Step by Step Solution
Rearrange:
Rearrange the equation by subtracting what is to the right of the equal sign from both sides of the equation :
6*x/x+5-(2*x-20/x+5)=0
Step by step solution :
Step 1 :
20
Simplify ——
x
Equation at the end of step 1 :
x 20
((6•—)+5)-((2x-——)+5) = 0
x x
Step 2 :
Rewriting the whole as an Equivalent Fraction :
2.1 Subtracting a fraction from a whole
Rewrite the whole as a fraction using x as the denominator :
2x 2x • x
2x = —— = ——————
1 x
Equivalent fraction : The fraction thus generated looks different but has the same value as the whole
Common denominator : The equivalent fraction and the other fraction involved in the calculation share the same denominator
Adding fractions that have a common denominator :
2.2 Adding up the two equivalent fractions
Add the two equivalent fractions which now have a common denominator
Combine the numerators together, put the sum or difference over the common denominator then reduce to lowest terms if possible:
2x • x - (20) 2x2 - 20
————————————— = ————————
x x
Equation at the end of step 2 :
x (2x2 - 20)
((6 • —) + 5) - (—————————— + 5) = 0
x x
Step 3 :
Rewriting the whole as an Equivalent Fraction :
3.1 Adding a whole to a fraction
Rewrite the whole as a fraction using x as the denominator :
5 5 • x
5 = — = —————
1 x
Step 4 :
Pulling out like terms :
4.1 Pull out like factors :
2x2 - 20 = 2 • (x2 - 10)
Trying to factor as a Difference of Squares :
4.2 Factoring: x2 - 10
Theory : A difference of two perfect squares, A2 - B2 can be factored into (A+B) • (A-B)
Proof : (A+B) • (A-B) =
A2 - AB + BA - B2 =
A2 - AB + AB - B2 =
A2 - B2
Note : AB = BA is the commutative property of multiplication.
Note : - AB + AB equals zero and is therefore eliminated from the expression.
Check : 10 is not a square !!
Ruling : Binomial can not be factored as the difference of two perfect squares.
Adding fractions that have a common denominator :
4.3 Adding up the two equivalent fractions
2 • (x2-10) + 5 • x 2x2 + 5x - 20
——————————————————— = —————————————
x x
Equation at the end of step 4 :
x (2x2 + 5x - 20)
((6 • —) + 5) - ——————————————— = 0
x x
Step 5 :
x
Simplify —
x
Equation at the end of step 5 :
(2x2 + 5x - 20)
((6 • 1) + 5) - ——————————————— = 0
x
Step 6 :
Rewriting the whole as an Equivalent Fraction :
6.1 Subtracting a fraction from a whole
Rewrite the whole as a fraction using x as the denominator :
11 11 • x
11 = —— = ——————
1 x
Trying to factor by splitting the middle term
6.2 Factoring 2x2 + 5x - 20
The first term is, 2x2 its coefficient is 2 .
The middle term is, +5x its coefficient is 5 .
The last term, "the constant", is -20
Step-1 : Multiply the coefficient of the first term by the constant 2 • -20 = -40
Step-2 : Find two factors of -40 whose sum equals the coefficient of the middle term, which is 5 .
| -40 | + | 1 | = | -39 | ||
| -20 | + | 2 | = | -18 | ||
| -10 | + | 4 | = | -6 | ||
| -8 | + | 5 | = | -3 | ||
| -5 | + | 8 | = | 3 | ||
| -4 | + | 10 | = | 6 | ||
| -2 | + | 20 | = | 18 | ||
| -1 | + | 40 | = | 39 |
Observation : No two such factors can be found !!
Conclusion : Trinomial can not be factored
Adding fractions that have a common denominator :
6.3 Adding up the two equivalent fractions
11 • x - ((2x2+5x-20)) -2x2 + 6x + 20
—————————————————————— = ——————————————
x x
Step 7 :
Pulling out like terms :
7.1 Pull out like factors :
-2x2 + 6x + 20 = -2 • (x2 - 3x - 10)
Trying to factor by splitting the middle term
7.2 Factoring x2 - 3x - 10
The first term is, x2 its coefficient is 1 .
The middle term is, -3x its coefficient is -3 .
The last term, "the constant", is -10
Step-1 : Multiply the coefficient of the first term by the constant 1 • -10 = -10
Step-2 : Find two factors of -10 whose sum equals the coefficient of the middle term, which is -3 .
| -10 | + | 1 | = | -9 | ||
| -5 | + | 2 | = | -3 | That's it |
Step-3 : Rewrite the polynomial splitting the middle term using the two factors found in step 2 above, -5 and 2
x2 - 5x + 2x - 10
Step-4 : Add up the first 2 terms, pulling out like factors :
x • (x-5)
Add up the last 2 terms, pulling out common factors :
2 • (x-5)
Step-5 : Add up the four terms of step 4 :
(x+2) • (x-5)
Which is the desired factorization
Equation at the end of step 7 :
-2 • (x + 2) • (x - 5)
—————————————————————— = 0
x
Step 8 :
When a fraction equals zero :
8.1 When a fraction equals zero ...Where a fraction equals zero, its numerator, the part which is above the fraction line, must equal zero.
Now,to get rid of the denominator, Tiger multiplys both sides of the equation by the denominator.
Here's how:
-2•(x+2)•(x-5)
—————————————— • x = 0 • x
x
Now, on the left hand side, the x cancels out the denominator, while, on the right hand side, zero times anything is still zero.
The equation now takes the shape :
-2 • (x+2) • (x-5) = 0
Theory - Roots of a product :
8.2 A product of several terms equals zero.
When a product of two or more terms equals zero, then at least one of the terms must be zero.
We shall now solve each term = 0 separately
In other words, we are going to solve as many equations as there are terms in the product
Any solution of term = 0 solves product = 0 as well.
Equations which are never true :
8.3 Solve : -2 = 0
This equation has no solution.
A a non-zero constant never equals zero.
Solving a Single Variable Equation :
8.4 Solve : x+2 = 0
Subtract 2 from both sides of the equation :
x = -2
Solving a Single Variable Equation :
8.5 Solve : x-5 = 0
Add 5 to both sides of the equation :
x = 5
Supplement : Solving Quadratic Equation Directly
Solving x2-3x-10 = 0 directly Earlier we factored this polynomial by splitting the middle term. let us now solve the equation by Completing The Square and by using the Quadratic Formula
Parabola, Finding the Vertex :
9.1 Find the Vertex of y = x2-3x-10
Parabolas have a highest or a lowest point called the Vertex . Our parabola opens up and accordingly has a lowest point (AKA absolute minimum) . We know this even before plotting "y" because the coefficient of the first term, 1 , is positive (greater than zero).
Each parabola has a vertical line of symmetry that passes through its vertex. Because of this symmetry, the line of symmetry would, for example, pass through the midpoint of the two x -intercepts (roots or solutions) of the parabola. That is, if the parabola has indeed two real solutions.
Parabolas can model many real life situations, such as the height above ground, of an object thrown upward, after some period of time. The vertex of the parabola can provide us with information, such as the maximum height that object, thrown upwards, can reach. For this reason we want to be able to find the coordinates of the vertex.
For any parabola,Ax2+Bx+C,the x -coordinate of the vertex is given by -B/(2A) . In our case the x coordinate is 1.5000
Plugging into the parabola formula 1.5000 for x we can calculate the y -coordinate :
y = 1.0 * 1.50 * 1.50 - 3.0 * 1.50 - 10.0
or y = -12.250
Parabola, Graphing Vertex and X-Intercepts :
Root plot for : y = x2-3x-10
Axis of Symmetry (dashed) {x}={ 1.50}
Vertex at {x,y} = { 1.50,-12.25}
x -Intercepts (Roots) :
Root 1 at {x,y} = {-2.00, 0.00}
Root 2 at {x,y} = { 5.00, 0.00}
Solve Quadratic Equation by Completing The Square
9.2 Solving x2-3x-10 = 0 by Completing The Square .
Add 10 to both side of the equation :
x2-3x = 10
Now the clever bit: Take the coefficient of x , which is 3 , divide by two, giving 3/2 , and finally square it giving 9/4
Add 9/4 to both sides of the equation :
On the right hand side we have :
10 + 9/4 or, (10/1)+(9/4)
The common denominator of the two fractions is 4 Adding (40/4)+(9/4) gives 49/4
So adding to both sides we finally get :
x2-3x+(9/4) = 49/4
Adding 9/4 has completed the left hand side into a perfect square :
x2-3x+(9/4) =
(x-(3/2)) • (x-(3/2)) =
(x-(3/2))2
Things which are equal to the same thing are also equal to one another. Since
x2-3x+(9/4) = 49/4 and
x2-3x+(9/4) = (x-(3/2))2
then, according to the law of transitivity,
(x-(3/2))2 = 49/4
We'll refer to this Equation as Eq. #9.2.1
The Square Root Principle says that When two things are equal, their square roots are equal.
Note that the square root of
(x-(3/2))2 is
(x-(3/2))2/2 =
(x-(3/2))1 =
x-(3/2)
Now, applying the Square Root Principle to Eq. #9.2.1 we get:
x-(3/2) = √ 49/4
Add 3/2 to both sides to obtain:
x = 3/2 + √ 49/4
Since a square root has two values, one positive and the other negative
x2 - 3x - 10 = 0
has two solutions:
x = 3/2 + √ 49/4
or
x = 3/2 - √ 49/4
Note that √ 49/4 can be written as
√ 49 / √ 4 which is 7 / 2
Solve Quadratic Equation using the Quadratic Formula
9.3 Solving x2-3x-10 = 0 by the Quadratic Formula .
According to the Quadratic Formula, x , the solution for Ax2+Bx+C = 0 , where A, B and C are numbers, often called coefficients, is given by :
- B ± √ B2-4AC
x = ————————
2A
In our case, A = 1
B = -3
C = -10
Accordingly, B2 - 4AC =
9 - (-40) =
49
Applying the quadratic formula :
3 ± √ 49
x = —————
2
Can √ 49 be simplified ?
Yes! The prime factorization of 49 is
7•7
To be able to remove something from under the radical, there have to be 2 instances of it (because we are taking a square i.e. second root).
√ 49 = √ 7•7 =
± 7 • √ 1 =
± 7
So now we are looking at:
x = ( 3 ± 7) / 2
Two real solutions:
x =(3+√49)/2=(3+7)/2= 5.000
or:
x =(3-√49)/2=(3-7)/2= -2.000
Two solutions were found :
- x = 5
- x = -2
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