Compound interest

Effective interest rates
The effect of earning 20% annual interest on an initial $1,000 investment at various compounding frequencies

Compound interest is the addition of interest to the principal sum of a loan or deposit, or in other words, interest on interest. It is the result of reinvesting interest, rather than paying it out, so that interest in the next period is then earned on the principal sum plus previously-accumulated interest. Compound interest is standard in finance and economics.

Compound interest may be contrasted with simple interest, where interest is not added to the principal, so there is no compounding. The simple annual interest rate is the interest amount per period, multiplied by the number of periods per year. The simple annual interest rate is also known as the nominal interest rate (not to be confused with the real, or inflation-adjusted, rate).

Compounding frequency

The compounding frequency is the number of times per year (or other unit of time) the accumulated interest is paid out, or capitalized (credited to the account), on a regular basis. The frequency could be yearly, half-yearly, quarterly, monthly, weekly, daily (or not at all, until maturity).

For example, monthly capitalization with annual rate of interest means that the compounding frequency is 12, with time periods measured in months.

The effect of compounding depends on:

  1. The nominal interest rate which is applied and
  2. The frequency interest is compounded.

Annual equivalent rate

The nominal rate cannot be directly compared between loans with different compounding frequencies. Both the nominal interest rate and the compounding frequency are required in order to compare interest-bearing financial instruments.

To assist consumers compare retail financial products more fairly and easily, many countries require financial institutions to disclose the annual compound interest rate on deposits or advances on a comparable basis. The interest rate on an annual equivalent basis may be referred to variously in different markets as annual percentage rate (APR), annual equivalent rate (AER), effective interest rate, effective annual rate, annual percentage yield and other terms. The effective annual rate is the total accumulated interest that would be payable up to the end of one year, divided by the principal sum.

There are usually two aspects to the rules defining these rates:

  1. The rate is the annualised compound interest rate, and
  2. There may be charges other than interest. The effect of fees or taxes which the customer is charged, and which are directly related to the product, may be included. Exactly which fees and taxes are included or excluded varies by country. may or may not be comparable between different jurisdictions, because the use of such terms may be inconsistent, and vary according to local practice.

Examples

Discount instruments


Mathematics of interest rate on loans

Calculation of compound interest

The total accumulated value, including the principal sum plus compounded interest , is given by the formula: Fv=Pv(r/n)^nt

where:

P is the original principal sum
P' is the new principal sum
r is the nominal annual interest rate
n is the compounding frequency
t is the overall length of time the interest is applied (usually expressed in years).

The total compound interest generated is:

Puvan

Suppose a principal amount of $1,500 is deposited in a bank paying an annual interest rate of 4.3%, compounded quarterly.
Then the balance after 6 years is found by using the formula above, with P = 1500, r = 0.043 (4.3%), n = 4, and t = 6:

So the new principal after 6 years is approximately $1,938.84.

Subtracting the original principal from this amount gives the amount of interest received:

Example 2

Suppose the same amount $1,500 is compounded biennially (every 2 years).
Then the balance after 6 years is found by using the formula above, with P = 1500, r = 0.043 (4.3%), n = 1/2 = 0.5 (the interest is compounded every two years), and t = 6:

So, the balance after 6 years is approximately $1,921.24.

The amount of interest received can be calculated by subtracting the principal from this amount.

The interest is less compared with the previous case, as a result of the lower compounding frequency.

Periodic compounding

The amount function for compound interest is an exponential function in terms of time.

Where:

= Total time in years
= Number of compounding periods per year (note that the total number of compounding periods is )
= Nominal annual interest rate expressed as a decimal. e.g.: 6% = 0.06
means that nt is rounded down to the nearest integer.

Since the principal is simply a coefficient, it is often dropped for simplicity, and the resulting accumulation function is used instead. Accumulation functions for simple and compound interest are listed below:

Note: A(t) is the amount function and a(t) is the accumulation function.

Continuous compounding

As n, the number of compounding periods per year, increases without limit, we have the case known as continuous compounding, in which case the effective annual rate approaches an upper limit of er  1, where e is a mathematical constant that is the base of the natural logarithm.

Continuous compounding can be thought of as making the compounding period infinitesimally small,achieved by taking the limit as n goes to infinity. See definitions of the exponential function for the mathematical proof of this limit. The amount after t periods of continuous compounding can be expressed in terms of the initial amount A0 as

Force of interest

As the number of compounding periods reaches infinity in continuous compounding, the continuous compound interest is referred to as the force of interest .

In mathematics, the accumulation functions are often expressed in terms of e, the base of the natural logarithm. This facilitates the use of calculus to manipulate interest formulae.

For any continuously differentiable accumulation function a(t), the force of interest, or more generally the logarithmic or continuously compounded return is a function of time defined as follows:

This is the logarithmic derivative of the accumulation function.

Conversely:

(since ; this can be viewed as a particular case of a product integral).

When the above formula is written in differential equation format, then the force of interest is simply the coefficient of amount of change:

For compound interest with a constant annual interest rate r, the force of interest is a constant, and the accumulation function of compounding interest in terms of force of interest is a simple power of e:

or

The force of interest is less than the annual effective interest rate, but more than the annual effective discount rate. It is the reciprocal of the e-folding time. See also notation of interest rates.

A way of modeling the force of inflation is with Stoodley's formula:  where p, r and s are estimated.

Compounding basis

To convert an interest rate from one compounding basis to another compounding basis, use

where r1 is the interest rate with compounding frequency n1, and r2 is the interest rate with compounding frequency n2.

When interest is continuously compounded, use

where is the interest rate on a continuous compounding basis, and r is the stated interest rate with a compounding frequency n.

Monthly amortized loan or mortgage payments

The interest on loans and mortgages that are amortized—that is, have a smooth monthly payment until the loan has been paid off—is often compounded monthly. The formula for payments is found from the following argument.

Exact formula for monthly payment

An exact formula for the monthly payment () is

or equivalently

where:

= monthly payment
= principal
= monthly interest rate
= number of payment periods

This can be derived by considering how much is left to be repaid after each month.
The Principal remaining after the first month is

i.e. the initial amount has increased less the payment.
If the whole loan is repaid after one month then

, so

After the second month is left, so

If the whole loan was repaid after two months,

, so

This equation generalises for a term of n months, . This is a geometric series which has the sum

which can be rearranged to give

This formula for the monthly payment on a U.S. mortgage is exact and is what banks use.

Spreadsheet Formula

In spreadsheets, the PMT() function is used. The syntax is:

PMT( interest_rate, number_payments, present_value, future_value,[Type] )

See Excel, Mac Numbers, Libreoffice, Open Office for more details.

For example, for interest rate of 6% (0.06/12), 25 years * 12 p.a., PV of $150,000, FV of 0, type of 0 gives:


= $966.45

Approximate formula for monthly payment

A formula that is accurate to within a few percent can be found by noting that for typical U.S. note rates ( and terms =10–30 years), the monthly note rate is small compared to 1: so that the which yields a simplification so that

which suggests defining auxiliary variables

.

is the monthly payment required for a zero interest loan paid off in installments. In terms of these variables the approximation can be written

The function is even: implying that it can be expanded in even powers of .

It follows immediately that can be expanded in even powers of plus the single term:

It will prove convenient then to define

so that which can be expanded:

where the ellipses indicate terms that are higher order in even powers of . The expansion

is valid to better than 1% provided .

Example of mortgage payment

For a $10,000 mortgage with a term of 30 years and a note rate of 4.5%, payable yearly, we find:

which gives

so that

The exact payment amount is so the approximation is an overestimate of about a sixth of a percent.

History

Compound interest was once regarded as the worst kind of usury and was severely condemned by Roman law and the common laws of many other countries.[2]

The Florentine merchant Francesco Balducci Pegolotti provided a table of compound interest in his book Pratica della mercatura of about 1340. It gives the interest on 100 lire, for rates from 1% to 8%, for up to 20 years.[3] The Summa de arithmetica of Luca Pacioli (1494) gives the Rule of 72, stating that to find the number of years for an investment at compound interest to double, one should divide the interest rate into 72.

Richard Witt's book Arithmeticall Questions, published in 1613, was a landmark in the history of compound interest. It was wholly devoted to the subject (previously called anatocism), whereas previous writers had usually treated compound interest briefly in just one chapter in a mathematical textbook. Witt's book gave tables based on 10% (the then maximum rate of interest allowable on loans) and on other rates for different purposes, such as the valuation of property leases. Witt was a London mathematical practitioner and his book is notable for its clarity of expression, depth of insight and accuracy of calculation, with 124 worked examples.[4][5]

Jacob Bernoulli discovered the constant in 1683 by studying a question about compound interest.

Trivia

Albert Einstein is apocryphally quoted as saying "Compound interest is the eighth wonder of the world. He who understands it, earns it ... he who doesn't ... pays it.[6]

See also

Look up interest in Wiktionary, the free dictionary.

References

  1. http://laws.justice.gc.ca/en/showdoc/cs/I-15/bo-ga:s_6//en#anchorbo-ga:s_6 Interest Act (Canada), Department of Justice. The Interest Act specifies that interest is not recoverable unless the mortgage loan contains a statement showing the rate of interest chargeable, "calculated yearly or half-yearly, not in advance." In practice, banks use the half-yearly rate.
  2.  This article incorporates text from a publication now in the public domain: Chambers, Ephraim, ed. (1728). "article name needed". Cyclopædia, or an Universal Dictionary of Arts and Sciences (first ed.). James and John Knapton, et al.
  3. Evans, Allan (1936). Francesco Balducci Pegolotti, La Pratica della Mercatura. Cambridge, Mass. pp. 301–2.
  4. Lewin, C G (1970). "An Early Book on Compound Interest - Richard Witt's Arithmeticall Questions". Journal of the Institute of Actuaries. 96 (1): 121–132.
  5. Lewin, C G (1981). "Compound Interest in the Seventeenth Century". Journal of the Institute of Actuaries. 108 (3): 423–442.
  6. http://quoteinvestigator.com/2011/10/31/compound-interest/
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