Mathematical Olympiad | Solve for a+b | Math Olympiad Preparation

Great. Thank you.

I think this is a better approach: notice that 9=3^2 = (ab)^2. The first equation can be rewritten as: a^2-b^2 = (ab)^2, we get a quadratic equation of (a/b). Solve this equation and together with ab=3, it's easy to find the value of a and b and consequently a+b.

a^2 - b^2 = 9
ab = 3
b = 3/a
a^2 - (3/a)^2 = 9
a^2 - (9/a^2) = 9
Let a^2 = x
x - (9/x) = 9
Multiplying by x
x^2 - 9 = 9x
x^2 - 9x - 9 =0
Solve for x.
Then a = square root of x
Then b = 3/a

From the second equation, b = 3/a. Substitute the value of b into the first equation: a² + (3/a)² = 9. Multiply both sides by a² to get a⁴ + 9 = 9a². Rearrange to get a⁴ - 9a² +9 = 0. Let x = a² to make this a quadratic: x² -9x +9 = 0. Solve with quadratic formula x = (9 + √(81 + (4)(1)(9))/2 or x = (9 - √(81 + (4)(1)(9))/2 simplifying to x = (9 + 3√(13))/2 or x = (9 - 3√(13))/2. Replace x by a² and note that the second value of x is negative. Ruling out imaginary numbers for a, x must be positive, a² = (9 + 3√(13))/2. From the first equation, b² = ((9 + 3√(13))/2) - 9 which simplifies to b² = (3√(13)-9)/2. we note that, for ab = 9, a and b must both be positive or both negative. Taking the positive roots, a + b = √((9 + 3√(13))/2) + √((3√(13)-9)/2). Using a scientific calculator, a = 3.147749500 and b = 0.953061862. a + b = 4.100811362. PreMath's solution of a + b = 6 + 3√(13) = 4.100811362 is identical when calculated to the same level of precision. I suspect that my solution can be simplified to be identical to PreMath's solution.
Taking negative values for my a and b produces a solution with the same magnitude but a negative sign, PreMath's other solution.

The last thing that I remember is that I was looking for a song....

Brilliant ! I like the fact that the explanation is always easy with you, step by step, reminding the rules.

An easier way is to use a right angles triangle with a as hypotenuse and the other 2 sides as b and 3. This uses the given info which is a^2 - b^2 = 9. Use
the second info ab = 3 to get b = 3/a. Now use the right angle triangle to get a^2 - (3/a)^2 = 9. In the calculation use a substitution x = a^2. Now solve a quadratic eqn to get x and then solve for a and b. Now do a + b. Very very simple. Unlike the method used in this video. Thanks. Have a great day.

We can still simplify the problem in the following manner. Let x = a² and y = b². So that x - y = a² - b² = 9 ... (1). Again xy = a².b²=(ab) ² = 3² = 9 ...(2) Now using the algebraic equation (x + y )² = (x - y )² + 4xy , we get (x + y )² = 9² + 4. 9 = 117. So that (x + y ) = √117. Here negative sign is not considered as x and y are square terms of a and b . Replacing the values of a and b for x ad y, we get a² + b² = √117. Now (a + b) ² = (a² + b²) + 2ab = √117 + 2. 3 = √117+6. Therefore a + b = +-√ (√117+6), thus our result.

Sir we can also do it by a+b=9/a-b then use(a-b) ²=(a+b) ² - 4ab and solve the quadratic

Shorter solution : i is the imaginary number
(a + ib)^2 = a^2-b^2+2iab
= 9+6i
Then |a + ib|^2 = sqrt( 81 +36 ) = 3*sqrt(13)
ie a^2 + b^2 = 3*sqrt(13)
a + b = + or - sqrt( a^2 + b^2 + 2ab)
= + or - sqrt(3*sqrt(13) + 6)

consider the system (1)
a ^ 2 + b ^ 2 = k (where ^ 2 stands for squared)
a ^ 2 - b ^ 2 = 9
from which adding and subtracting the two equations member by member
a ^ 2 = (k + 9) / 2 and b ^ 2 = (k - 9) / 2 (2)
a ^ 2 * b ^ 2 = (ab) ^ 2 = 3 ^ 2 = 9,
applying the (2)
k ^ 2 - 81 = 36 k ^ 2 = 117 = 13 * 9 and k = ± 3 √13
from (a ^ 2 + b ^ 2)> 0, k = + 3√13 follows
a ^ 2 + b ^ 2 = (a + b) ^ 2 -2ab = + 3√13 and
(a + b) ^ 2 = 6 + 3√13 (the solution 6 - 3√13 must be discarded because it is negative in contrast to the first member of equality which is always positive)
a + b = ± √ (6 + 3√13)

A shorter solution: Substitute x=a+b, y=a-b. We obtain from here that xy=9, x^2-y^2=12. We can remove y from this system to obtain a biquadratic equation for x

I love it!!! Very similar to "the answer is made by rotating a roulette N^((i*pi*e)^-i) times" Because exist traditional method solving this question

You can go directly from a^4 - 2a^2b^2 + b^4 = 81 to a^4 + 2a^2b^2 + b^4 = 81 + 4a^2b^2. The LHS is (a^2 + b^2)2 and the RHS is 117. So instead of adding 18 twice you just add 36 once. And you don't need to consider a^2 + b^2 = - 3 sqrt(13). You keep that option around far longer than necessary.

Since a^2 - b^2 = 9 and ab = 3 then we can write a^2 - b^2 = ( a-b) (a+b) = 9 that means a + b = 9 / a - b if we substitute a = b/3 in that equation to becomes 3/b + b = 9 / (3/b - b) then by solving this equation we will get the following form : b^4 + 9b^2 - 9 = 0 now let's call b^2 = x then we get x^2 + 9x - 9 = 0 and by solving this equation we will get x = 0.908 and we know that x = b^2 that means b = 0.953 then a = 3, 1477 and a + b = 4,1 and that is the same answer. Thank you very much sir.

Actually, this is a very simple and trivial problem that can be solved directly by expressing unknown a (and b) from the second equation ab=3, and by substituting it to the first equation. In this obvious method, we get a quadratic equation for a^2 (and for b^2). Having received a^2 and b^2, it is very easy to find (a+b)^2 and solve the problem. Such a straightforward solution does not require any tricky actions (as it is done in this video). In my opinion, this problem does not correspond to the level of Math Olympiad, since it is very simple, and it can be done to the students in any regular (not math) class as a homework. BTW, since we are dealing with real numbers only (not complex), it’s absurd to use a minus sign in the expression (a^2+b^2) because it can't be negative.

a^2 - b^2 = 9
a.b = 3
So, a = 3/b and b = 3/a
a^2 - (3/a)^2 = 9
a^2 - (9/a^2) = 9 multiple by a^2
a^4 - 9 = 9a^2 (substitution)
a^4 + 9a^2 + 9 = 0,
Remember : ax^2+bx+c = 0
X1 = [-9 + root of 9^2 - 4x1(-9)] / 2
X1 = [-9 + root of 81 - (-36)] / 2
X1 = [-9 + root of 117] / 2
X1 = (-9 + 3 times of the squared root of 13) / 2
Or : (-9 + 10,82) / 2
1.82 / 2 = b = 0.91
And then,
If a = 3/b and b = 3/a
a = 3/0.91 = 3.29
So, "a" + "b" is equals to 4.2 (four second) or (four over two)

b=3/a
a^2-(3/a)^2=9
a^2-9/a^2=9
a^4-9a^2-9=0
a^2=(9+3sqrt13)/2. (a^2 is +ve -sign is Cancel)
Now putting the value of a^2 in Ist eqaution

I suppose it would be a lot easier if you use the concept a square-b.square= (a+b)(a-b)=9 and it gives a+b =9/a-b, given the ab =3, a+b =9/a-a/3, a+b=27/2a, giving a.square=81/2, giving a=9/root2 ,b now=3/a=3xroot2/9=root2/3; therefore.a+b= 9/root2+root2/3, a=b =29xroot2/3

Set t := a + b. Because (a-b)^2 = t^2 - 4ab = t^2 - 12, we have 81 = (a^2-b^2) = (a-b)^2(a+b)^2 = t^2(t^2-12), or equivalently t^4 - 12t^2 -81 = 0. Calculating the positive root of x^2 - 12x - 81 = 0 and taking ±sqrt of it, we obtain the values of t.

The most important thing is...We know that {ab = 3}
and{ a^2-b^2 = 9} means (a+b)(a-b) = 9.
and What we are finding is (a+b) NOT (a, b). better to ignore each of a, b.
At this point, the best approach is...
Just Put X = (a+b),Y = (a-b)
and... use Basics of math, below --> DONE.
[1]. (a+b)^2 = a^2+b^2 + 2ab
[2]. (a-b)^2 = a^2+b^2 - 2ab
Obviaously, [2] = [1] + 4ab ,and we know (ab=3).
[3]. Y^2 = X^2 + 12
[4]. XY=9
with [3] and [4], we get quadro of func(X), and find X^2, and find X.
(still skipping each of a , b).

Hi there and thanks for this nice system. Another shorter solution is to take X=(a+b)^2 and Y=(a-b)^2 .
We can easily get that X-Y=12 and XY=81. It’s then easy to find X and then a+b

I followed the same approach, but a^2 + b^2 cannot be equal to -sqrt(117), since it is always positive.

Let a + b = c. By an express from this equality `a`(b) and squaring both sides we are getting a^2 - b^2 = c^2 - 2ac and b^2 - a^2 = c^2 - 2bc. Hereof c^2 - 9 = 2bc and c^2 + 9 = 2ac, from product of the last two equations are getting c^4 -12 c^2 - 81 = 0. By solved this biquadratic equation we are getting the same solution.

My attempt before video.
Let u=a+b, then we have
u² = a² + b² + 6 = 15 - 2b², and
(9/u)² = (a - b)²=a² + b² - 2ab = 3 - 2b²
Subtracting, both of them give
u² - 81/u² - 12 = 0.
⇒ u⁴ - 12u² - 81 =0
⇒ u² = 6 ± 3√13
⇒ u = ±√[ 6 ± 3√13].

Simple and standard way to solve this is:
subtracting the second equation multiplied by 3 from the first, we get:
a^2 - 3ab - b^2 = 0, This is homogeneous equation - sum of all powers is 2. And then b = k * a - is standard substitution for homogeneous equation.
a^2 - 3 a^2 k - a^2 * k^2 = 0; a 0;
k^2 + 3k - 1 = 0;
k = (-3 +- sqrt(13) / 2; and ab = 3 , hence a^2 * k = 3, hence k > 0, and the only k = (-3 + sqrt(13)) / 2.
and then from a^2 * k = 3, a = +- sqrt( (3/2) * (sqrt(13) + 3) ), and from b = k*a
b = +- sqrt( (3/2) * (sqrt(13) - 3) ).

Your explanation is so “ step by step” and i actually follow the procedures !
Thank you for sharing ……Abe ( uk )

There is a much more general, systematic, elegant, concise and faster way (which is quite surely the optimum), by use of the Aristarchus identity, whose modern version is the complex number quadrance (or modulus) fundamental theorem : Q(z)Q(Z) = Q(zZ)
Where z=a+ib, Z=A+iB, and Q(z) = a^2+b^2 is the quadrance of the complex number z.
Indeed in the special case z=Z it simplifies to : (a^2+b^2)^2 = (a^2-b^2)^2 + (2ab)^2
From that starting point the general solution to the problem follows immediately :
(a+b)^2 = 2ab +(a^2+b^2)= 2ab + sqrt[(2ab)^2 + (a^2-b^2)^2]. (the negative sqrt is excluded by positivity of the LHS)
Which gives the two solutions for a+b. QED

Thanks for video.Good luck sir!!!!!!!!!

Fulgurant résolution :
Aristarchus identity : (a^2+b^2)^2 = (2ab)^2 + (a^2-b^2)^2
Thus : (a+b)^2 = 2ab +(a^2+b^2)= 2ab + sqrt[(2ab)^2 + (a^2-b^2)^2].
Which gives immediately the two general solutions for a+b.
For particular solutions use : ab=3 and (a^2-b^2)=9 to get : (a+b)^2 = 6+3sqrt(13)
QED

consider the system (1)
a squared + b squared = k
a squared - b squared = 9
a ^ 2 or b ^ 2 = a squared or b squared
from which adding and subtracting the two equations member by member
a ^ 2 = (k + 9) / 2 ... b ^ 2 = (k - 9) / 2 ... (2)
a ^ 2 * b ^ 2 = (ab) 2 = 32 = 9, applying (2)
k ^ 2 - 81 = 36 ... k ^ 2 = 117 = 13 * 9 and k = ± 3 √13
therefore a ^ 2 + b ^ 2 = + 3√13 (sum of two squares necessarily positive)
a ^ 2 + b ^ 2 = (a + b) ^ 2 -2ab = 3√13 ... (a + b) ^ 2 = 2ab + 3√13.
(a + b) ^ 2 = 6 + 3√13
a + b = ± √ (6 + 3√13)

a*b=3 so b=3/a
Sub 3/a in a^2-9/a^2=9>>>let a^2 =x
X -9/X = 9
X^2 - 9X - 9 = 0. Solve for X which solves for a^2 which gives the value for a and b

Great video as always, found it even trickier than most of your other videos 😁
I am wondering: Could you solve a task like this one quickly if you were asked? I think it is anything but straight forward.

He can save a little time by dropping the solution -3(13)^(1/2) from equation (3) by noting that a^2+b^2 is >=0.

Great work 🙂👊

It is also easily solvable by (a²-b²)²= (a+b)²(a-b) ²
Then (a²-b²)²=(a+b) ²{(a+b) ²-4ab}

Just amazing. Love it when you utilized the (a+b)^2 identity to bring it all together.

Great and clear explanation Sir .
Thank you so much.

There is a more simple solution: From handling Pythagorean triples we know, that a, b, c in an rectangular triangle may be represented by the expressions m^2 - n^2, 2mn and m^2 + n^2 for a and b, c respectively. Let x, y and z be the 3 sides of an rectagular triangle. So if a^2 - b^2 = 9 = x and ab = 3, y has to be 2ab = 6. Thus, z will be 3*sqrt(13). So (a+b)^2 = a^2 + b^2 + 2ab is equal to 3*sqrt(13) + 6 and ab = +/-sqrt(6 + 3*sqrt(13)).

This one stretched me further than most of your other videos, so I will have to go through it again more slowly. I got part way without watching the video first, but I think remembering those identities is important for me.

Well done. I got the answer in almost the same way.

you can just reject -ve at eq3, as a^2 + b^2 can't be neg for a,b in real numbers.

Write X = a+b, such that a-b=9/X, using (a+b)(a-b)=9.
Obviously (a+b)^2 - (a-b)^2 = 4ab, and thus X^2 - 81/X^2 = 12, such that (X^2)^2 - 12*X^2 - 81 = 0.
Solving this quadratic equation gives X^2 = 6 + sqrt(117), and thus a+b = X equal to sqrt(6 + sqrt(117)) and -sqrt(6 + sqrt(117)).

6:18
a²+b² can't be negative, is it? So, we can write just 3√13, without ±

you had a^2+b^2= +-3sqrt(13), the negative can be rejected here as the LHS is non-negative

i think i've found a better way to solve, we can use quadratic equations:
M = A-B
S = A+B
delta = b^2 - 4ac => M = sqrt(b^2 - 4ac) / |a| => in this case we divided the whole equation by a, so a = 1 and equation is:
P = A*B = 3 => x^2 - Sx + 3 = 0
and delta = S^2 - 12
so since a = 1 => M = sqrt(S^2 - 12)
(a+b) (a-b) = a^2 - b^2 = 9
S * M = 9
S * sqrt(S^2 - 12) = 9
sqrt(S^2 - 12) = 9 / S
S^2 - 12 = 9^2 / S^2 => S^2 = t
t - 12 = 81 / t
t^2 - 12t - 81 = 0
t = 6 + 3 * sqrt(13) => S^2 = 6 + 3*sqrt(13) => S = (A+B) = sqrt(6 + 3*sqrt(13))
~~t = 6 - 3 * sqrt(13) => since 3 * sqrt(13) > 6, so this is not acceptable~~

a² - b² = 9 (1)
ab = 3 (2)
Lets divide (1) on (2)
a/b - b/a = 3 (3)
x - 1/x = 3 (4)
x² - 3x -1 = 0 standard square equation with solutions m
so
ab = 3 and a/b = m
a+b = √(3m) + √(3/m)
where m = (3 + √13)/2
Notes : can't use second root
(3 - √13)/2 since it's negative.
Alternatevely, a + b =
√(a² + 2ab + b²), so
a+b = √(3m + 6 + 3/m)

J'apprécie vos vidéos. Concernant celle-là, je vous propose une solution de plus que celles déjà proposées:
Si a # 0, b=3/a donc a^2 - 9/a^2 = 9 donc a^4 - 9a^2 - 9 = 0 bicarrée en a^2 avec rac(delta) = rac(117) et donc a^2 = (9+rac(117))/2 , l'autre valeur est exclue car négative ( 81 < 117 )
Donc b^2 = a^2 - 9 soit b^2 = (- 9 + rac(117))/2 positive.
Enfin (a + b)^2 = a^2 + b^2 + 2ab = 6 + rac(117) et donc a+b = +/- rac(6 + 3rac(13)).
Si a = 0 alors b^2 = -9, impossible dans R. Pas de solution en plus. Il n'y a que 2 solutions.
Salutations

This problem is a little harder than it looks. My solution is fairly similar to professor's. First take (a-b)*(a+b)=a^2-b^2=9 (equation 3). Square this to get (a-b)^2 * (a+b)^2 = 81 (equation 3a). Next note that (a+b)^2-(a-b)^2= (a+b)^2-(a-b)^2=4ab=12 (equation 4). Rearrange this to (a-b)^2=(a+b)^2-12 (equation 4a). We can now get rid of the (a-b)^2 by inserting equation 4a into 3a. The result is [(a+b)^2-12]*(a+b)^2)=81. (equation 5). Now define u=(a+b)^2. Equation 5 then becomes (u-12)*u=81 (equation 5b) Or u^2-12u-81=0 (equation 5c). The solution to this quadratic is u=[12+-sqrt(468)]/2. Or u = 6+-3sqrt(13). Since u is a square and thus must be positive we reject the negative root 6-3sqrt(13), thus u=6+3sqrt(13). Since u = (a+b)^2, then a+b=+-sqrt[3sqrt(13)].

That was a fair amount of work. Good explanation

Bravo Professor!

One more way is to take (a+bi)^2=a^2+2ab-b^2=9+6i and use square root formula for complex numbers to get an answer

Kind of a prety generic solution.
X = +/- sqrt(2V+sqrt(U^2+4V^2))
where U, V are used in place of 3 and 9.

My solution below:
a + b = +/-sqrt[(a+b)^2] = +/-sqrt(a^2 + 2ab + b^2) = +/-sqrt(a^2 + 6 + b^2) = +/-sqrt[a^2 + 6 + (a^2 - 9)] = +/-sqrt(2a^2 - 3)
b = 3/a, so plugging that into equation 1 gives: a^2 - (3/a)^2 = 9
Rearranging gives a^2 - 9 - 9/a^2 = 0
Multiplying by a^2: (a^2)^2 - 9a^2 - 9 = 0
This is a quadratic equation in a^2, solving for a^2 gives: a^2 = [9 +/- 3sqrt(13)]/2
Plugging this into the equation found earlier:
a+b = +/-sqrt(2a^2 - 3) = +/-sqrt[9 + 3sqrt(13) - 3] = +/-sqrt[6 + 3sqrt(13)]

The path you expose here, toward the correct solution, is good. Nevertheless a bit lengthy with furthermore some extra missed shortcuts like your lack of simplification with a2+b2=3sqrt13.
But remarquably, there is a much more general, systematic, concise and faster way (which is very probably the optimum), by use of the Aristarchus identity (which modern form is the complex number quadrance (or modulus) fundamental theorem) : Q(z)Q(Z) = Q(zZ)
Where z=a+ib, Z=A+iB, and Q(z) = a^2+b^2 is the quadrance of the complex number z.
Indeed in the special case z=Z it simplifies to : (a^2+b^2)^2 = (a^2-b^2)^2 + (2ab)^2
From that starting point the general solution to the problem follows immediately :
(a+b)^2 = (a^2+b^2) + 2ab = 2ab + sqrt[(2ab)^2 + (a^2-b^2)^2]. (the negative sqrt is excluded by positivity of the LHS)
Which gives the two solutions for a+b
QED

I just went for x=a² and y=b² and solved (1) x-y=9 and (2) xy=9 for x and y and simply added the two square roots.

I am delighted that i got the right answer.

My idea was different from this.
I had some idea
1)a,b>0 2)a,b0
a/b=(3+sqrt13)/2
b/a=2/(3+sqrt13)
sqrt a/sqrt b +sqrt b/sqrt a= (a+b)/sqrt 3
But my Renault for a,b>0 Is (sqrt 3)*{(5+sqrt13)/[(sqrt2)(sqrt(3+sqrt13)]
Its the samé on calculator, but not so nice .....

I solved for a and b, which are:
a = sqrt((3*sqrt(13)+9)/2)
b = sqrt((3*sqrt(13)-9)/2)
And their negative counterparts.
I took the sum, squared it, simplified, and took the square root to get:
a + b = +- sqrt(6 + 3*sqrt(13))

At the end of Step 1 you had a^4 + b^4 =99. It seems like you should have been able to take the 4th root of both sides and ended up with a + b = 4√99.
But 4√99 does not equal +/-2√(6 + 3√13).

លំហាត់ល្អ!👍👍😍

8:48 the numerical value of + - sqrt (6+3 sqrt 13) is + and - 4.10609

Let X = (a+b)^2 = a^2 +2ab +b^2
Then summing this with the first equation leads to
2a^2 + 2ab = X + 9 hence 2a^2 = X + 3 [ab = 3]
Substraction gives
2b^2 + 2ab = X - 9 hence 2b^2 = X - 15
Let's multiply :
2a^2 x 2b^2 = (X+3)(X-15) = 4 x (ab)^2 = 36 which leads to
X^2 - 12X - 45 = 36
X^2 - 12X - 81 = 0
Delta is 12^2 + 4x81 = (2^2 x 2^2 x 3^2) + (2^2 x 3^2 x 3^2) = 6^2 x 13
Sqrt(Delta) = 6Sqrt(2^2+3^2) = 6Sqrt(13)
X is a square so > 0, only positive root is (12 + 6Sqrt(13)) / 2 = 6 + 3Sqrt(13)
finally a+b = Sqrt(6 + 3 Sqrt(13))

Very good lesson ..nice learn mathemathic program...suport

Okay, so I introduced new variables; p = a + b and m = a - b. p*m = (a + b)(a - b) = a^2 - b^2 = 9 and p^2 - m^2 = (a + b)^2 - (a - b)^2 = 4ab = 4 * 3 = 12. So I switched to a system with p and m, where I need to find p. p * m = 9 --> m = 9/p --> m^2 = 81/p^2. Substitute that in the second equation: p^2 - 81/p^2 = 12. Multiply by p^2 to get p^4 - 81 = 12 * p^2. Move everything to the same side and we get p^4 - 12 * p^2 - 81 = 0. This is a biquadratic equation, so we can solve for p^2 with the quadratic formula: p^2 = [-(-12) + - sqrt((-12)^2 - 4 * 1 * (-81))]/2 = [12 + - sqrt(468)]/2 = [12 + - 6*sqrt(13)]/2 = 6 + - 3*sqrt(13). 3*sqrt(13) > 6, so that cannot be an answer to p^2 (if we ignore complex answers). So p^2 = 6 + 3*sqrt(13). Which leads to p = a + b = + - sqrt(6 + 3*sqrt(13)).

Similarly quick way to find a^2 + b^2 = 3 sqrt{ 13 }.. which also gives a solution to the problem in a different form (and solves for a and b):
(a^2) + ( - b^2 ) = 9
(a^2) ( - b^2 ) = - 9 (from ab = 3).
Thus (a^2) and ( - b^2 ) are the roots of the polynomial X^2 - (sum of roots) + (product of roots), so here of X^2 - ( 9 ) X + (-9),
and so they're the two solutions to the equation X^2 - 9 X - 9 = 0.
Thus (a^2) and ( - b^2 ) are the two values of X in: X = [ 9 +/- sqrt{ (-9)^2 - 4 (1)(-9) } ] / 2 = 9/2 +/- sqrt{ (9)^2 + 4(9) } / 2 = 9/2 +/- 3 sqrt{ 13 } / 2.
And so a^2 + b^2 = difference of those two roots, positive version. Taking that difference, the term 9/2 part cancels and the alternating sign of 3 sqrt{ 13 } / 2 means it doubles.
Thus a^2 + b^2 = 3 sqrt{ 13 }.
(Could of course solve a^2 = 9/2 + 3 sqrt{ 13 } / 2, - b^2 = 9/2 - 3 sqrt{ 13 } / 2 to find a^2 + b^2.)
Could also use that a^2 = 9/2 + 3 sqrt{ 13 } / 2, - b^2 = 9/2 - 3 sqrt{ 13 } / 2 to find a and b up to sign, and from there reason to a + b (the required reasoning is to show sgn(a)=sgn(b)).
Get a + b = +/- [ sqrt{ 3 sqrt{ 13 } / 2 + 9/2 } + sqrt{ 3 sqrt{ 13 } / 2 - 9/2 } ] .

I expressed a=3/b, substituted "a" in the first equitation with 3/b and solved quadratic equation.

Thanks, I had learn every day watching yours vídeos

2 equations and 2 unknowns. Just equate one of the equation to x. Then substitue this X equation to the second then simplify.

Such! Today, the opposite is true: the task seems simple, but the answer is surprisingly cumbersome :)) Thank you, Professor. My congratulations on the Day of Remembrance and Reconciliation! Never Again!

I have seen some of videos. How do you come up with a strategy for solving these equations? The connection from the start to the end is not obvious. What kind of intuition to you use?

em....I think the question should mentioned that a and b is real number at the very beginning. If it state a and b is natural number instead, then obviously it is no solution
ab = 3 imply both a and b is odd number
(a+b)(a-b) = 9 which doesn't means sense as both a+b and a-b can only be even number, product of 2 even numbers can only be even number, so a+b is no solution

Great please more of equations

From two given equations, we have a^2=(9+-3rt13)/2.
Also from the two given equations we have (a+b)^2=2a^2-3, so we get the answer.

What about :
a^2-b^2-2ab = 9-6
-(a^2+b^2+2ab) = -3
-(a+b)^2 = -3
(a+b)^2 = 3
(a+b) = SQRT(3)
I don"t see where i miss something. Do you ?

It is assumed that a and b are real numbers.
9²=(a²-b²)²=(a+b)²(a-b)²=(a²+b²+2ab)(a²+b²-2ab)=(a²+b²)²-4(ab)²=(a²+b²)²-4x3²
∴ (a²+b²)²=81+36=117. ∴a²+b²=√117=3√13. (a+b)²=a²+b²+2ab=3√13+6.
∴a+b=±√(6+3√13).

You know, that a^2+b^2 >= 0. So there is no need to calculate with \pm3\sqrt{13}! Thanks for the video

I think this is shorter
from equation (2) ab = 3 then we get a2 b2 = 9
then substitute in equation (1)
a2 - b2 = a2 b2
a2 - b2 - a2 b2 =0
a2(1-b2) - b2 = 0 (3)
form equation (2) we get a=3/b or a2=9/b2 then substitute in equation (3)
(9/b2)(1-b2) -b2 =0
let b2 = y then we get
9(1-y)/y - y = 0 , multiply by y we get
9-9y-y2=0 (4)
y=(9 [+,-] Sqr(81 - (4 * 9 * -1) ))/(2*9)
y=(9 [+,-]Sqr(117))/ 18 we know that y must be positive and Sqr(117)>9 then
y=(9+Sqr(117))/18 = 1.100925213
b = [+,-] Sqr(y) =[+,-] Sqr(1.100925213) = [+,-] 1.0492
a = 3/b =[+,-] 3 /1.0492 = [+,-] 2.8592
a+b = [+,-] (2.8592 + 1.0492) = [+,-] 3.9084

What a complicated solution

The best way for you please trying solving this task using complex analysis method, then you Will finding imaginary and real component and then those shall be completed to solve

a=b/3 Substitut and solve quadratik equation and finish.

Well I have two other ways to find the solution.
What we would like to do at first is sum L1 and 2*L2 to get somthing close to a remarkable identity: a²-b²+2ab = 15, close but no cigar, it would have to be +b² . Well when it comes to squares and we want - instead of + it's only natural to think about complex numbers, so let's see whether (a+ib)² does the trick:
(a+ib)²=a²+i²b²+2abi=a²-b²+2abi = L1+2iL2=9+6i. So we are looking for a complex Z whose square is 9+6i and we want Re(Z)+Im(Z) . We have the formulas Re(Z) = |Z| * cos(arg(Z)) and Im(Z) = |Z|*sin(arg(Z)) . So we only need to get module and argument of Z. let's say p=9+6i
We have |p|=sqrt(9²+6²)=sqrt(117) and arg(p)=arctan(6/9)=arctan(2/3).
|Z| = sqrt(|p|)=sqrt(sqrt(117)) and arg(Z)*2 = arg(p) so arg(Z)= arctan(2/3)/2 OR arctan(2/3)/2 + pi because args are mod 2*pi . so we can inject those values and find Re(Z)=a and Im(Z)=b and then a+b .
Also another way would be to compute -L2² : -a²b²=-9 and say A=a² and B=-b² : L1 becomes A+B=9 and L2 becomes AB=-9 and then because of viet formulas A and B are the roots of that polynomial : X²-9X-9 there is a positive and a negative root because the product of the roots is negative, so the negative root has to be B because both a² and b² are positive, and then we can find a and b, but that will amount to 4 solutions: from which we can scrap those where a and b are not of the same sign because ab=3 and 3 is positive, and then we only have two solutions for (a,b) and for a+b.

V nice explanationSir

Thanks for solving this. First, l want to say this solution is perfect but l used another algebraic formula for this question. I used a⁴+b⁴=((a+b)²-2(ab))²-2a²b². And when l watched this solution l saw it is better.👍

Awesome video, excellent way of solving the question, excellent, Sir, many thanks!
a^2 := k; b^2 := p → k - p = 9 → √(kp) = 3 → kp = 9 → kp = k - p → k = p/(1 - p) →
kp = 9 → kp = p(p/(1 - p) → p^2/(1 - p) = 9 → p^2 + 9p - 9 = 0 →
p1 = (3/2)(√13 - 3); p2 = -(3/2)(√13 + 3) < 0 ≠ solution!
kp = 9 → k = 9/p = 18/(3√13 - 9) = (3/2)(√13 + 3)
m ∶= √13 + 3; n ∶= √13 - 3 → a + b = (√6/2)(√m + √n) = √(3(√13 + 2)) ≈ 4,1

no tricks
a ^ 2-b ^ 2 = 9
ab = 3
f (x, y) = a + b
Let's try my favorite substitution:
We substitute:
x = m + y
y = m - r
and we get
4mr = 9
m ^ 2-r ^ 2 = 3
f (x, y) = 2m
16 (mr) ^ 2 = 81
r ^ 2 = m ^ 2-3
16m ^ 2 * (m ^ 2-3) = 81
16 m ^ 4 - 48 m ^ 2 - 81 = 0
we are interested in f (x, y) = 2 * m so let's substitute (2m) ^ 2 = t
that is, m ^ 2 = t / 4; m ^ 4 = t / 16
t ^ 2-12t-81 = 0
t1 = 3 (2 + sqrt (13))
t 2 = 3 (2 - sqrt (13))
So we have two real solutions
(2 * m) ^ 2 = 3 * (2 + sqrt (13))
2m1 = sqrt (3 * (2 + sqrt (13)))
2m2 = -sqrt (3 * (2 + sqrt (13)))
And two are imaginary
2m3 = sqrt (3 * (sqrt (13) -2)) * i
2m4 = -sqrt (3 * (sqrt (13) -2)) * i
there is the answer.

My solution is something like this
let x=a+b
Since ab=3, we have 2ab=6 and a^2b^2=9 , then a^2+b^2=x^2-6
compare with a^2-b^2=9
we have a^2= (x^2+3)/2 and b^2=(x^2-15)/2
sub. in a^2b^2=9
we get (x^2+3)(x^-3-12)=36
and then (x^2+3)(x^2-3)-12(x^2+3)=36
x^4-12x^2-81=0
x^2= (12+/- sqrt(144+4(81))) /2
=6+3sqrt13 or 6-3 sqrt13 (rejected if complex no. not accepted)
x=sqrt (6+3 sqrt 13)

Mind-blowing problem

a square plus b square can only be a positive number. So one result can be removed in the third equation and no need to do that in Step 3.

Nice solve! Thanks for making it!

sqrt both sides
a-b=3
a-3=b
ab=3
(a)a-3=3
used a calculator and got sqrt6 for a
(sqrt6)^2-(sqrt6 -3)^2
6-6+9
6-6=0
0+9=9
a=sqrt6
b=sqrt6-3
I think this is right, but I'm about to go into highschool next year so I wouldn't be to surprised if it was wrong, is it?

eq-3 a square plus b square should be only positive. Because sum of square of two real numbers must be positve

Professor;
if a²-b²=9 -> (a+b)(a-b)=9 -> a+b must be 9 b/c (a+b) >(a-b)

if I wrote down: +- square root of (4.5 + square root of 29.25) + 3 : +-square root of (4.5 + square root of 29.25) does that count as the correct answer? The numerical value of this expression is the same as the value of the expression that the author of the video received, it's just that my record is longer (if I didn't have to write the square root in words all the time, it would be shorter). Sorry for my english, it's not my native language

Very good! Greetings from Brazil👍

There is an unstated assumption that the solution must be in real numbers. If you allow complex numbers, then you cannot say that (a+b)^2 = 6-3(sqrt(13)) is a false statement.
This assumption should be included in the problem statement.

What are the practical applications of this?

U explain fantastic every time,thank u

Very good sir

You do not need to use the symbol '±' because it is a^2+b^2 > 0.