exact value of sin(10 degrees)

13:00 for that we can use the polar form of each numbers. For the first, we get e^(2*i*pi/3), then we divide by 3 the exponent (because of the cube root).
So at the end we get 1/2(e^(2i*pi/9)+e^(-2*i*pi/9))
Then we can use the trig form and we see that the imaginary parts cancels: (cos(2pi/9)+isin(2pi/9)+cos(2pi/9)-isin(2pi/9))=2cos(2pi/9)
Then we multiply by 1/2 and we get cos(2pi/9)≈0.766
In degrees, it gives us cos(40°) which is indeed sin(50°) using trig identity, like in the video

Man, the people who discovered this stuff without the use of calculators to sanity check what they were doing... hats off.

Finally, we can write out the value in roots of sin(1°), which we could then use to get the sine of any integer (despite lengthy expansions.

I really enjoy when you keep things real and show the struggles you had to reach the result and not only the cleaned-up result. As a math teacher I relate and get a better appreciation of your video. 谢谢

In Cardano's formula if complex number show up it is not possible to get an answer than involves only reals and radicals.

I've always had troubles with the cubic formula, and I believe it's all because weird stuff goes on with branch cuts when you have to take a sum of two nonreal cube roots. You'd have to go back to the derivation of the formula, and make sure everything is defined over a branch cut C^3 -> C so that you make sure you equate the compatible cube roots. It all feels very messy and fiddly and I don't want to be the one who has to delve into it.

Well, I love this
I think your next video is to finally get the exact value of sin1° that is mixed with pythagorean theorem, your special special right triangle of 15-75-90, 18-72-90, 3-87-90
Then you will prove cardano's cubic formula, the trigonometric identities and more

I’m finally far enough in my trig that, I was actually able to jump ahead of blackpen and derive the equation myself and then check my solution, just needed a push in the right direction. Well done Blackpen🤝

We could have just used euler form and demoivre's theorem

You can reach a formula that always works this way:
You can begin using Euler’s formula and say that:
Sin(x/3)=(1/2i)(e^(ix/3)- e^(-ix/3))
Next, you can just say that e^(ix/3)= cuberoot( cosx + isinx), and the same can be done to e^(-ix/3).
This gives us the formula: Sin(x/3)=(1/2i)(cuberoot( cosx + isinx)- cuberoot( cosx - isinx))
This formula only works for x less than pi but greater than 0.
If you want a formula for x less than 2pi but greater than pi, you should multiply the first term in the formula by w1, and multiply the second term by w2, where w1, and w2, are the complex cubic roots of unity. So we get the formula:
Sin(x/3)=(1/2i)((-1/2+√3/2 i)cuberoot( cosx + isinx)- (-1/2-√3/2 i)cuberoot( cosx - isinx))
If you want me to explain why these formulas always work, feel free to reach out to me as it would be hard to explain here in the comment section. It has something to do with the rotations in the complex plane.

Excellent. Thanks very much ! 🙂

A basic difficulty I have about this is:
y=x^3+px+q has constant p and q. But here we have q=q(x). Typically we're trying to find the roots of a fixed polynomial. We vary the x and get the y value along a specific curve, and we're looking for where y=0. Here, as we vary x, the whole curve changes because q=q(x).
Or in terms of 2nd order poly.:
y=Ax^2+Bx+C(x). We could just use the quadratic formula, and get a result, but thinking about what exactly we are doing is a bit confusing. Could even consider 1st order: y=ax+b. Root formula would be x=-b/a. Now we try it with y=ax+b(x), and use the same formula, so x= -b(x)/a. I'll have to think about this a bit more.
Any comments?
Thanks

I’m not sure how correct I am, but i read on a wikipedia page that unfortunately according to Galois theory, for cubic equations with all 3 roots being real irrational numbers, the roots cannot be expressed with a finite radical expression using only real numbers.
So unfortunately, we can’t write sin(10 degree) in a finite radical expression without the i.
If someone could fact check me, that would bemuch appreciated

always knew a video like this was coming

Do you go from sin(50°) to sin(-70°) and then to sin(-190°)=sin(10°) by utilizing the cube roots of 1 because those cube roots are 120° apart?

Good writing sir❤❤❤

This is nice,but at the end what you get is cos80=sin10 .the formula you get at the end after simlifying is :0.5(e^(4pi/9)i+e^-(4pi/9)i) which is cos(4pi/9)=cos80=sin10,so there is nothing special here,but the way you got it was nice

this is a lot of formulae . It's better if you use euler's formula and some rearangements ; like expressing sine of x|3 as -i ×half of e^ix|3 - e^ix|3
then writing i as e^pi|2, -i as e^-pi|2. This reduces to your obtained answer.

Since the roots of a polynomial are not sorted and are algebraicaly indistinguishable, I claim there is no way to know what is the correct root for a given angle in advance. But you can have a set of solutions called red, blue, and black, which is kind of better.

If you want to take the cube root of those imaginary numbers, you’re going to have to use DeMoivre’s Theorem. It states the following:
For any number a+bi, it can be represented in the form r(cos(a) + isin(a)) or rcis(a). Additionally, for any complex number in this form that has a power applied to it,
(r*cis(a))^n = r^n * cis(n*a).
For example, if we are to take the fourth root of 1, we know that 1 equals 1(cos(0) + i*sin(0)), or cis(0). Keeping in mind that we can rotate this angle 360 degrees, we can represent 1 as cis(0), cis(360), cis(720), and cis(1080) (you’ll see why we do this in a second). Because we take 1 to the one fourth, or 0.25th power, that means:
1^0.25
= (cis(0))^0.25
= cis(0*0.25)
= cis(0)
= 1
We can also repeat this for the other reference angles:
(cis(360))^0.25
= cis(360*0.25)
= cis(90)
= i
For cis(720), the same process results in cis(180), or -1, and for cis(1080), this results in cis(270), or -i.
As such, we can get that the fourth roots of one are 1, i, -1, and -i.
Hope this helps!

Those two complex numbers you wrote in your expression for sin 10° have magnitude 1, so you might try writing them in polar form and dividing their arguments by 3.

This is very similar to a Hong Kong 2007 grade 13 A-level mathematics problem. I regret I had arithmetic panic that time and I didn't score this. The whole paper is damn easy

Congrats on 1000000ln3 subs🎉🎉🎉

Interesting results :)

I love math.Thank you sir... ❤❤

8x³-6x+1=0
Where x=sin(10)
This equation also have the same three roots
We can also get approximate value by
(10×π)÷180

I literally plug sin(x/3) in the calculator earlier
This help me a lot

You can use de movies theorem to find the formula for sin(x/3) much faster, and for the final bit you can use polar exponent form. I know you didn’t want to go into complex too much because that restricts the viewers who understand it and you’d have to teach them an entire new subject which is fair.

He just weaves in all conpcept in so easily
It seems every sentence is just a revision of a topic

11:16 you could prob put the terms inside the radicals in terms of cis to simplify the radicals

Math is so beautiful and helpful in our life.❤️❤️❤️

Keep it up bro, What's the best books to learn advanced mathematics after graduating high school?

I was wondering if you could do this problem sometime. This is a very interesting problem, and I can't get the proof anywhere.
Prove that a^x = log (base a) x (a

Very interesting. I think one problem could be that at around 9:40 you say sqrt(-cos^2 x) is i*cos x. That's not correct; you are missing abs(...). sqrt(-cos^2 x) is +-i*abs(cos x). In the situation you are calculating that it makes no difference because there is +- in front. However, later at 10:38 it makes a difference.

Another method to evaluate the complex sued is by assuming it to be u
Then u^3 = -1 + 3(cbrt(-1/2 + iroot 3/2)(cbrt(-1/2 -root3/2)u
U^3 = -1 + 3(1)u
So this becomes a polynomial that is p(x) = u^3 -3u +1
Then again applying cardanos formula for depressed cubics you can get an answer
@blackpenredpen
I just checked with wolfram alpha
I got an 3 real roots and when you divide one of the answers namely 0.3470 by 2 in the original formula you get 0.1735 which is very close to sin 10 degrees

Interesting and very well done. Thank you for this!

This works from 0 to π:
sqrt(1 - (1/2 (1/(cos(x) + sqrt(-1 + cos^2(x)))^(1/3) + (cos(x) + sqrt(-1 + cos^2(x)))^(1/3)))^2)
And this works from π/2 to 2π + π/2:
1/(2 (-sin(x) + sqrt(-cos^2(x)))^(1/3)) + 1/2 (-sin(x) + sqrt(-cos^2(x)))^(1/3)

13:00 you can set the expression in parenthesis to x and then ''cube both sides'' similiar to this vid: czcams.com/video/5pa1AryylpM/video.html
You can then substitute x to get a cubic equation with real coefficients. However it seems like it will have 3 roots, probably because we cubed both sides. Which root is the correct answer? I dunno

I can just use the power series of sin to get a decimal approximation. I was hoping this would end with some sort of real closed-form radical expression. (knowing my luck, if i tried to manipulate the imaginaries in the radicals with polar forms and such, i'd end up with sin (10) = sin (10) )

14:00 it is because you forgot the 1/64 perviously. + to check it the number is real simply check if it is equals to its cojuge aka replacement every "i" with "-i"

Hi Blackpenredpen. Make a video demonstrating why π is irrational. I am subscribed to your channel, very good videos. Greetings from Mexico

I have been watching your videos since I was about 13. Now I am 16 and I can gladly say that I can understand almost all of your videos. (Some of them still confuse me, but just wait another year!!!)

once you have the sinx+icosx under roots, can you use euler identity to simplfy it further?

While trying to simplify the complex solution. I got cos(2pi/9) in the way and it is interesting that it is equal to exactly sin50 degrees

What is the alternative solution of the strend problem solved by ramanujan?

"Can we tell which solution will give sin(10°)?"
I may have an answer to your question.
When solving for cos(θ/3) we have
x_j = [cos(2πj/3 + θ/3) + i sin(2πj/3 + θ/3) + cos(-2πj/3 - θ/3) + i sin(-2πj/3 - θ/3)]/2, j = 0, 1, 2
When j = 0 we get x_0 = [cos(θ/3) + cos(-θ/3)]/2 = cos(θ/3).
So, when solving for cos(θ/3) use the first root corresponding to j = 0.
But, when solving for sin(θ/3) things are a bit more complicated...
x_j = [cos(2πj/3 + γ/3) + i sin(2πj/3 + γ/3) + cos(-2πj/3 - γ/3) + i sin(-2πj/3 - γ/3)]/2, j = 0, 1, 2 where γ = θ + π/2. Then, after combining terms, substitute θ + π/2 back for γ and set j = 2 to get
x_2 = [cos(3π/2 + θ/3) + cos(-3π/2 - θ/3)]/2 = sin(θ/3)!
In summary when solving for cos(θ/3) set j = 0 and when solving for sin(θ/3) initially replace θ with γ - π/2 and set j = 2. Then replace γ back with θ + π/2 and simplify.
So, similar to what you observed, solving for cos(θ/3) requires the first root (j = 0) and solving for sin(θ/3) requires the third root (j = 2).

I was just about to tell you to use cube root of unity, but then you figured it out yourself

Sorry for asking an unrelated question.
There is a statement "For complex numbers, square roots can only accept principal values as output."
Is that statement true?
Example: √-1 = i, but not -i, while i² = (-i)² = -1
If yes, some of your previous video may have wrong answers!

It is impossible to write an expression for a non-multiple of 3 degrees for sine without having a cube root of a complex number (or worse). By the way, here are some expressions for sine of non-multiple of 3 degrees that I find interesting. Note that you can copy and paste them into Wolfram Alpha in order to visualize them (and verify that they work). You have to be careful when taking the cube root of a complex number below. Choose the "principal value" (since there are 3 possibilities, but only one fits the conventional definition for principal value). I avoid writing "i" to make the syntax more universal for computer entry. Also, sind() is the sine degrees function.
First the simplified version of what was derived in the video:
sind(10)= sqrt(2-(1/2+sqrt(-3)/2)^(1/3)-(1/2-sqrt(-3)/2)^(1/3))/2
Now here is an alternative form that only has one cube-root in it:
sind(10)= 1/sqrt(1-(1-4/(2-( 4+sqrt(-48))^(1/3)))^2)
And finally, the holy grail, for 1 degree:
sind( 1)= 1/sqrt(1-(1-16/(8-(4+sqrt(-48))^(1/3)*(sqrt(-1)-sqrt(-5)+sqrt(10+sqrt(20)))))^2)

This is me every other class but math 😂

bro really cube rooted the cube root of unity at some point

Just substitute. a fot the first radical and b for the second one. Then the product ab would be the cubic root of the product of conjugated which is real. Then a^3 +b^3 would be the sum of conjugates which is also real. Those two quantities will generate a cubic equation of a+b which has real roots. I suggest using a numerical method to solve as opposed to cubic formula.

w0 works for the range 90-180, w2 for the range 0-180. I have a code in R plotting all the options. I will post the code if there is interest.

-sinx+icosx=(-i)(cosx+isinx)=-ie^ix
-sinx-icosx=(i)(cosx-isinx)=ie^-ix
Cube root of i=
-i, root(3)/2+/-(i/2)
Cube root of -i=
i, -root(3)/2+/-(i/2)
Wait... I'm going to get back to the polar form expression for sin. This doesn't help you go further... but it does give you an alternate route to prove the same expression. Maybe exploring it will help you understand which form to use.

being a cube root it has 3 solutions for each cubic where 2 of the solutions are sin(10) = 1/2 [ cos(80) + i sin(80) + cos(80) + i sin(-80) ] which simplifies to cos(80) and cos (-80) so it is a long way of proving sin(10) = cos(90 - 10) and sin(10) = cos(10 - 90) surprising the other solutions that produce real solution are cos (40), cos(-40), cos(160), cos(-160)

This man is mathing which we cant even math about mathematics

I'll ask you a question
What is -ln(-1) =?
A . iπ
B . -iπ
C. A ans B both
D. Can't possible
E. None of the above
I am not testing you but by watching just your videos i got that question in my mind

This cubic equation has three roots, which would be [e^(i2π/9) + e^(-i2π/9)]/2, [e^(i8π/9) + e^(-i8π/9)]/2, and [e^(i14π/9) + e^(-i14π/9)]/2. The third of these roots gives cos(280°) = sin(10°) Before taking the cube roots we have e^[±i(2π/3 + 2πj)], j = 0, 1, 2. The three roots above come from e^[±i(2π/3 + 2πj)/3], j = 0, 1, 2.

Hi!
I made up a function that is almost perfectly equal to e^(-x^2), hoping for that we'll be able to come up with an elementary integral function for it.
The function is 9/(7+2,8^(2,8x)+2,8^(-2,8x)), I created it using the reciprocal of cosh(x).
How should I go on to make it more (or perfectly) equal?

Please could u do a video on why sin(54 degrees) = φ/2 , where φ is the golden ratio? I feel like this is a result not many people know about. Thank you!

His name should be written Guinness world record for the fastest pen changing

You should have pointed out that sin 50 = sin 130 and -sin 70 = sin 250. The three values you calculated are for angles all 120 degrees apart. 10, 130 and 250 degrees.

Exact expression for sin(10):
Use: cos(80) = sin(10)
Use: half angle formula for cos: cos(A/2) = +/- sqrt((1 + cos(A))/2).
Set x = 2/A, multiply by 2, assume 0

There's a nice way of getting there by looking at the properties of the 80:80:20deg isosceles triangle: if the short (unequal side) has unit length, then the two equal sides have length 3-x^2, satisfying the equation 3-x^2=1/x. sin 10 is then given as x/2. Unfortunately you still get a cubic equation to solve to find x, and it's still not immediately obvious from the solutions that x is real.
I wanted to post a picture to show this but I don't know how to; so I'll have to describe the construction: if you bear with me, once you've done the construction it's very nice ...
Construct triangle ABC with angle 20 at A and the other two angles 80; choose BC to be unit length. All construction lines are inside ABC: first draw a line B at 20 deg to BC; this meets AC at D; let x be the length BC; now draw a line from D at 60 deg to BD; this meets AB at E; now draw a line from E at 100 deg from BE meeting AC at F; finally draw two lines from F, one at 60 deg to EF meeting AB at G, the other at 80 degrees to EF meeting AB at H. You should now be able to satisfy yourself that triangle BDE is equilateral and triangles ABC, FGH, BCD, AGF and EFH are similar isosceles triangles, with the last three congruent. Since additionally DEF is isosceles, BD, BE, DE, EF, AF, AG, EF and EH are the same unit length as BC, and because BCD, AFD and EFH are congruent, FG and FH are the same length as BC, namely x, and the similarity of FGH to this triangle allows us to deduce GH is x^2. Finally the similarity between BCD and ABC gives the result 3-x^2=1/x ==> x^3 - 3x +1 = 0, with sin 10 = x/2

Interesting that this is an algebraic number. Can we say when this is the case and when sin(x) is transcendental?

Can you teach me all maths that you have ever learned, watching videos and learning is great, but physical tuitions will be next level

The final solutions can be changed into hyperbolic functions sinh (ix) = i sin (x), cosh (ix) = cos (x) to verify your answer , probably without the use of calculator.

my approach was to look at those two radicals in polar form, and realize that each has three roots in the complex plane, all equal in magnitude but splayed out 120 degrees from one another.
the magnitude of the quantity in each radical is 1, so you just have to determine the three phase angles.
for the first radical, the possible phase angles are 2pi/9, 8pi/9, and 14pi/9. (roughly 40, 160, and 280 degrees if you prefer thinking in degrees)
for the second radical, the possible phase angles are 4pi/9, 10pi/9, and 16pi/9. (roughly 80, 200, and 320 degrees)
If you draw these in the complex plane, you'll see that each triad is splayed out 120 degrees (2pi/3) about the origin.
Then, you need to add these two values. Consider all possible combinations of the three, and figure out which ones have wholly real-valued sums.
This is easy, just pick off the ones in "group 1" and "group 2" which have equal and opposite imaginary values.
There are three possible additions which result in a real-valued result:
(1) 2pi/9 from the first radical with 16pi/9 from the second radical.
(2) 14pi/9 from the first radical with 4pi/9 from the second radical.
(3) 8pi/9 from the first radical with 10pi/9 from the second radical.
Each of these pairs has equal and opposite imaginary components, so all you have to do is add the real components. It turns out that in each pair, the real values are identical, so you pick one and double it. And then as the last step you multiply by 1/2 to complete the expression from the video.
combination (1) gives you sin(50). (coming from sin(150) in the 1/3-angle formula)
combination (2) gives you sin(10). (coming from sin(30) in the 1/3-angle formula)
combination (3) gives you sin(70). (coming from sin(210) in the 1/3-angle formula)
The problem with Wolfram is that it arbitrarily chooses one of the three roots and discards the others. Apparently, the roots chosen correspond to combination (1), which is why you got the result for 50 degrees.
In this case, combination (2) is the one you want.
(my final quandary was that there are FOUR angles which have sines of +-1/2: 30, 150, 210, and 330 degrees. The first three are represented in the combinations above, but I couldn't find a combination corresponding to 330 degrees. That, in turn, would give us sin(110) when put through the 1/3-angle formula. However, sin(110) = sin(70) so that simply collapses into combination (3) above). This continues: sin(390) degrees is also equal to 1/2, and plugging that into the 1/3-angle formula would give you sin(130), but that's the same as sin(50), so it collapses into combination (1). And sin(360+150) = sin(510) = 1/2, which would give sin(170) after dividing the angle by 3, but that's exactly the same as sin(10) which corresponds to combination (2). This continues forever....)

..working on it from time to time..
not there yet with a common usable formula
...so faar the function is off by +2.7 degres at 'sin(10)' degrees
..but its a start...
..if someone want to help pitch in
this is the startinng formula, x is in rad, and the output is in sin of x +0 to 3 degrees of error, with an error at zero and pi/2 of zero (3 degees of error at sin(45) ) to far off for any use yet
Y= (-pi(x)^2 + pi^2x) / ( 2pi^2- (4pi - 2pi/11) )

Here is another challenge. 18° = 60° - 3*14°. Thus, given x = sin14° evaluate sin18° as a function of x.
That solution is relatively simple, but let us go the other way around. Given that sin18° = (Φ - 1)/2 = 1/(2Φ) where Φ = (√5 + 1)/2 is the Golden Ratio,
evaluate sin14° as a function of Φ, where 14° = (60° - 18°)/3.
I'm more impressed by how fast @blackpenredpen switches between pens. I try that and there's more ink on me than the board.

3 sin 10 - 4 sin^3 10 = sin (3x10 = 30) = 1/2, so sin 10 is one of the 3 roots of cubic equation 8 x^3 - 6 x + 1 = 0. What about the other 2 roots ?
sin (-210) = sin (150-360) = sin (150) = sin (180-30) = sin (30) = 1/2, So the other 2 roots are sin (150/3 = 50) and sin (-210/3) = - sin(70).
If T = 10, 50, -70 degrees, then sin 3T = sin 30 = sin (180 - 30 = 150) = sin (150 - 360 = -210) = 1/2 = 3 sin T - 4 sin^3 T = 3x - 4x^3 where x = sin T are the 3 roots of the cubic equation.
The 3 roots of cubic equation (x^3 + 3mx = 2n) are x = (A + B, Aw + B/w, A/w + Bw) where 1, w and w^2=1/w=w* are the 3 (real and complex conjugate) cube roots of unity=1 and A^3 = n+d and B^3 = n-d where d^2 = discriminant D = n^2 + m^3.
So, 8x^3 - 6x + 1 = 0 can be re-written as x^3 + 3 (m = -3/4) x = 2 (n = -1/2), therefore d^2 = discriminant D = n^2 + m^3 = (-1/2)^2 + (-3/4)^3 = 1/4 - 27/64 = -11/64, So d = ± i √11/8
A^3 = n + d = -1/2 + i √11/8 = (-4 + i √11)/8 and B^3 = -1/2 - i √11/8 = (-4 - i √11)/8 and complex conjugate cube roots of unity = w,w* = cos(2π/3) ± i sin (2π/3) = (-1 ± i√3)/2
So, sin(10) = Aw + B/w (after substituting the values of A^3, B^3 and w above).

By Ramanujan theorem :
Sinθ=θ-(θ³/3!)+(θ⁵/5!)+(θ⁷/7!)
Note:- Theta's value(input) will be in radians but output will it give in degrees {make sure that you putted value in rad}

We know the expression is real without checking because it is of the form z + z* where z* is the complex conjugate of z. z + z* is guaranteed always real.
Now about the nice expression involving only radicals, I have no fuckin idea 😅

how big is your board?

Hey, the values you get in first place and in the first check are sin(60-10°) and sin(60+10°). using sine addition formula for each and subtracting the equation you get sin(10°)=-(-sin(70°)+sin(50°))/(cos(pi/3)*2). Not the answer to why you choose a solution respect to the other but it was funny to note the simmetry around pi/3

To solve the equation 4(sinx)^3-3sinx+sin(3x)=0, substitute sinx=u+v to obtain u^3 = -1/8*sin(3x)±i/8*cos(3x). Before taking the cubic root to obtain u, we must multiply u^3 by e^(2𝜋i*n), n=0,1,2 to obtain all three branches of the cubic root. Then we have u = ( -1/8*sin(3x)±i/8*cos(3x))^(1/3)*e^(2𝜋i*n/3), n=0,1,2. Since sinx = u+v and v=1/(4u) we get sinx = (1/8*sin(3x)+i/8*cos(3x))^(1/3)*e^(2𝜋i*n/3) + (1/8*sin(3x)-i/8*cos(3x))^(1/3)*e^(-2𝜋i*n/3) , n=0,1,2. For 3x=𝜋/6 we get sin(𝜋/18) = ½*e^(2𝜋i/3)^(1/3)* e^(2𝜋i*n/3) + ½*e^(-2𝜋i/3)^(1/3)* e^(-2𝜋i*n/3) =cos(2𝜋/9*(1+3n)) = cos(40°)≈0.7660.. , -cos(20°)≈-0.9396.. , sin(10°)≈0.1736.. , for n=0,1,2, respectively. Obviously, we take n=2 to obtain the correct solution. /Roland Karlsson

13.26 use polar method to solve it

Nice

Thats fine

I have a challenge for you, calculate 2^^0.5, 2^^π, -1^^i, 2^^i and i^^i (tetrations)

Hi blackpenredpen! A challenge for you from my side - prove the following:
The volume of an n-dimensional sphere of radius R is :
(Pi to the power (n/2))/(n/2) factorial

First think I noticed (and apology as well)... Black pen, red and pen and now blue pen!! I am sure I am about the 1000 plus to remind you of that!

Hay have found a more general solution. I you put the ecuation in terms of e, you will obtain (1/2)*(e^(i*(pi*(1+4n)/6 + x/3)) + e^(i*(pi*(1+4n)/6 - x/3))).
For a real solution, the condition is sin(pi*(1+4n)/6 + x/3) + sin(pi*(1+4m)/6 - x/3) = 0, that complies with pi*(1+4n)/6 + x/3 = 2*pi*p and (pi*(1+4m)/6 - x/3) = 2*pi*q, (n, m, p, q)€(N,N,N,N), for example. I haven't go further, but I think it might be a interesting way.

Excuse me! Does anyone understands this one?
16. The weights of seven packages mailed by a company are 7Kg, 9Kg, 6Kg, 12Kg, 10Kg, 9Kg and 8Kg. Find

a) ∑x
b) ∑(x − 4)
🙏🙏

sin 1deg should be (relatively) easy now! sin and cos 72deg can be found with the golden ratio triangle, and then we could use the half angle formula thrice to get sin and cos 9 deg! then sin 1deg = sin10deg*cos9deg - cos10deg*sin9deg

always liked doing these things

Alternate Method:
Let θ = 10°
sin θ = sin 10°
sin 3θ = sin 30°
3 sin θ - 4 sin³θ = (1/2)
6 sin θ - 8 sin³θ = 1
8 sin³θ - 6 sin θ + 1 = 0
Let sin³θ = t
8t³ - 6t + 1 = 0
Solve the above cubic equation to get 3 solutions.
The solution which is closest to 0.174 will be the value of sin 10 degrees.

9:57 why is the absolute value not needed?

bring a video on bayes theorem

Revolutionary

On this regard I would like to recommend you to check out the book called "One-third Angle in Trigonometry: New method for Cubic Equation" by Bhava Nath Dahal, which is available online. I am to greedy to pay a quid for it, but as the description says, it might have the general formula we all are looking for.
If someone does buy this book, please share the answer :)

Nice way 😊😊😊 I tried another way 😍

PROF U have potential of being Profi Kray teacher's international MATH competition gold medalist)

Can someone explain to me the cube roots of unity?
Is it as simple as "assuming you have 1 answer, you can find the other 2?"
.....assuming you only have 1 eeal root, if all 3 roots are real i doubt unity would work as youre introducing unessesary "i"s
Anyway so like if I had a cubic equation whose first root is... idk 7, could I find the other two roots using omega?
Or is there some sort of special requirements for this to work? (For example... idk maybe you require two terms like in the video)

This whole approach seems to have gotten me nowhere. I have exact values for sine and cosine of 60° and 18° and used them to get exact values for sine and cosine of 42°. Then I wanted to get exact values for sine and cosine of 14° = 42°/3. Using the methods described here I can solve two depressed cubic equations for cos14° and sin14°, but in the process I must find cube roots of complex numbers, which requires computing approximate values for cos14° and sin14° to get those cube roots. I don't want to use some canned program to evaluate the cube roots, but do it myself. The only way I know to evaluate (a + bi)^(1/3) is the r^(1/3)[cos(θ/3) + i sin(θ/3)] approach where r = √(a^2 + b^2) and θ = arctan(b/a), but that requires approximating the values that I want to solve for. In general it appears there are no other ways to evaluate those roots without using approximate trig functions, which defeats the whole purpose in the first place.

Very interesting. That polynomial has one real root and two imaginary roots which are of course conjugates.

I think what you are really doing is getting sin(x/3) = Im(e^(xi/3) = [e^(xi/3) - e^(-xi/3)] / 2i . If you substitute for the exponentials using Euler's formula, you will end up with the same 1/2(sum of cube roots) that you got after simplifying. But I don't think this helps to find a closed form using real numbers?

Even though I am from india❤ ..
your videos are helpful to crack competitive exams(after 10+2)
🎉🎉🎉You are a mathematician sir ...🎉🎉🎉

Substitute cubic root sum as *A*
sin 10° = (1/2) • *A* then count:
A''' = -1 + 3A• *1* ➡ A = (A''' +1) / 3
Substitute back ⬆ we get:
sin 10° = (1 + A''') / 6
--- --- ---
Original Formula:
sin 3x = sin x •( 3 - 4.sin"x)
sin 30° = sin 10°•( 3 - 4.sin"10)
1/2 = 3.sin 10° - 4.sin'''10°
1 = 6.sin 10° - 8.sin''' 10°
1 + 8.sin'''10° = 6.sin 10° ↔
sin 10° = [ 1 + (2.sin10°)'''] / 6
--- ---
So, A = 2.sin 10° !?!? 🔄
Round and round 😵
---
I don't like imaginary number.
It Only exist in dreams world.
√(-1) = not 1, not -1 = Error! 😜

i love this