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Tuesday, May 25, 2010

Solving a binomial Using The Pascal's Triangle

The Pascal s triangle is to some extent useful in expanding a binomial. Before I go on, let me explain what a binomial is. A binomial could be defined as a mathematical expression of two terms which usually involves addition and subtraction. Examples are (y-1), (x+a)^2, (x-3)^3.


The Pascal s triangle makes the expansion of binomials with high powers easier and faster. The Pascal s triangle for a binomial with increasing power is the pattern of coefficient of the binomial as its power increases from a lower value to a higher value. It is best explained using an example. Lets take a binomial (x+1) increasing in power from (x+1)^1 to (x+1)^2 to (x+1)^3 on and on like that till we reach (x+1)^6 we have a pattern like the one below.



Binomial                                                                coefficient

(x+1)^1                                                                      1   1



(x+1)^2                                                                     1  2  1



(x+1)^3                                                                   1   3  3   1



(x+1)^4                                                                1   4   6   4    1



(x+1)^5                                                           1     5   10  10   5    1



(x+1)^6                                                       1    6    15    20  15    6    1.



This pattern of coefficients is what mathematicians commonly refer to as the Pascal s triangle. It is the same for all binomials. Pascal s triangle can be derived or was derived by a french philosopher called Pascal. For how it can be derived see Pascal s triangle.
 
Now let us give an example. Expand (y-1)^3.

Solution.

First of all we look at the power to which the binomial is raised which is 3.

Next we go to the Pascal's triangle and see the coefficients that correspond to a binomial raised to the power of 3 which are 1 3 3 1.

So (y-1)^3=1+3+3+1.

Next we identify the first and second terms which are y and -1 respectively.

Futhermore, we then multiply the first and second terms to the coefficients but know that the powers of the first term y decrease from the power of the binmial to 0 going from left to right while that of -1 increase from 0 to that of the binomial. See Pascal's triangle and binomial.

So (y-1)^3= 1(y)^3(-1)^0+3(y)^2(-1)^1+3(y)^1(-1)^2+1(y)^0(-1)^3
(y-1)^3= y^3-3y^2+3y-1

Thursday, May 6, 2010

Solving Simultaneous Equation Through Substitution Method

The substitution method is one of the ways through which one can solve simultaneous equations with two variables. The best way to explain it is through a worked example.


Solve the simultaneous equations using substitution method, x+2y= 3, 2x-4y= 8.

Step 1: Name the equations




                                          x+2y = 3..................(1.)



                                        2x-4y = 8..................(2.)
 
Step 2: From (1.), make x the subject of the eqn since eqn (1.) is simpler than eqn (2.).


So from (1.),

                     x+2y = 3



                    x= 3-2y.


Step 3: Now substitute for x in (2.).



So from (2.),


               2x-4y = 8 but x=3-2y



          so 2x-4y = 8 becomes



        2(3-2y)-4y= 8



          6-4y-4y = 8


              6-8y = 8



                -8y = 8-6



                -8y = 2



                   y = 2/-8

                   y = -1/4.



Step 4: To find x, substitute for y in (1.).




So from (1.),



          x+2y = 3 but y= -1/4



      so x+2y = 3 becomes



         x+2(-1/4)= 3



            x-1/2 = 3



           x = 3+1/2



           x = (6+1)/2



           x = 7/2



       So x = 7/2, y = -1/4.
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Tuesday, May 4, 2010

Simultaneous Equations Using Elimination Method

Introduction


The elimination method is one way to solve simultaneous equation. It is very useful really if the coeeficients of the equation are greater than one you. Let's proceed to see how this method can be used.

Solve the following simultaneous equation, 3a-4b= 1, 2a+3b= 5

(1.) 3a-4b=0, 2a+3b= 5

Solution

Name the equations

3a-4b= 1                                        (1)

2a+3b= 5                                       (2)

Then multiply eqn (1) by 2 and eqn (2) by 3

(3a-4b= 1)*2 and

(2a+3b= 5)*3 to give

6a-8b= 2                                          (3)

6a+9b=15                                        (4)

Subtract eqn (3) from (4)

6a+9b= 15

-

6a-8b= 2

17b= 13

b= 13/17

Substitute for b in (1).

So from (1)

3a-4b= 1

and since b= 13/17

3a-4(13/17)=1

3a-4.13/17= 1

3a-52/17= 1

3a= 1+52/17

3a= 17/1+52/17

3a= (17+52)/17

3a= 69/17

a= 69/17*1/3

a= 23/17

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