At 1:21, can't we just raise 1 and r to the power of t? that would mean: 1+r^t=A/P (Since 1^anything = 1) therefore: r^t=(A/P) - 1 giving: r=((A/P)-1) Just a question. I may be wrong but I think I need some clarification here.

you know the formula for (a+b)^2,,,right It contains a 2ab term similarly ,a cubic equation contains a 3ab(a+b) term Therefore,it's reasonable to infer that anything to the power of t would not contain isolated exponential sum of the individual terms. Hope it helps :)

At 1;20, why do you need to raise t to the 1 over t power?

Great question! Sal is using a common method to simplify radical expressions. For example, if you have *x^3 = 27*, then you can take the cube root of both sides of the equation to solve for x. If you have learned about fractional exponents, remember that taking the cube root of something is the same as raising it to the (1/3) power. Similarly, taking the square root of something is the same as raising it to the (1/2) power. So, to cancel out the *t* power, Sal is raising both sides of the equation to the *(1/t)* power.

Isn't one raised to any power 1? So why couldn't the answer be c?

Interesting question, Devonique! You are correct that 1^(1/t) would be 1, but remember that (x-y)^2 *does not* equal x^2 - y^2. So, if you were write out choice C and multiply it out using the FOIL technique, you would have a messy middle term – the equivalent of the -2xy term in my quadratic example. So, choices C and D are not equivalent. To prove this further, you could *plug in some values for A, P, and t* and see if r comes out differently for each choice.

my teachers taught me a whole different way to do the problem dealing with isolating quantities harder example. can someone please confirm what the recommended way to do this is?

Well, what way did your teacher teach you? Just use the one you're comfortable with.

Main content

Course: Digital SAT Math > Unit 12

Lesson 6: Isolating quantities: advanced

Isolating quantities — Harder example

Name: Isolating quantities — Harder example
Uploaded: 2015-04-17T16:48:45Z
Description: Watch Sal work through a harder Isolating quantities problem.

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Watch Sal work through a harder Isolating quantities problem.

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Siddak Ahuja
Posted 8 years ago. Direct link to Siddak Ahuja's post “At 1:21, can't we just ra...”
At
1:21
, can't we just raise 1 and r to the power of t?
that would mean:
1+r^t=A/P (Since 1^anything = 1)
therefore:
r^t=(A/P) - 1
giving:
r=((A/P)-1)

Just a question. I may be wrong but I think I need some clarification here.
Button navigates to signup pageComment on Siddak Ahuja's post “At 1:21, can't we just ra...”
(14 votes)
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- Aditya Tandon
  Posted 8 years ago. Direct link to Aditya Tandon's post “you know the formula for ...”
  you know the formula for (a+b)^2,,,right
  It contains a 2ab term
  similarly ,a cubic equation contains a 3ab(a+b) term
  Therefore,it's reasonable to infer that anything to the power of t would not contain isolated exponential sum of the individual terms.
  Hope it helps :)
  Button navigates to signup page
  (15 votes)
ganglorem
Posted 8 months ago. Direct link to ganglorem's post “tbh, i like this kinda is...”
tbh, i like this kinda isolating quantities problems. <3
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(19 votes)
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ganglorem
Posted 8 months ago. Direct link to ganglorem's post “Hi all, wish you guys luc...”
Hi all, wish you guys luck.
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(15 votes)
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ugoachane
Posted 8 years ago. Direct link to ugoachane's post “At 1;20, why do you need ...”
At 1;20, why do you need to raise t to the 1 over t power?
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(5 votes)
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- Dave Travis (Khan Academy)
  Posted 7 years ago. Direct link to Dave Travis (Khan Academy)'s post “Great question! Sal is us...”
  From the author:Great question! Sal is using a common method to simplify radical expressions. For example, if you have x^3 = 27, then you can take the cube root of both sides of the equation to solve for x. If you have learned about fractional exponents, remember that taking the cube root of something is the same as raising it to the (1/3) power. Similarly, taking the square root of something is the same as raising it to the (1/2) power. So, to cancel out the t power, Sal is raising both sides of the equation to the *(1/t)* power.
  Comment on Dave Travis (Khan Academy)'s post “Great question! Sal is us...”
  (18 votes)
MrAnnonymous
Posted 8 months ago. Direct link to MrAnnonymous's post “anyone who has sat on nov”
anyone who has sat on nov
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(7 votes)
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aiyawork2
Posted 8 months ago. Direct link to aiyawork2's post “These are so fun lowkey”
These are so fun lowkey
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(5 votes)
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gracedesimone
Posted 6 years ago. Direct link to gracedesimone's post “any other videos explaini...”
any other videos explaining this type of math? I have no idea whats going on
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Andrew Thummel
Posted 6 years ago. Direct link to Andrew Thummel's post “my teachers taught me a w...”
my teachers taught me a whole different way to do the problem dealing with isolating quantities harder example. can someone please confirm what the recommended way to do this is?
Button navigates to signup pageComment on Andrew Thummel's post “my teachers taught me a w...”
(2 votes)
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- David Lee
  Posted 6 years ago. Direct link to David Lee's post “Well, what way did your t...”
  Well, what way did your teacher teach you? Just use the one you're comfortable with.
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  (6 votes)
Devonique Weir
Posted 7 years ago. Direct link to Devonique Weir's post “Isn't one raised to any p...”
Isn't one raised to any power 1? So why couldn't the answer be c?
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(3 votes)
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- Dave Travis (Khan Academy)
  Posted 7 years ago. Direct link to Dave Travis (Khan Academy)'s post “Interesting question, Dev...”
  From the author:Interesting question, Devonique! You are correct that 1^(1/t) would be 1, but remember that (x-y)^2 does not equal x^2 - y^2. So, if you were write out choice C and multiply it out using the FOIL technique, you would have a messy middle term – the equivalent of the -2xy term in my quadratic example. So, choices C and D are not equivalent. To prove this further, you could plug in some values for A, P, and t and see if r comes out differently for each choice.
  Comment on Dave Travis (Khan Academy)'s post “Interesting question, Dev...”
  (3 votes)
ashleyb
Posted 3 years ago. Direct link to ashleyb's post “Has Sal ever talked to an...”
Has Sal ever talked to anyone in the questions or comments?
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Video transcript

- [Instructor] If an initial investment, P, bears interest at a rate r, so this initial investment P, bears interest at a rate R, and is compounded annually, its future value A, after t years, can be determined with the equation above. Which of the following equations shows the interest rate in terms of the future value, initial investment, and number of years invested? So they really just want us to solve for r. So let's see if we can do that. So we have the future value, gonna give myself some space. Future value is equal, I'm just rewriting it, is equal to the initial investment times one plus our interest rate, and then that quantity to the t power. So let's see what we can do. So the first thing I could do is I can get the P onto the left-hand side by dividing both sides of this equation by our initial investment. So if I do that, I get, and actually, let me, let me swap the sides, too. Then I get one plus r to the t power is equal to our future value divided by our initial investment. Now, how do I get rid of this to the t power here? Well, I can raise both sides to the one over t power. So I could raise that to the one over t power. One over t. By doing the left side, I have to do it to the right side, as well. So on the left-hand side, if I raise something to the t and then I raise it to the one over t, remember, if you raise something to an exponent and then raise it to another exponent, you're raising it to the product of these two exponents. So this is equivalent to raising one, this is equivalent to just raising one plus r to the first power, or this is just going to simplify to one plus r on the left-hand side. And on the right-hand side, we're gonna have our future value divided by our initial investment to the one over t power. And now, pretty straightforward. You wanna solve for r, subtract one from both sides. We get r is equal to our future value divided by our initial investment to the one over t power minus one. And that is this choice right over there.