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Poly question (extension Cambridge q) (1 Viewer)

Kurosaki

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Division transformation is that you can express a polynomial A (the dividend), with divisor D, quotient Q and remainder R as:
, and the degree of R is less than that of D. So try thinking about what D and R are :). If you still can't figure it out I'll show you how to do it :).

And the MX1 exam was pretty easy, not too hard.
 
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iStudent

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Division transformation is that you can express a polynomial A (the dividend), with divisor D, quotient Q and remainder R as:
, and the degree of R is less than that of D. So try thinking about what D and R are :). If you still can't figure it out I'll show you how to do it :).

And the MX1 exam was pretty easy, not too hard.
You mean you smashed it and should get 70/70 and that you would've state ranked if not for internals :p
 

Drongoski

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Let P(x) = (x-p)(x-q)Q(x) + ax+b

.: P(p) = 0 + ap+b = p^3
& P(q) = 0 + aq+b = q^3

Solving the 2 simultaneous equations for a and b, you get:

a = p^2 + pq + q^2 and b = -pq(p+q)

.: remainder is (p^2+pq+q^2)x - pq(p+q)
 

hsc3hard5me

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Thanks, I have another question I'm struggling to get, it looks really easy but I don't know how to get the answer:

 

Carrotsticks

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You can find M easily by using the fact that there is a root at x=-2, in other words P(-2)=0.

Now that you have M, you can use the sum of roots.

Note that the roots are -2, A and A, so the sum of roots is -2+2A. Compare that to the sum of roots by observing the coefficients and you can solve for A.
 

Axio

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Let P(x) = (x-p)(x-q)Q(x) + ax+b
.: P(p) = 0 + ap+b = p^3
& P(q) = 0 + aq+b = q^3

Solving the 2 simultaneous equations for a and b, you get:

a = p^2 + pq + q^2 and b = -pq(p+q)

.: remainder is (p^2+pq+q^2)x - pq(p+q)
With this, how do you know that the remainder is linear? (Or does it not matter)
 

Trebla

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With this, how do you know that the remainder is linear? (Or does it not matter)
Division by a quadratic always yields a remainder of a lower degree than the quadratic (ie a linear or constant function). If the 'remainder' has a degree greater than or equal to the degree of the quadratic then it is not really a true 'remainder' because further division can be carried out
 

hsc3hard5me

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You can find M easily by using the fact that there is a root at x=-2, in other words P(-2)=0.

Now that you have M, you can use the sum of roots.

Note that the roots are -2, A and A, so the sum of roots is -2+2A. Compare that to the sum of roots by observing the coefficients and you can solve for A.
I tried subbing in x=-2 but it m ends up cancelling out and the equation ends up as 0=0
 

Carrotsticks

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Oh dear, my response was incorrect anyway. I did not see that the second term was an x term, not an x^2 term. Ignore that please =)

The sum of roots is zero since the x^2 term has a zero coefficient (which is why it is not there).

2A - 2 = 0

A=1.

Now that you have all three roots, you can use the product of roots to calculate M.
 

hsc3hard5me

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Oh dear, my response was incorrect anyway. I did not see that the second term was an x term, not an x^2 term. Ignore that please =)

The sum of roots is zero since the x^2 term has a zero coefficient (which is why it is not there).

2A - 2 = 0

A=1.

Now that you have all three roots, you can use the product of roots to calculate M.
Thanks, that explained it quickly!
 

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