Using a logarithm property to make this equation easier!

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Your ability to change colors quickly doesn't cease to amaze me.

I tried it, but came up with a different method:
x^ln4 + x^ln10 = x^ln25
a = x^ln5 , b = x^ln2
b^2 + ab = a^2
Using Quadratic Formula:
a = b(1 + root5)/2 [since a and b must be the same sign, the other one is ignored]
x^ln5 = x^ln2(phi) [dividing by x^ln2, means x^ln2 must not be 0. So 0 is a Solution. 😅 Didn't realize at first.]
x^ln(5/2) = phi
x = phi^(1/ln(5/2))
Edit: Essentially I found out after watching the video for his solution that phi^(1/(ln(5/2)) = phi^(log(base5/2)(e)) = e^log(base(5/2))(phi). So I got the Answer!!! Woohoo!!

The golden ratio caught me off guard, but the fact that it’s there is amazing

Been a long time since I have seen a math equation and problem that was just genuinely cool. Having phi show up was a real nice surprise.

This was my idea:
x^ln4 + x^ln10 = x^ln25
Leave out the case x=0 and divide both sides by x^ln10. Distributing the denominator and applying properties of the power you get
x^(ln4-ln10) + 1 = x^(ln25 - ln10)
Applying properties of logarithms we get
x^ln(2/5) + 1 = x^ln(5/2)
Substituting z=x^ln(5/2), and noting that ln(2/5)=-ln(5/2) the equation becomes
z^-1 + 1 = z
Which can easily become a quadratic equation and the rest follows in a similar way to what you did.

what i did was move everything to one side and factor x^ln4(x^ln25/4 - x^ln10/4 -- 1) = 0 --> x^ln25/4 is just x^ln10/4 squared so in this case u can let t = x^ln10/4
leading to the quadratic equation t^2 - t - 1 = 0 --> t solves for (1+-sqrt(5) / 2 --> x^ln10/4 = (1+--sqrt(5) / 2 --> take ln() on both sides --> ln10/4*lnx = ln((1+--sqrt(5)/2)) -->
lnx = ln((1+--sqrt(5)/2)) / ln10 --> to solve for x, e^ on both sides to cancel the lnx to get x --> x = e^(ln((1+--sqrt(5)/2)) / ln10) --> x ≈ 1.69

Seems like we're finally back at the golden ratio we all love so much - one BPRP video a week.

2:50 Voodoo

Got it in 2 min buddy!!
You definitely helped me a lot to prepare logarithms for competitions..!
Gratitude from India 🇮🇳

very nice equation and explanation

Answer is nearly equal to 1 + ln(2)

You can also start by dividing everything by x^ln(4) and immediately getting a quadratic of x^ln(5/2). Nice equation.

FINALLY!! A youtube math exercise that I couldn't do in my head. Nice. It brought back some memories of forgotten log properties. Oh, to be a freshman in college again.

Very nice equation. Thanks for your perfect presentation. Great, as always👌your videos are so great!

Wolframalpha couldn't figure out the given exact form solution from the original form, but could when the equation was transformed.

Love it, thanks.

Very good video!👏👏
Anhother way to isolate the X in the last part would be using the NOTE again, and we get X=(phi)^(1/ln(5/2))

I dont understand half of the video but it's still fun to watch

Try to solve this question that I found in a calculus textbook (by James Stewart):
Use a quadruple integral to find the hypervolume enclosed by the hypersphere x^2+y^2+z^2+w^2=r^2 in R4 (I wish I made that up lol)

Great solution development. I never would have thought to approach it that way, because I never thought about the fact a^ln(b) = b^ln(a). I mean, it's obviously true, but not a tool I would have thought to use.

That is a really cool problem and solution.

Love your videos

from Morocco all my respects...thank you for those genious ideas..i shared this video on facebook

Hey! Have there always been a warehouse full of colored markers in your teaching studio? I've watched all your videos and have never noticed that feature.
Either way, nice touch, like all you do.

I gave this baby a try, and was surprised I could get the answer (got an imaginary one as well), but I did this a little differently. I noticed the common factors 4 = 2*2, 10 = 2*5, and 25 = 5*5, so I knew there was some way I could leverage that, so I factored it, and with some playing around I got: x^2 ln 2 + x^ln 5* x^ln 2 - x^2 ln 5 = 0. At this point, I noticed that we had (x^ln 2)^2 in the first term, and x^ln 2 in the second, so used the quadratic formula (solving was interesting but too long for UA-cam comment) to solve for x^ln 2, which gives x^ln 2 = x^ln 5 (-1 +/- sqrt(5))/2. Then, I moved the x^ln 5 to the other side and combine to get x^ln(2/5) = (-1 +/- sqrt(5))/2. Now I just take the weird root of both sides and I get the same answer.

Finally! That is indeed a nice one!!

I first converted all the ln() functions from:
ln(4), ln(10), ln(25)
to
2ln(2), ln(2) + ln(5), 2ln(5)
Then I divided everybody by x^2ln(5), getting:
x^(2ln(2) - 2ln(5))
+ x^(ln(2) + ln(5) - 2ln(5))
=
1
Which becomes:
u^2 + u - 1 = 0,
where u = x^(ln(2) - ln(5)) = x^(ln(2/5))
though my final solution does not look as elegant:
x = ((-1 + √5) / 2) ^ (1 / ln(2/5))
Pretty cool to see how many ways there are of solving this equation!

Nicely done. ❤

As a side note, basically the same approach also works without turning it into an exponential equation, after excluding the solution x=0 just divide the original equation by x^(log 4) on both sides, which gives:
1 + x^log(5/2) = x^log(25/4) = x^(log(5/2) + log(5/2)) = (x^log(5/2))^2
Using substitution u = x^log(5/2) gives 1 + u = u^2, and therefor u = phi. By solving for x we then get the same result

Very cool problem.

You can avoid using fractional bases by reversing the exponent a second time near the end:
x^(ln(5/2)) = phi
So x = phi^(1/ln(5/2)) = 1.691...

I love every video that starts with Let's do some math for fun. Thanks!

I noticed immediately that it would form a quadratic equation when we divide through either of X^ln4 and X^ln25
But I didn't know about the switch of X and the argument of the log functions.
I really love your videos thanks so much.

wonderful!

For the first time in a while I impressed myself. I looked at the exponent, told myself, 4=2*2, 25=5*5 and 10=2*5 that would be nice to divide either by 4 to have a 5/2 and (5/2)**2 appear. Then I looked at the signs in front of the coefficient and I said to myself : I don’t know how but there is the golden ratio hidden in this equation.

This equation may be solved without using the transformation: x^ln(a) = a^ln(x) however, it makes it more convenient. Very interesting clip and nice explanation.

This guy is always sponsored by brilliant. He probably has a free course by now from them 😂
I love learning from him. He’s the whole reason I was so interested in integrals

Thanks

Can we just acknowledge the shear number of markers in the bottom right bro be spending 25 hours a day on math to use them up

wow that's cool

I love how you are able to bring golden ratio everywhere!

Awesome! For the solution, why is e^log(base 5/2)(phi) preferable to phi^(1/(log(5/2)), or phi^log(base 5/2)(e)? ❤

Very good. Cheguei nessa resposta equivalente: [ (sqrt(5-1)/2 ] ^ (1 / ln(2/5) ).

Thankyou sir,this is goos way.

you are the best

You can write x^ln4=x^ln(2*2)=x^(ln2+ln2)=x^ln2*x^ln2. Doing soemthing similar for the other terms one finds: x^ln2*x^ln2+x^ln2*x^ln5=x^ln5*x^ln5
Dividing everything by ln2*ln5
x^ln2/x^ln5 + 1 = x^ln5/x^ln2
Define a=x^ln2/x^ln5
Then
a+1=1/a
Which yields a=phi
Then x=phi^(ln5/ln2)=phi^ln(5/2)
Which is what you got expressed differently

brilliant!

Difference of two squares and then divide each factor by x^(ln2) giving 2=x^(ln5)

With a different procedure I also found two complex conjugate solutions approximately x=-0.567 ± 0.167·i

nice and very easy

when i first saw the question in the thumbnail I thought of relating it to the technique of solving integrals by using log there I used the same way
x^ln(4)+x^ln(10)=x^ln(25)
taking log on both sides
lnx^ln(4)+lnx^ln(10)=lnx^ln(25)
by ln property lnx^a = a ln x
ln(4)*ln x+ln(10)*ln x=ln(25)*ln x
canceling out ln x from both sides....we get
ln(4)+ln(10)=ln(25)
and after reaching here I was like what do we have to find in this in the first place!!🥲

So I looked at the nonzero solution to x^(ln(9)) + x^(ln(12)) = x^(ln(16)) and noticed the solution was e^(log base 4/3 (phi)). So this leads to the idea that maybe for positive values a and b the nonzero solution to x^(ln(a^2)) + x^(ln(ab)) = x^(ln(b^2)) is e^(logbase b/a (phi)). I'm going to work this out to see if it is true.

the first transformation isn't material. you can just divide by x^log(25) and simplify: x^(2log(2/5))+x(log(2/5))=1 and you're on the same line.

I tried to do it in another way by manipulating around the powers but only got to 0, how do I know if an equation like this one has more than 1 solution ? and is there a methodology I could follow to find these solutions? or do I just have to study extremely hard maths to become able to find them

Blackpenredpen just casually fit the golden ratio and 69 in one equation

this is brilliant.

I solved it using only power properties, but I got phi^ln(2/5), but then realized that, doing some additional operations, I got the same result as in the video.

Nice equation❤

You switch colors just as smoothly as you switch log bases 😄. And that stock of pens in corner..😄

I like the stash of markers

How did you know to do the step at 5:47 where you set one side equal to the quadratic formula value

I saw the thumbnail and tried solving it myself, And I got the answer (5/2)√[(1+√5)/2] as X.

I used the same property but then used graphs to find the no of soln

Please try to integrate 1/x^5+1

I got ((1+sqr5)/2)^(1/ln(5/2)), so basically the same thing :D

Can u help solve Integral of 1/(Square root of x(to the power 3)+x)

Always the same trick with those:
divide the 2 sides by smth clever so you end up with a ratio and its inverse.
The 1st step is to decompose the exponents with the ln rules
ln4=ln2+ln2, etc...
Divide both sides of the equation by x^ln2*x^ln5, and you get to 1/X+1=X with X =x^ln2.5
X = phi (well known golden ratio), the negative root is rejected given X>0
x = Exp(lnPhi / ln(2.5))
year 11 stuff.

Starting with: x^(ln 4) + x^(ln 10) = x^(ln 25)
Divide both sides by the RHS: x^(ln 4) / x^(ln 25) + x^(ln 10) / x^(ln 25) = 1
Use law of indices: x^(ln 4 - ln 25) + x^(ln 10 - ln 25) = 1
Use law of logs: x^(ln 4/25) + x^(ln 10/25) = 1
Form a quadratic: (x^(ln 2/5))^2 + x^(ln 2/5) - 1 = 0
Solve quadratic: x^(ln 2/5) = (-1 +/- sqrt(5)) / 2
Since powers are always positive, choose + solution only: x^(ln 2/5) = (-1 + sqrt 5) / 2
Therefore x = ((-1 + sqrt 5) / 2)^(1 / ln 2/5)
= 1.69075...
Getting my answer to match the form in the video was the hardest part!
let phi = (1 + sqrt 5) / 2, then 1/phi = (-1 + sqrt 5) / 2
Then x = (1/phi)^(1 / ln 2/5)
x = phi^(-1 / ln 2/5)
x = phi^(1 / ln 5/2)
x = phi^(ln e / ln 5/2)
x = e^(ln e / ln 5/2 * ln phi)
x = e^(ln phi / ln 5/2 * ln e)
x = e^(log_{5/2}(phi) * ln e)
x = e^(log_{5/2)(phi))

x^(ln 2 + ln 2) + x^(ln 2 + ln 5) == x^(ln5+ln5)
divide by x^(ln2+ln5):
x^(ln2)/x^(ln5)+1==x^(ln5-ln2)
substitute:
t=x^(ln5)/x^(ln2)
t^2-t-1==0
following steps are same

The "equation of the year" definition reminds me when I participated to the local math contest which I participated when I was 12

That's a lot of pens you got there

x=e^a, 4^a + 10^a = 25^a
s=2^a, t=5^a
s^2+st-t^2=0
Hmmm, can solve s as a function of t or vice versa as a quadratic, maybe the equation is solvable for a when you substitute back. Perhaps a log or W function will show up later if the problem is nice enough to allow it.

If THIS doesn't smell like a hidden quadratic.
Later Edit: And it was. And I haven't even seen the video yet.

Beautiful

I was thinking of x=phi^(1/ln2.5). Is there a preferable method of writing it down? And if so, why?

I got (phi-1)^(1/(ln(2/5))), which is same.

Solution:
x^ln4 + x^ln10 = x^ln25
x^(2ln2) + x^(ln2+ln5) = x^(2ln5)
(x^ln2)² + x^ln2 * x^ln5 = (x^ln5)² |-(x^ln5)²
(x^ln2)² + x^ln2 * x^ln5 - (x^ln5)² = 0
Substitution
u = x^ln2
v = x^ln5
u² + vu - v² = 0
u = -v/2 ± √((v/2)² - (-v²))
u = -v/2 ± √(v²/4 + 4v²/4)
u = -v/2 ± √(5v²/4)
u = -v/2 ± √5 * v/2
u = v * (-1 ± √5)/2
Resubstitution
x^ln2 = x^ln5 * (-1 ± √5)/2 |ln
ln2 * lnx = ln5 * lnx + ln((-1 ± √5)/2) |-(ln5 * lnx)
ln2 * lnx - ln5 * lnx = ln((-1 ± √5)/2)
lnx * (ln2 - ln5) = ln((-1 ± √5)/2) |:(ln2 - ln5)
lnx = ln((-1 ± √5)/2) / (ln2 - ln5) |e → e^(lna/b) = a^(1/b)
x = ((-1 ± √5)/2)^(1/ (ln2 - ln5))
x₁ ≅ 1.69075...
x₂ ≅ -0.567... + i * 0.167...
Curious, that x = 0 doesn't come up as a result, even though it is clearly a valid solution

What's cool is that e≈5/2, so the log with base 5/2 is approximately ln, so the solution is approximately the golden ratio.

i tried solving it on my own and got spooked by the golden ratio jumpscare

Nice

Can you please help me with this question sir, x^2=y^2 by taking square root we have
√x^2=√y^2
|x|=|y| what is the next step sir

I believe you can tidy this up a bit by using the change of basis formula of the logarithm. As in:
log(φ,5/2)=ln(φ)/ln(5/2)
Thus, x=[exp(ln(φ))]^(1/ln(5/2))
x=φ^(1/ln(5/2))
Edit: Your solution might actually be prettier lol.

Whenever (•)² = (•) + 1 appears, always expect ±φ^(±1).

That's just brilliant! Literaly lol

x=[(√5+1)/2]^(1/ln5/2)=1,69075

i love math of course

genial

Wait, but why is the golden ratio (1 + sqrt(5)) / 2? that's such a random number!

Im in 9th grade, and it's funny how i understood some of it. That's why because he explained in a way that my sped mind could even understand. And today, i thought myself the Pythagorean Theorem

If we want to find all the real solutions, we have to check negative numbers as well, but ln x has no real solution if x is negative, so using this way cannot give us negative solutions. My question: is there a way to prove that this equation has no negative solutions or is there a condition for x being positive? Thanks!

x is also equal to 1 if you want another trivial solution. Otherwise it's 1.69075256401782556972357870922404325917589445848038.

does anyone know the promo code (if there's any) for his merch?

Can x be equal to 1 as well?

Hey, I did it!

If bro starts yapping about logarithms again, I'm going to sle

Why was the complex solution ignored?

yerr

Doesn't your first step exclude complex solutions?

Why don't you upload videos frequently?