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Additional Maths

The cubic equation x^3 + ax^2 + bx -26 = 0 has 3 positive, distinct, integer roots. Find the values a and b.

I don't understand how to work this out.

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Reply 1
Have you tried getting everything factorised

x3+ax2+bx26=\displaystyle x^3 + ax^2 + bx - 26 =

p(x)=x32x2x+2=(x1)(x2+ax+b)=x3+(a1)x2+(ba)xb\displaystyle p(x) = x^3 - 2x^2 - x + 2 = (x - 1)(x^2 + ax + b) = x^3 + (a - 1)x^2 + (b - a)x - b

Is that what you mean?
(edited 12 years ago)
Reply 2
What factor would I use?
Reply 3
If the equation has three distinct roots, you will be able to factorise it into something of the form:

(xf)(xg)(xh)=0\displaystyle (x-f)(x-g)(x-h) = 0

Where f, g and h are your solutions. When you multiply this all out, you're going to get a bunch of different terms. Importantly, you will find that you have only one constant term, -fgh. You know that this must equal -26, which tells you what your three solutions must be (here you can apply the restriction that the solutions are distinct and positive integers). Put your solutions back into the factorised form and multiply out in full.
(edited 12 years ago)
Reply 4
Original post by TheMagicMan
If rir_i are the roots of the polynomial i=0naixi\displaystyle\sum_{i=0}^n a_i x^i, then ri=(1)na0\prod r_i =(-1)^n a_0. Use the fact that rirjr_i \not = r_j if iji \not= j, and that riNr_i \in N


I wish I understood this.
Reply 5
Original post by porkstein
If the equation has three distinct roots, you will be able to factorise it into something of the form:

(xf)(xg)(xh)=0\displaystyle (x-f)(x-g)(x-h) = 0

Where f, g and h are your solutions. When you multiply this all out, you're going to get a bunch of different terms. Importantly, you will find that you have only one constant term, -fgh. You know that this must equal -26, which tells you what your three solutions must be (here you can apply the restriction that the solutions are distinct and positive integers). Put your solutions back into the factorised form and multiply out in full.


Thanks.
Reply 6
I got 1,2,13, can't it be -1,-2, -13?
Reply 7
Original post by Math12345
I got 1,2,13, can't it be -1,-2, -13?

Notice the condition upon the question - they are three POSITIVE, distinct integer roots.*

If -1, -2, and -13 are the roots, then you'll have the cubic equation:

(x+1)(x+2)(x+13) (x+1)(x+2)(x+13)

But 1×2×1326 1 \times 2 \times 13 \neq -26 , so -1, -2 and -13 can't be the three roots (plus they're not even positive in the first place)
Reply 8
Original post by Blazy
Notice the condition upon the question - they are three POSITIVE, distinct integer roots.*

If -1, -2, and -13 are the roots, then you'll have the cubic equation:

(x+1)(x+2)(x+13) (x+1)(x+2)(x+13)

But 1×2×1326 1 \times 2 \times 13 \neq -26 , so -1, -2 and -13 can't be the three roots (plus they're not even positive in the first place)


Got it, thanks.
Reply 9
Original post by Math12345
If rir_i are the roots of the polynomial i=0naixi\displaystyle\sum_{i=0}^n a_i x^i, then ri=(1)na0\displaystyle \prod r_i =(-1)^n a_0. Use the fact that rirjr_i \not = r_j if iji \not= j, and that riNr_i \in N


I wish I understood this.

TheMagicMan is being almost deliberately confusing, introducing notation that simply isn't necessary for this question. He's essentially just expressing what the question says in words with symbols, presumably because that satisfies him or something. I can't see how he could've thought it would help you in any way.

It really isn't relevant, but in case you'd like to know what he means (it's not as hard as it looks):

i=0naixi\displaystyle\sum_{i=0}^n a_i x^i

Means:

a0x0+a1x+a2x2+a3x3++anxn\displaystyle a_0 x^0 + a_1 x + a_2 x^2 + a_3 x^3 + \cdots + a_n x^n

a4 just represents some general constant that is multiplied by the x4 term. You could call it "the x4 coefficient". As such the expression above involving that capital sigma (the big E-like symbol) is just a way of expressing some general polynomial (of degree n).

ri\displaystyle \prod r_i , which should really be written as i=1nri\displaystyle \prod_{i=1}^n r_i

Means:

r1×r2×r3××rn\displaystyle r_1 \times r_2 \times r_3 \times \cdots \times r_n

So looking back at the equation involving this capital pi, what we're trying to say is that the product of all the roots of the equation is equal to a0, the constant term of the polynomial. This is similar to what I said about fgh being equal to 26. The (-1)^n bit just comes about because if, say, 5 is a root of the equation, then in the factorised form it's going to appear as (x minus 5). When all these roots are multiplied together you'll potentially get a minus term floating around, depending on just how many things you multiply together.

rirjr_i \not = r_j if iji \not= j

This is just a fancy way of saying that the roots are all different. The second root of the equation, r2, is not equal to the fifth root of the equation, r5. Nor is the fifth root equal to the fourth root, and so on. The i just stands in for any number, as does j. When you run through all the combinations of roots, if you ask yourself, say, whether the third root of the equation equals the third root of the equation, the answer is obviously yes. Thus the i =/= j just says that the roots are all different, providing you don't consider the same root twice in your comparisons.

riNr_i \in N

This is just a fancy way of saying the roots are integers.
(edited 12 years ago)
Original post by porkstein
TheMagicMan is being almost deliberately confusing, introducing notation that simply isn't necessary for this question. He's essentially just expressing what the question says in words with symbols, presumably because that satisfies him or something. I can't see how he could've thought it would help you in any way.

It really isn't relevant, but in case you'd like to know what he means (it's not as hard as it looks):

i=0naixi\displaystyle\sum_{i=0}^n a_i x^i

Means:

a0x0+a1x+a2x2+a3x3++anxn\displaystyle a_0 x^0 + a_1 x + a_2 x^2 + a_3 x^3 + \cdots + a_n x^n

a4 just represents some general constant that is multiplied by the x4 term. You could call it "the x4 coefficient". As such the expression above involving that capital sigma (the big E-like symbol) is just a way of expressing some general polynomial (of degree n).

ri\displaystyle \prod r_i , which should really be written as i=1nri\displaystyle \prod_{i=1}^n r_i

Means:

r1×r2×r3××rn\displaystyle r_1 \times r_2 \times r_3 \times \cdots \times r_n

So looking back at the equation involving this capital pi, what we're trying to say is that the product of all the roots of the equation is equal to a0, the constant term of the polynomial. This is similar to what I said about fgh being equal to 26. The (-1)^n bit just comes about because if, say, 5 is a root of the equation, then in the factorised form it's going to appear as (x minus 5). When all these roots are multiplied together you'll potentially get a minus term floating around, depending on how many things you multiply together.

rirjr_i \not = r_j if iji \not= j

This is just a fancy way of saying that the roots are all different. The second root of the equation, r2, is not equal to the fifth root of the equation, r5. Nor is the fifth root equal to the fourth root, and so on. The i just stands in for any number, as does j. When you run through all the combinations of roots, if you ask yourself, say, whether the third root of the equation equals the third root of the equation, the answer is obviously yes. Thus the i =/= j just says that the roots are all different, providing you don't consider the same root twice in your comparisons.

riNr_i \in N

This is just a fancy way of saying the roots are integers.


There's really only one hint that's helpful in this problem...that the product of the roots is equal to the coefficient of x0x^0...as for the notation, it's a lot quicker than words, and most users of this site would understand it.

Also, when there is an 'obvious' range for the summation and product limits, there is really no need to put them on.

Anyhow, like most people here, I'm just trying to help, so...
Original post by TheMagicMan
...


It's certainly not quicker than words - I highly doubt it took you longer to write that 'helpful hint' than the mess of LaTeX you gave him. Given the OP is asking a question about additional maths, which even if one didn't know was a qualification for 16 year-olds is (from the question) evidently not particularly advanced stuff, I find it highly unlikely that (s)he would be comfortable throwing around summations and products and terms with subscript i in that fashion.

And if you're going to leave the limits off, at least be consistent in doing so.
Reply 12
Can somebody please post a solution with the answers

edit: nevermind
(edited 12 years ago)
I am sorry but why is everone confusing this kid on such a basic question.

If it is a cubic and the constant is -26, then the factors have to make -26.

Now let's take all the factors of -26; they are -1,-2,-13,-26.

A factor can not be -26, since then you would have -1 and -1 as the other two factors which aren't distinct. Therefore, the three factors are -1,-2,-13.

Therefore we see the equation can be written in this format:

(x-1)(x-2)(x-13)=0

The roots of the above equation are x=1,2,13: Three positive, distinct, integer roots!

Now simply expand the brackets and you get:

x^3–16x^2+41x–26 = 0.

Therefore, a =-16 and b=41
Original post by TheMagicMan
If rir_i are the roots of the polynomial i=0naixi\displaystyle\sum_{i=0}^n a_i x^i, then ri=(1)na0\prod r_i =(-1)^n a_0. Use the fact that rirjr_i \not = r_j if iji \not= j, and that riNr_i \in N


Don't try and act really clever with this. You are being annoying by trying to look so great and confusing the kid, when there is a very easy solution which you have failed to find with your "complex" method.
Original post by Blazy
Notice the condition upon the question - they are three POSITIVE, distinct integer roots.*

If -1, -2, and -13 are the roots, then you'll have the cubic equation:

(x+1)(x+2)(x+13) (x+1)(x+2)(x+13)

But 1×2×1326 1 \times 2 \times 13 \neq -26 , so -1, -2 and -13 can't be the three roots (plus they're not even positive in the first place)


i think he is confused between factors and roots.
Original post by GreenLantern1
Don't try and act really clever with this. You are being annoying by trying to look so great and confusing the kid, when there is a very easy solution which you have failed to find with your "complex" method.


It's not complex...it's exactly the same as whatever else has been suggested
Original post by TheMagicMan
It's not complex...it's exactly the same as whatever else has been suggested


No you have suggested a complex notation that the kid is clearly not going to understand when he is only 15/16 years old an is doing maths harder than the GCSE normally taken at his age.
Reply 18
Original post by TheMagicMan
It's not complex...it's exactly the same as whatever else has been suggested


You know what he means. There was just no need to use higher level notation for this question.

When you help someone with maths (in TSR or anywhere else), you should first consider the level and ability of the person that you are helping. Sometimes, you may think that you're helping out but really, you're just making them more confused.
Original post by TheMagicMan
If rir_i are the roots of the polynomial i=0naixi\displaystyle\sum_{i=0}^n a_i x^i, then anri=(1)na0a_n \prod r_i =(-1)^n a_0. Use the fact that rirjr_i \not = r_j if iji \not= j, and that riNr_i \in N


Did it make you feel better to give me a negative rating when you clearly were being an arrogant, pompous fool!

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