Tag: amount of an annuity

$\Rightarrow$   Process of loan repayment by installment payment is classified as $amortizing\,a\,loan.$

Here, we have a deferred annuity of $8$ terms(n), deferred for $4$ terms.Each installment, A=Rs $10000$
Rate of interest, $r=$ $6\%$= $0.06$
m= $4$, $m + n=$ $12$
Using the formula, present value
$V = \dfrac{A}{r}$ $\times \dfrac{1}{(1+r)^m}$ - $\frac {1}{(1+r)^{m+n}}$
$V = \dfrac{10000}{0.06} \times [(1.06)^{-4}-(1.06)^{-12}]$$ =49187.38$

$ SI= prt$

$\Rightarrow$  Here, $P=Rs.2500,\, R=5\%,\, T=5\,years$.

$\Rightarrow$   We have, $V=\$1000\, r=8\%=0.08$ and $n=5$

Each Installment = $\dfrac{P{\cdot}r}{100[1-{{ \frac{100}{100+r} }}^n]}$

In first case, we have annuity due of $15$ terms.
Its present value (as on Mr. Gupta's $60^{th}$ birthday),
$v = \frac{A}{r} \times (1+r) \times [1-(1+r)^{-n}]$
= $\frac{3000}{0.08} \times 1.08 \times [1-(1.08)^{-15}]$
Now if only $10$ payments are to be received, we have annuity due of $10$ terms. If A is the amount of each annual installment,
$\frac{A}{0.08} \times 1.08 \times [1-(1.08)^{-10}]$
Thus,
$\frac{A}{0.08} \times 1.08 \times [1-(1.08)^{-10}]$ = $\frac{3000}{0.08} \times 1.08 \times [1-(1.08)^{-15}]$
A = $30000 \times \frac{[1-(1.08)^{-15}]}{[1-(1.08)^{-10}]}$
A = $38268$

$\Rightarrow$  Dollar amount of mortgage loan multiplied monthly payment of mortgage loan per dollar is used to calculate $monthly\,mortgage\,payment.$

$\Rightarrow$  Here, $A=Rs.500,\, n=8$ and $r=\dfrac{8}{100}\times \dfrac{1}{4}=0.02$

Payments if made at end of each period such as end of year is classified as ordinary annuity and deferred annuity.