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Friday, November 19, 2010

Quadratic functions - nature of roots


Find the range of values of k for which the quadratic equation
2x2 – 2x + k + 2 = kx has real roots.

This is a classic question that makes use of the determinant of the quadratic equation. The determinant of a quadratic equation is D = b2 – 4ac.

When D = 0, then it means that the equation has equal roots; i.e. the two answers of x for the quadratic equation are the same.

When D > 0, the roots will be real and distinct; i.e. there will be two different answers for x.

When D < 0, then the roots will be imaginary. This means that there are no answers to the quadratic equation and graphically, it means that the curve does not intersect the x axis at all.

Now, what about when the roots are simply real?  Then it means that D >= 0.  So, apply this to our question, we will first rearrange the equation so that it will equal to zero. Hence,

2x2 – 2x  - kx + k + 2 = 0

or

2x2 – (2 + k)x + (k + 2) = 0

For real roots,








Since this is a positive k2 function, then



Wednesday, November 17, 2010

Logarithms - change of base


Solve  log5x – 2logx5 = 1

In order for us to solve this question, we need to recall the change of base formula, which is:
We also know that we cannot have an unknown base. Hence, we need to change the logx5 into log5x.  Therefore, the equation can be expressed as:
Solving this gives:


And this is how we solve for logarithm questions with different base.

Hope this helps!

Friday, November 12, 2010

How to solve indices equations...

Today I want to talk about solving indices questions. There are basically two types of questions. The first is when 
                                                a f (x) = a g(x)

the base of each side of the equation is the same  (a). Hence,  f (x) = g(x). Of course, in this case, you must be able to simplify each side of the equation to the same base.  One hint: all the terms on each side are multiplied or divided with each other.

Let’s look at an example:

Solve:
 



In this case, you will see that the terms on LHS of the equation are multiplied with each other. Hence, we can use this form of solution; and first transform them into the same base viz,























The next type of question is the substitution question. Basically, this is when the terms in the equation are added (or subtracted) together, not multiplied. In this case, we are unable to simplify them into the same base for both sides (even if they are already of the same base!) because the terms are separated by a “+” or “-“ sign.  In this case, we will use the substitution method; as such:


































 So now, we have seen both types of questions that usually come with indices questions. Master them and you will be on your way to A Maths mastery….!

Have a great weekend!















Thursday, November 11, 2010

Solving absolute value equations...

Today I want to discuss a topic which I am sure not many students are clear about. How to solve absolute value equations. Although it may be simple, there are some equations that are a little tricky. I shall talk about all of them here today.

First, what is an absolute value function?  It is a function that will always yield positive results. It is written as such:  | f(x)|.  So |f(x)| = f(x) if  the value of f(x) is positive, but is -f(x) if the value of f(x) is negative.

Let me illustrate with an example.

Say I have an absolute value function  |x - 1|.  Now, x - 1 will be positive (or zero) if x = 1 or more. But if x is less than 1, then it will return a negative value. Correct?  So, then

|x - 1| = x - 1 when x ≥1; but is  -(x – 1) when x < 1
Hence, |x - 1| will return two functions, depending on what the value of x is.

Understand so far?

If you do, then let us look at the first equation to solve:    |x + 3| = 5

Then, it means that  x + 3 = 5   or    - (x + 3) = 5
Since the negative sign can be brought over to the other side of the equation, then the solution for

|x + 3| = 5 is   x + 3 = ± 5
Which means that x + 3 = 5   or    x + 3 = -5
Hence, x = 2 or x = -8.

So far so good, right?

Now, let’s go one step further. What happens when |f(x)| = g(x)?
Well, the same argument still applies.
The solution will be  f (x) = g(x)  or  f(x) = -g(x) and we solve for x for each of these cases.

For example,  solve for   |3x – 2| = 1 – x
In this case,
            3x – 2 = 1 – x              or                     3x – 2 = - (1 – x)
            3x + x = 3                                            3x – 2 = - 1 + x
            4x = 3                                                  2x = 1
            x = ¾                                                   x = ½
Hence,
            x = ½  or  ¾.

So far still here?
I hope so, because this is not rocket science.

Now, what happens if our question is  |f(x)| = |g(x)|?
Well in this case, the solution still remains the same way as above; i.e.
             f (x) = g(x)  or  f(x) = -g(x)
So there won’t be any examples for this.

But watch what happens with we have a constant term added to the above equation with two absolute value function, like this |f(x)| = a + |g(x)|? This will make things a little more troublesome.

In this case, we will need to identify which range of values of x there are and apply the right combination of positive or negative functions.  Let’s see an example of this to understand what I am trying to say…

Example we have
|3x – 2| = |1 – x | - 2

In this case, we will first need to see what combinations of positive and negative functions to use. We will take each of the functions in turn and determine the range of values of x for which they are positive.

So, if  3x – 2 > 0, then  x > ⅔
And if  1 – x > 0, then x < 1
So, in this case we have three regions:
Less than ⅔,   between ⅔ and 1 and greater than 1.

We have seen that for 3x – 2, it will yield a positive function only when x > ⅔. It means that for the region where x < ⅔, it would be negative.
For the case of 1 – x, we have seen that it will yield a positive value only when x < 1. Hence, for the region for x > 1, it will yield a negative value.
This now gives us the possibilities of values of x.

So, for the region x < ⅔, we will have the case of –(3x – 2) but +(1 – x). Hence, we will solve the equation:
-(3x – 2) = (1 – x) – 2
-3x + 2 = 1 – x – 2
-2x = - 3
x = 3/2

For the region of x in between ⅔ and 1,
            (3x – 2) = (1 – x) – 2
            3x – 2 = - x – 1
            4x = 1
            x = ¼

And finally, for the region where x > 1, we have
            3x – 2 = - (1 – x) – 2
            3x – 2 = -1 + x – 2
            2x = -1
            x = -½
So now, we have three solutions:  x = 3/2,  ¼  or 

This is not the end.  We now need to confirm which of these is valid. We will need to put it back into the equation  |3x – 2| = |1 – x | - 2

So, when x = 3/2, we have  5/2 = ½ - 2  and this is NOT valid.
When x = ¼ , we have   1¼ = - 1 ¼   so this is also not valid.
Lastly, when x = - ½   we have  5/2 = ½  and this is ALSO not valid.

In this case, there are no valid solutions to the equation, even if we thought we could find it. To confirm this, check out wolfram alpha at http://www.wolframalpha.com/input/?i=solve+abs%283x-1%29%3D%281-x%29-2
 
So here you have it. How to solve absolute value functions. The mathematics is easy but the understanding needs time to sink it. So let it sink in…

If you have any queries, please ask away…

Sunday, November 7, 2010

2010 Paper 2 Q11 - trigonometry




The diagram shows the curves y = 4 cosx  and y = 2 + 3sin x  for 0 ≤ x ≤ 2π radians. The points A and B are turning points on the curve y = 2 + 3sin x  and the point C is a turning point on the curve y = 4 cosx.  The curves intersect at the points D and E.
(i) Write down the coordinates of A, B and C.
(ii) Express the equation 4 cos x = 2 + 3 sin x in the form cos (x + α) = k, where α and k are constants to be found.
(iii) Hence, find in radian, the x-coordinate of D and of E.

(i)  Some of you might be tempted to use differentiation to solve for the coordinates of A, B and C. While that is not wrong, it is the worst possible way to do it. It will eat up all your time for something as fundamental as this.
To find the coordinates of A and B, we must remember that the sine curve has turning points at π/2 and 3π/2. Also, the max value of 3 sinx is 3 and the min value is -3. However, since the curve has moved up the y-axis by 2 units, then the max value of 2 + 3sin x is 5 and the min value of 2 + 3sin x is -1.
Therefore, the coordinates of A and B are (π/2 , 5) and (3π/2 , -1) respectively.
For C, the min point for cos x occurs at x = π.  The min value of 4 cos x = -4.  Hence, the coordinates of C are (π , -4)

(ii)  Given 4 cos x = 2 + 3 sin x
Therefore,  4 cos x – 3 sin x = 2
Let 4 cos x – 3 sin x R cos (x + α), where R2 = 42 + 32 = 25.  Hence, R = 5
                                                                                and tan α = ¾; i.e.  α = 0.644 radians
Hence  4 cos x – 3 sin x 5 cos (x + 0.644).


(iii)  To find the x-coordinate of D and E, therefore 5 cos (x + 0.644) = 2
                                cos (x + 0.644) = 0.4
                                x + 0.644 = 1.159 ,   2π – 1.159
                                                  = 1.159 ,  5.124
Therefore,
                                x = 1.159 - 0.644    or   x = 5.124 – 0.644
                                   = 0.515 radians               = 4.45 radians

The x-coordinates of D is 0.515 rad, and the x-coordinates of E is 4.45 rad.

2010 Paper 2 Q10 - partial fractions and integrals

Given that



where A, B and C are constants, find the value of A and B and show that C = 0.
(ii) Differentiate ln(x2 + 4) with respect to x.
(iii) Using the results from parts (i) and (ii), find




(i)  Since




Equating coefficients of x2, we have
A + 2B = 3   --- (1)
Equating coefficients of x, we get
B + 2C = 4   --- (2)
Equating constants, we have
4A + C = -20   ----(3)

From (1), A = 3 – 2B --- (4)
Sub (4) into (3), we get     4(3 – 2B) + C = - 20
                                                12 – 8B + C = -20
                                                -8B + C = -32 ---(5)
                                                B + 2C = 4  --- (2)
(5) x 2                                    -16B + 2C = -64 --- (6)
(2) – (6)                                                17B = 68
                                                B = 4
Sub B = 4 into (2), we get C = 0 (shown)
From (3)   4A = -20
                A = -5
Hence, A = -5, B = 4 and C = 0

(ii)




(iii) So,






From (ii),





so finally,
















2010 Paper 2 Q9 - coordinate geometry













The diagram shows a triangle ABC with vertices at A(0, 5), B(8, 14) and C(k, 15). Given that AB = BC,
(i) find the value of k,
A line is drawn from B to meet the x-axis at D such that AD = CD.
(ii) Find the equation of BD and the coordinates of D.
(iii) Show that the area of the triangle ABC is 2/7 of the area of the quadrilateral ABCD.

(i) Using Pythagoras’ theorem,
AB2 = BC2
So,
82 + 92 = (k – 8)2 + 12
64 + 81 – 1 = (k – 8)2
144 = (k – 8)2
k – 8 = ± 12
Since k is positive, therefore,
k = 8 + 12 = 20

(ii) For AD = CD, the line BD must be perpendicular to AC.
Hence, the gradient of BD = - 20/10 = -2
Equation of BD is  y = -2x + c
At (8, 14),   14 = -16 + c
                c = 30
Hence, the equation of BD is  y = -2x + 30
For the coordinates of D, which lies on the x-axis, y = 0
Therefore  x = 15
Hence, D(15, 0)

(iii) There are several ways to go about this. One way, is to find the area of the triangle using the coordinates (remember the anti-clockwise method?) and then the area of the quadrilateral and then find their ratio. Can, but too long, and not a clever option.
The next way is to find the height of the triangle and find the area using ½ base x height. And then do the same for the quadrilateral. Again, not a clever option.
The last way is a variant of the second one. Since the base of the triangle is the same for the smaller one and the larger one (the quad is made up of 2 triangles), then, the way to calculate the ratio of the areas is simply find the ratio of BM/BD, where M is the midpoint of AC.
So, M = (10, 10)
BM = √(22 + 42) = √(4 + 16) = √20 = 2√5
BD = √(72 + 142) = √(49 + 196) = √245 = 7√5
Hence, BM/BD = 2√5/7√5 = 2/7  (shown)

Notice something here. I did not go about finding the actual answer for each length. The reason was because the answer, 2/7, is a nice rounded number. With the radical (√) numbers, we know we will not get a nice round number. Hence, it gave me a hint that I should keep the radical sign and I expected that they would cancel each other.