What is compound interest?

Compound interest is the interest on a loan or deposit calculated based on both the initial principal and the accumulated interest from previous periods.

How is compound interest calculated?

Compound interest can be calculated using the formula A = P(1 + r/n)^(nt), where A is the amount of money accumulated after n years, including interest, P is the principal amount, r is the annual interest rate, n is the number of times interest is compounded per year, and t is the number of years.

What is the Rule of 72?

The Rule of 72 is a formula that estimates the number of years required to double the investment at a fixed annual rate of return by dividing 72 by the annual interest rate.

How does compounding frequency affect investment returns?

The more frequently interest is compounded, the more interest you earn on your investment. For example, quarterly compounding yields more than annual compounding.

How can I estimate the time it takes to double an investment?

You can estimate the doubling time by using the Rule of 72, which states that the time to double is approximately 72 divided by the annual interest rate in percentage.

What does it mean if an account is credited with interest annually?

If an account is credited yearly, it means that the interest is calculated once a year and added to the principal.

What is the importance of time in investing?

Time allows compound interest to accumulate, leading to greater returns. The longer an investment is held, the more significant the growth.

Can logarithms be used in calculating investment growth?

Yes, logarithms can be used to find the time required for an investment to grow to a certain amount when dealing with compound interest.

What does 'n' represent in the compound interest formula?

In the compound interest formula, 'n' represents the number of times interest is compounded per year.

What is meant by principal in investment terms?

Principal refers to the initial amount of money invested or loaned, not including any interest.

Compound Interest

00:10:52

https://www.youtube.com/watch?v=Hn0eLcOSQGw

Ringkasan

TLDRThe video provides a comprehensive look at compound interest through practical examples. It begins with Luke's investment of $1,000 at a 9% annual interest rate, showing how his investment grows to $2,367.36 after 10 years and $5,604.41 after 20 years. It emphasizes the significance of time in growing investments. Next, Sam invests $5,000 at a 10% rate with quarterly and monthly compounding, demonstrating how frequency influences returns. Finally, Megan invests $10,000 at a 6% fixed rate, calculating the time needed for her investment to double using logarithms and the Rule of 72 for approximation. Overall, it highlights the impact of interest rates, compounding frequency, and time on investment growth.

Takeaways

📈 Understanding compound interest is crucial for investing effectively.
💵 Time significantly enhances investment returns through compound interest.
🕒 Doubling time can be estimated using the Rule of 72.
🔍 Wealth accumulation is impacted by how often interest is compounded.
🔢 Logarithms help calculate time needed for investments to grow.
👍 Regularly investing can result in substantial future gains.
💡 More frequent compounding yields greater returns.
💰 Principal amount is the starting investment before interest.
✔️ Realizing the importance of long-term investments is key.
📊 Comparing different compounding methods helps in strategic planning.

Garis waktu

00:00:00 - 00:10:52
Moving forward, Sam invests $5,000 in an account with a 10% annual interest rate, compounded quarterly initially. After calculations, it reveals that the account would grow to $36,047.84 over 20 years. By shifting to a monthly compounding frequency, the amount slightly increases to $36,640.37, demonstrating that more frequent compounding can yield higher returns. Lastly, Megan aims to learn how long it will take for her $10,000 investment at a 6% annual interest rate to double. By applying a logarithmic approach, it is calculated that it will take approximately 11.896 years, aligning closely with the Rule of 72 estimate of 12 years.

Peta Pikiran

Video Tanya Jawab

What is compound interest?
Compound interest is the interest on a loan or deposit calculated based on both the initial principal and the accumulated interest from previous periods.
How is compound interest calculated?
Compound interest can be calculated using the formula A = P(1 + r/n)^(nt), where A is the amount of money accumulated after n years, including interest, P is the principal amount, r is the annual interest rate, n is the number of times interest is compounded per year, and t is the number of years.
What is the Rule of 72?
The Rule of 72 is a formula that estimates the number of years required to double the investment at a fixed annual rate of return by dividing 72 by the annual interest rate.
How does compounding frequency affect investment returns?
The more frequently interest is compounded, the more interest you earn on your investment. For example, quarterly compounding yields more than annual compounding.
How can I estimate the time it takes to double an investment?
You can estimate the doubling time by using the Rule of 72, which states that the time to double is approximately 72 divided by the annual interest rate in percentage.
What does it mean if an account is credited with interest annually?
If an account is credited yearly, it means that the interest is calculated once a year and added to the principal.
What is the importance of time in investing?
Time allows compound interest to accumulate, leading to greater returns. The longer an investment is held, the more significant the growth.
Can logarithms be used in calculating investment growth?
Yes, logarithms can be used to find the time required for an investment to grow to a certain amount when dealing with compound interest.
What does 'n' represent in the compound interest formula?
In the compound interest formula, 'n' represents the number of times interest is compounded per year.
What is meant by principal in investment terms?
Principal refers to the initial amount of money invested or loaned, not including any interest.

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Teks

Gulir Otomatis:

00:00:01
in this video we're going to work on
00:00:02
some problems associated with compound
00:00:04
interest
00:00:05
like this one
00:00:07
luke puts a thousand dollars in an
00:00:09
account
00:00:10
that pays an annual interest of nine
00:00:12
percent
00:00:13
what will be the value of the account
00:00:15
after 10 years
00:00:16
so the formula that we need to use is
00:00:18
this one a
00:00:20
which is the final account value equals
00:00:22
p the principal or the amount that he
00:00:25
invests
00:00:26
times 1 plus r over n
00:00:29
raised to the nt
00:00:31
r is the interest rate as a decimal
00:00:34
n is the number of times
00:00:36
interest is credited to an account on an
00:00:39
annual basis or per year rather
00:00:42
so let's say if
00:00:44
the account is credited with interest
00:00:46
only once per year and is one
00:00:50
if it's compounded quarterly that is if
00:00:52
the account receives interest four times
00:00:54
a year and it's four
00:00:56
if it's compounded weekly if the account
00:00:59
receives interest every week
00:01:02
then n is 52 because there's 52 weeks
00:01:04
per year
00:01:05
so n
00:01:06
is the number of times
00:01:08
the account is credited with interest
00:01:10
per year and t is the time in years
00:01:14
so in this problem the amount invested
00:01:17
is a thousand dollars
00:01:19
the interest rate is nine percent
00:01:21
nine percent as a decimal
00:01:24
is point zero nine to get that value
00:01:27
take nine divided by a hundred
00:01:31
now
00:01:33
how often is interest credited
00:01:36
to this account
00:01:38
well we see that the count pays an
00:01:40
annual interest of nine percent
00:01:42
and there's nothing else to tell us that
00:01:44
it's compounded monthly or weekly
00:01:47
so n is one for this problem
00:01:50
and we want to find the value of the
00:01:51
account ten years later
00:01:54
so a is going to be a thousand
00:01:56
times one plus point zero nine or one
00:01:59
point zero nine
00:02:01
raised to the tenth power
00:02:09
and so this is going to be
00:02:11
two thousand three hundred
00:02:13
sixty seven dollars
00:02:15
and thirty six cents
00:02:17
now let's move on to part b
00:02:19
so what will be the value of the account
00:02:21
after 20 years
00:02:23
the only thing we need to change is the
00:02:24
time from 10 years
00:02:26
to 20 years
00:02:28
so this is going to be a thousand
00:02:31
times 1.09 raised to the 20th power
00:02:39
and the answer
00:02:41
is going to be five thousand
00:02:43
six hundred and four dollars and forty
00:02:45
one cents
00:02:49
so this example really illustrates
00:02:52
how time is important when investing
00:02:56
so let's analyze this
00:02:58
in 10 years
00:03:01
his account went from a thousand to two
00:03:04
thousand three hundred sixty seven
00:03:06
dollars and thirty six cents
00:03:08
so basically
00:03:10
his gain
00:03:12
was
00:03:13
thirteen hundred dollars
00:03:15
1367.36
00:03:18
after 10 years
00:03:22
but when he keeps it for 20 years
00:03:26
his investment multiplies by a factor of
00:03:29
5.6
00:03:32
so his gain
00:03:35
is more than double
00:03:37
it's more than thirteen hundred dollars
00:03:39
in this case it's four thousand
00:03:43
six hundred and four dollars and forty
00:03:44
one cents
00:03:47
so by leaving it for ten years he made
00:03:49
about thirteen hundred dollars
00:03:51
but by leaving it for twenty years he
00:03:53
made forty six hundred dollars
00:03:54
from his investment
00:03:57
so the lesson is simple
00:03:59
the more time that an investment has to
00:04:01
work
00:04:02
the greater the return will be
00:04:05
number two
00:04:07
sam invests 5 000
00:04:09
in an account that pays an annual
00:04:11
interest of 10 percent
00:04:13
the funds are invested for 20 years
00:04:15
what will be the value of the account if
00:04:17
interest is credited to the account on a
00:04:19
quarterly basis
00:04:21
so on a quarterly basis
00:04:23
n is for there's four quarters in a year
00:04:26
each quarter represents three months
00:04:29
so now let's use the same formula
00:04:37
so p the principal or the amount
00:04:39
invested
00:04:40
is thousand
00:04:42
the interest rate is ten percent
00:04:45
ten divided by a hundred is point ten
00:04:49
n is four
00:04:51
and we wanna determine the value of the
00:04:53
account twenty years later
00:05:01
so let's do this one step at a time
00:05:03
0.10
00:05:05
divided by 4
00:05:06
is 0.025
00:05:08
if we add 1 to that we're going to get
00:05:10
1.025
00:05:12
and 4 times 20 is 80.
00:05:16
so it's 5 000 times
00:05:18
1.025 raised to the 80th power
00:05:22
and so the value of the investment
00:05:24
twenty years later will be
00:05:26
thirty six thousand
00:05:29
forty seven dollars
00:05:31
and eighty four cents
00:05:32
so to round it to the nearest set
00:05:36
now let's move on to part b let's see
00:05:38
what's going to happen
00:05:40
if
00:05:41
the account is credited
00:05:43
with interest on a monthly basis
00:05:50
so everything is going to be the same
00:05:51
but we're going to change n
00:05:53
from 4
00:05:55
to 12.
00:06:06
10 divided by 12 is
00:06:08
0.0083 repeating
00:06:10
if we add 1 to that this is going to be
00:06:15
1.0083 repeating
00:06:17
so there's many threes after that and
00:06:19
then 12 times 20
00:06:23
is 240.
00:06:25
so if we type in 5000 times
00:06:28
1.008 333333
00:06:31
raised to the 240th power
00:06:35
we're going to get thirty six thousand
00:06:40
six hundred forty
00:06:43
and thirty seven cents
00:06:45
so notice that
00:06:47
this amount
00:06:48
is about six hundred dollars more
00:06:51
than this amount
00:06:53
so what does this tell us
00:06:56
when interest is credited
00:06:59
to an account more frequently
00:07:01
the return will be slightly more
00:07:04
so in this example when interest is
00:07:05
credited 12 times a year
00:07:08
the amount earned over 20 years is 600
00:07:10
more than if interest is credited four
00:07:14
times a year
00:07:16
now the difference is not that great but
00:07:19
over many years it could be significant
00:07:23
now let's move on to our last problem
00:07:25
megan
00:07:26
invests ten thousand dollars in an
00:07:28
annuity that pays a fixed interest of
00:07:31
six percent on an annual basis
00:07:34
how many years will it take for
00:07:36
investment to double in value
00:07:41
so let's start with this equation once
00:07:44
more
00:07:52
now interest is credited to the account
00:07:54
on an annual basis
00:07:56
so n is 1.
00:07:59
her original investment is 10 000.
00:08:03
we want to find the time it takes for
00:08:05
her to double the investment so we're
00:08:07
looking for t
00:08:10
so when her investment doubles it's
00:08:12
going to be worth twenty thousand
00:08:13
dollars
00:08:15
so let's replace a with twenty thousand
00:08:18
and let's replace p with ten thousand
00:08:22
i'm not going to plug in the value for r
00:08:24
yet
00:08:25
n is one
00:08:28
if we divide both sides by ten thousand
00:08:34
we'll get that two is equal to one plus
00:08:37
r
00:08:38
raised to the t
00:08:41
now what i'm going to do in the next
00:08:42
step is i'm going to take the natural
00:08:44
log
00:08:44
of both sides
00:08:50
a property of logs and natural logs
00:08:52
allows us to move the exponent to the
00:08:54
front
00:08:55
so we're going to get ln 2 is equal to t
00:08:59
times ln
00:09:00
1 plus r
00:09:02
so dividing both sides by ln
00:09:05
1 plus r
00:09:09
we're going to get a formula that tells
00:09:11
us
00:09:12
the time it takes to double
00:09:15
when we receive interest on an annual
00:09:17
basis
00:09:18
and here it is
00:09:19
the time it takes to double is equal to
00:09:21
the natural log of two
00:09:23
divided by the natural log
00:09:25
of one plus r
00:09:36
so now let's plug in r
00:09:38
r is six percent
00:09:40
so that's point zero six as a decimal
00:09:43
so this is going to be the natural log
00:09:45
of two
00:09:46
divided by the natural log
00:09:48
of one point zero six so you could use
00:09:50
log or natural log
00:09:52
both will give you the same answer
00:09:55
so let's type in ln 2 divided by ln
00:09:58
1.06
00:10:00
and the answer is 11.896
00:10:04
years
00:10:06
so that's how long it's going to take
00:10:08
for
00:10:09
megan's investment to double in value
00:10:13
now you can get the answer quickly
00:10:16
or at least an estimate of the answer
00:10:18
using what is known as the rule of 72.
00:10:22
according to the rule of 72 the time it
00:10:24
takes to double is equal to 72
00:10:28
divided by
00:10:29
the interest rate as a percentage not as
00:10:31
a decimal
00:10:33
so we're going to take 72 and divide it
00:10:35
by 6 not by 0.06
00:10:38
72 divided by 6 is 12.
00:10:42
and so we can see that this formula
00:10:44
gives us a good approximation
00:10:46
of the time it takes to double
00:10:48
11.896 years is approximately 12 years