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Line 1: ~~The~~In actuarial mathematics, the '''accumulation function''' ''a''(''t'') is a function ~~defined in terms~~ of time ''t'' expressing the ratio of the value at time ''t'' ([[future value]]) and the initial investment ([[present value]]).<ref name="Vaaler2009">{{cite book \|last1=Vaaler \|first1=Leslie Jane Federer \|last2=Daniel \|first2=James \|title=Mathematical Interest Theory \|date=19 February 2009 \|publisher=MAA \|isbn=978-0-88385-754-0 \|page=11-61 \|url=https://books.google.com/books?id=1lLsmGVj2HIC&dq=%22accumulation+function%22&pg=PA62 \|language=en}}</ref><ref name="Chan2021">{{cite book \|last1=Chan \|first1=Wai-sum \|last2=Tse \|first2=Yiu-kuen \|title=Financial Mathematics For Actuaries \|date=14 September 2021 \|publisher=World Scientific \|isbn=978-981-12-4329-5 \|page=2 \|edition=Third \|url=https://books.google.com/books?id=VoZGEAAAQBAJ&dq=%22accumulation+function%22&pg=PA2 \|language=en}}</ref> It is used in [[interest theory]]. Thus ~~<math>~~''a''(0) = 1~~.</math>,~~ and the value at time ''t'' is given by: :<math>A(t) = kA(0) \cdot a(t). </math>. where the initial investment is ~~''k''~~<math>A(0).</math> InFor ~~the~~various ~~case~~interest-accumulation ~~that~~protocols, the accumulation function is ~~due~~as tofollows (with ''i'' denoting the [[interest itrate]] isand an''d'' denoting the [[~~increasing~~annual ~~function~~effective discount rate\|discount rate]],): [[simple interest]]: <math>a(t)=1+t \cdot i.</math>▼ [[compound interest]]: <math>a(t)=(1+i)^t.</math>▼ [[simple discount]]: <math>a(t) = 1+\frac{td}{1-d}</math> [[compound discount]]: <math>a(t) = (1-d)^{-t}</math> In the case of a positive [[rate of return]], as in the case of interest, the accumulation function is an [[increasing function]]. ==Variable rate of return== The [[Rate_of_return#Logarithmic_or_continuously_compounded_return\|logarithmic or continuously compounded return]], sometimes called [[Compound interest#Force of interest\|force of interest]], is a function of time defined as follows: :<math>\delta_{t}=\frac{a'(t)}{a(t)}\,</math> Line 17 ⟶ 23: Conversely: :<math>a(nt)=~~e^{~~ \exp \left( \int_0^nt \~~delta_t~~delta_u\, ~~dt}\~~du \right), </math> reducing to :<math>a(t)=e^{t \delta}</math> for constant <math>\delta</math>. The effective [[annual percentage rate]] at any time is: :<math> r(t) = e^{\delta_t} - 1</math> ==See also==▼ ~~==Common accumulation functions==~~ [[~~time~~Time value of money]]▼ ~~The accumulation function for the two common types of interest:~~ ==References== ~~===Simple interest===~~ {{reflist}} ▲:<math>a(t)=1+t \cdot i.</math> {{DEFAULTSORT:Accumulation Function}} ~~===Compound interest===~~ ▲:<math>a(t)=(1+i)^t.</math> ▲==See also== ▲[[time value of money]] [[Category:Mathematical finance]] ~~[[ro:Funcţie de acumulare]]~~