Difference between revisions of "One Root Equations Document"
(Created page with ' ='''One root equations''' = '''Written by Justin Stevens ''' Thanks to our contributors: AIME15 El_Ectric BOGTRO == 1.1 Deriving the quadratic formula == When we have a quad…') |
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− | + | '''One root equations''' | |
− | '''Written by Justin Stevens ''' | + | '''Written by Justin Stevens ''' |
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We are going to analyze the case when <math>\sqrt{b^2-4ac}=0</math> | We are going to analyze the case when <math>\sqrt{b^2-4ac}=0</math> | ||
− | <math> | + | <math>b^2-4ac</math> is called the '''discriminant.''' |
Square both sides to get: | Square both sides to get: | ||
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Let’s evaluate cases now. | Let’s evaluate cases now. | ||
− | + | ==1.2 The discriminant when a= c == | |
First we evaluate the case <math>a=c</math> | First we evaluate the case <math>a=c</math> | ||
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Therefore when <math>a=c</math> and <math>b=2a</math> we are going to have one root for the equation. | Therefore when <math>a=c</math> and <math>b=2a</math> we are going to have one root for the equation. | ||
− | + | === Example 1: === | |
<math>9x^2+18x+9x=0</math> | <math>9x^2+18x+9x=0</math> | ||
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− | + | === Example 2: === | |
<math>x^2+2x+1=0</math> | <math>x^2+2x+1=0</math> | ||
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Therefore we have <math>a=c=\frac{b}{2}</math> | Therefore we have <math>a=c=\frac{b}{2}</math> | ||
− | + | '''So, when <math>a=c=\frac{b}{2}</math> we will have one root, and that one root will be –1.''' | |
− | + | == 1.3 The discriminant when a=b == | |
When <math>a=b</math> we get: | When <math>a=b</math> we get: | ||
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So, our only case is <math>a=b=4c</math> | So, our only case is <math>a=b=4c</math> | ||
− | + | === Example 1: === | |
<math>4x^2+4x+1=0</math> | <math>4x^2+4x+1=0</math> | ||
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<math>\frac{-4}{8}=\boxed{\frac{-1}{2}}</math> | <math>\frac{-4}{8}=\boxed{\frac{-1}{2}}</math> | ||
− | + | === Example 2: === | |
<math>8x^2+8x+2=0</math> | <math>8x^2+8x+2=0</math> | ||
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<math>x=\boxed{\frac{-1}{2}}</math> | <math>x=\boxed{\frac{-1}{2}}</math> | ||
− | + | '''Therefore when <math>a=b=4c</math> we will have one root which will be <math>\frac{-1}{2}</math>''' | |
− | + | == 1.4 The discriminant when b=c == | |
<math>b^2-4ac=0</math> | <math>b^2-4ac=0</math> | ||
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− | + | === Example 1: === | |
<math>x^2+4x+4=0</math> | <math>x^2+4x+4=0</math> | ||
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<math>x=-2</math> | <math>x=-2</math> | ||
− | + | === Example 2: === | |
<math>2x^2+8x+8=0</math> | <math>2x^2+8x+8=0</math> | ||
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<math>x=\boxed{-2}</math> | <math>x=\boxed{-2}</math> | ||
− | + | '''Therefore when <math>b=c=4a</math> in <math>ax^2+bx+c=0</math>, the root is going to be <math>-2</math>''' | |
− | + | == 1.5 Conclusion == | |
When <math>a=\frac{b}{2}=c</math> we will have one root. That one root will be –1. | When <math>a=\frac{b}{2}=c</math> we will have one root. That one root will be –1. | ||
When <math>a=b=4c</math> we will have one root. That one root will be <math>\frac{-1}{2}</math> | When <math>a=b=4c</math> we will have one root. That one root will be <math>\frac{-1}{2}</math> | ||
When <math>4a=b=c</math> we will have one root. That one root will be –2 | When <math>4a=b=c</math> we will have one root. That one root will be –2 | ||
+ | |||
+ | == Contributors == | ||
+ | <nowiki>Thanks to our contributors: | ||
+ | AIME15 | ||
+ | El_Ectric | ||
+ | BOGTRO | ||
+ | bzprules | ||
+ | El_Ectric | ||
+ | SuperNerd123 | ||
+ | </nowiki> |
Revision as of 17:15, 1 June 2011
One root equations
Written by Justin Stevens
Contents
1.1 Deriving the quadratic formula
When we have a quadratic, we normally specify it in the form
The way to find a formula for the roots of the equations goes as follows:
\[\sqrt{(x+\frac{b}{2a})^2=\frac{b^2-4ac}{4a^2}\] (Error compiling LaTeX. Unknown error_msg)
We have two real roots when We have complex roots when We have one root when
We are going to analyze the case when
is called the discriminant.
Square both sides to get: Add to both sides to get:
Let’s evaluate cases now.
1.2 The discriminant when a= c
First we evaluate the case
When a=c, we have:
Take the square root of both sides to get:
Therefore when and we are going to have one root for the equation.
Example 1:
Example 2:
When and we can write the problem as follows:
Using the quadratic formula, we get:
A simpler way to do this, is to start off by dividing by a. We get:
If we want to write this as one equality, we can do as follows:
Divide by 2 on the second equation to get:
Therefore we have
So, when we will have one root, and that one root will be –1.
1.3 The discriminant when a=b
When we get:
The roots are going to be
Therefore we have: or
However, if (a,b)=0, we would be left with This is only a constant term left.
So, our only case is
Example 1:
Example 2:
Let’s find a general formula for this. If , we have:
Using the quadratic formula, we get:
Another way to do this, is to start off by dividing by c. Divide by 4 to get:
Therefore when we will have one root which will be
1.4 The discriminant when b=c
, therefore
The roots are going to be which gives us:
Since we get:
Divide by a to get:
However, since (a,b,x)=(0,0,0) this is just a case with only a quadratic term, and shouldn’t be considered.
Let’s try the second case of which is going to be
We have:
Example 1:
Example 2:
Let’s try an in-general example of when
Using the quadratic formula, we get
We can also start off by dividing by a to get:
Therefore when in , the root is going to be
1.5 Conclusion
When we will have one root. That one root will be –1. When we will have one root. That one root will be When we will have one root. That one root will be –2
Contributors
Thanks to our contributors: AIME15 El_Ectric BOGTRO bzprules El_Ectric SuperNerd123