many older financial textbooks as an appendix.

Below, you can see what a compound interest table looks like.

t | r=1% | r=2% | r=3% | r=4% | ||||
---|---|---|---|---|---|---|---|---|

Compound amount factor | Present worth factor | Compound amount factor | Present worth factor | Compound amount factor | Present worth factor | Compound amount factor | Present worth factor | |

1 | 1.0100 | 0.9901 | 1.0200 | 0.9804 | 1.0300 | 0.9709 | 1.0400 | 0.9615 |

2 | 1.0201 | 0.9803 | 1.0404 | 0.9612 | 1.0609 | 0.9426 | 1.0816 | 0.9246 |

3 | 1.0303 | 0.9706 | 1.0612 | 0.9423 | 1.0927 | 0.9151 | 1.1249 | 0.8890 |

4 | 1.0406 | 0.9610 | 1.0824 | 0.9238 | 1.1255 | 0.8885 | 1.1699 | 0.8548 |

5 | 1.0510 | 0.9515 | 1.1041 | 0.9057 | 1.1593 | 0.8626 | 1.2167 | 0.8219 |

6 | 1.0615 | 0.9420 | 1.1262 | 0.8880 | 1.1941 | 0.8375 | 1.2653 | 0.7903 |

7 | 1.0721 | 0.9327 | 1.1487 | 0.8706 | 1.2299 | 0.8131 | 1.3159 | 0.7599 |

8 | 1.0829 | 0.9235 | 1.1717 | 0.8535 | 1.2668 | 0.7894 | 1.3686 | 0.7307 |

9 | 1.0937 | 0.9143 | 1.1951 | 0.8368 | 1.3048 | 0.7664 | 1.4233 | 0.7026 |

10 | 1.1046 | 0.9053 | 1.2190 | 0.8203 | 1.3439 | 0.7441 | 1.4802 | 0.6756 |

Using the data provided in the compound interest table, you can calculate the final balance of your investment. All you need to know is that the column **compound amount factor** shows the value of the factor $(1 + r)^t$(1+r)t for the respective interest rate (first row) and t (first column). So to calculate the final balance of the investment, you need to multiply the initial balance by the appropriate value from the table.

Note that the values from the column **Present worth factor** are used to compute the present value of the investment when you know its future value.

Obviously, this is only a basic example of a compound interest table. In fact, they are usually much, much larger, as they contain more periods $t$t various interest rates $r$r and different compounding frequencies $m$m... You had to flip through dozens of pages to find the appropriate value of the compound amount factor or present worth factor.

With your new knowledge of how the world of financial calculations looked before Omni Calculator, do you enjoy our tool? Why not share it with your friends? Let them know about Omni! If you want to be financially smart, you can also try our other finance calculators.

## Additional Information

Now that you know how to calculate compound interest, it's high time you found other applications to help you make the greatest profit from your investments:

To compare bank offers that have different compounding periods, we need to calculate the Annual Percentage Yield, also called Effective Annual Rate (EAR). This value tells us how much profit we will earn within a year. The most comfortable way to figure it out is using the APY calculator, which estimates the EAR from the interest rate and compounding frequency.

If you want to find out how long it would take for something to increase by n%, you can use our rule of 72 calculator. This tool enables you to check how much time you need to double your investment even quicker than the compound interest rate calculator.

You may also be interested in the credit card payoff calculator, which allows you to estimate how long it will take until you are completely debt-free.

The depreciation calculator enables you to use three different methods to estimate how fast the value of your asset decreases over time.

## Behind the scenes of compound interest calculator

Tibor Pál, a PhD in Statistical Methods in Economics with a proven track record in financial analysis, has applied his extensive knowledge to develop the compound interest calculator.

Inspired by his own need to calculate long-term investment returns and simplify the process for others, Tibor created this tool. It's designed to help users plan their financial future, whether for retirement, saving for a home, or understanding the potential growth of their investments.

Tibor has extensively used this calculator in various projects, allowing him to project financial outcomes accurately and advise on investment strategies. It's become an essential tool for anyone needing to calculate the future value of their investments, considering different compounding frequencies and additional contributions.

Trust in the compound interest calculator is grounded in our rigorous standards of accuracy and reliability. Financial experts have thoroughly vetted it to ensure it meets the practical needs of both individual investors and financial professionals.

## FAQ

### What's compound interest?

Compound interest is a type of interest that's calculated from both the initial balance and the interest accumulated from prior periods. Essentially you can see it as **earning interest from interest**.

### What's the difference between simple and compound interest?

While simple interest only earns interest on the **initial balance**, compound interest earns interest on both the initial balance and the **interest accumulated from previous periods**.

### How do I calculate compound interest?

To calculate compound interest is necessary to use the **compound interest formula**, which will show the **FV** future value of investment (or future balance):

**FV = P × (1 + (r / m)) ^{(m × t)}**

This formula takes into consideration the initial balance **P**, the annual interest rate **r**, the compounding frequency **m**, and the number of years **t**.

### How long does it take for $1,000 to double?

With a compounding interest rate, it takes **17 years and 8 months** to double (considering an annual compounding frequency and a 4% interest rate). To calculate this:

**Use the compound interest formula:****FV = P × (1 + (r / m))**^{(m × t)}**Substitute the values**. The future value**FV**is twice the initial balance**P**, the interest rate**r = 4%**, and the frequency**m = 1**:**2P = P × (1 + (0.04 / 1))**^{(1 × t)}**2 = (1.04)**^{t}**Solve**for time**t**:**t = ln(2) / ln(1.04)****t = 17.67 yrs = 17 years and 8 months**