Answer
Verified
399.3k+ views
Hint:Use log properties to solve the given equation
The very first step to solve these types of problems is to use the addition and subtraction log properties. We know that $\log a + \log b = \log (ab)$ and $\log a - \log b = \log \dfrac{a}{b}$. So, after using the given properties on the above question, we will get a much simplified version of the question. To move forward we will use the $\log a - \log b = \log \dfrac{a}{b}$ property and then move forward to equate the argument part inside the equation to 0. Solving the equation we will get our final answer.
Complete step by step solution:
The given question we have is ${\log _5}(x - 1) + {\log _5}(x - 2) - {\log _5}(x + 6) = 0$
Now, we will use a simple property of log, and that is
$\log a - \log b = \log \dfrac{a}{b}$
So, applying this rule to the question, the modified version of the question will be:-
$
{\log _5}(x - 1) + \left[ {{{\log }_5}(x - 2) - {{\log }_5}(x + 6)} \right] = 0 \\
{\log _5}(x - 1) + \left[ {{{\log }_5}\left( {\dfrac{{x - 2}}{{x + 6}}} \right)} \right] = 0 \\
$
Now, we will use another log property which states that:-
$\log a + \log b = \log (ab)$
So, when we use this property, our modified version of the question will be:-
$
{\log _5}(x - 1) + \left[ {{{\log }_5}\left( {\dfrac{{x - 2}}{{x + 6}}} \right)} \right] = 0 \\
\Rightarrow {\log _5}\left[ {\left( {x - 1} \right) \times \left( {\dfrac{{x - 2}}{{x + 6}}} \right)} \right] = 0 \\
\Rightarrow {\log _5}\left[ {\dfrac{{\left( {x - 1} \right)\left( {x - 2} \right)}}{{x + 6}}} \right] = 0
\\
\Rightarrow {\log _5}\left[ {\dfrac{{{x^2} - 2x - x + 2}}{{x + 6}}} \right] = 0 \\
\Rightarrow {\log _5}\left[ {\dfrac{{{x^2} - 3x + 2}}{{x + 6}}} \right] = 0 \\
$
To further simplify this step, we will use another property which states that:-
If,
$
{\log _b}a = x \\
\Rightarrow {b^x} = a \\
$
So, if we use this property on the above question, we will get:-
\[
{\log _5}\left[ {\dfrac{{{x^2} - 3x + 2}}{{x + 6}}} \right] = 0 \\
\Rightarrow {5^0} = \dfrac{{{x^2} - 3x + 2}}{{x + 6}} \\
\Rightarrow 1 = \dfrac{{{x^2} - 3x + 2}}{{x + 6}} \\
\Rightarrow x + 6 = {x^2} - 3x + 2 \\
\]
Subtracting x from both the sides we will get:-
\[
x + 6 = {x^2} - 3x + 2 \\
x + 6 - x = {x^2} - 3x + 2 - x \\
6 = {x^2} - 4x + 2 \\
\]
Subtracting 2 from both the sides we will get:-
\[
6 = {x^2} - 4x + 2 \\
6 - 2 = {x^2} - 4x + 2 - 2 \\
4 = {x^2} - 4x \\
\]
Subtracting 4 from both the sides we will get:-
\[
4 = {x^2} - 4x \\
4 - 4 = {x^2} - 4x - 4 \\
{x^2} - 4x - 4 = 0 \\
\]
To solve this step we will use the quadratic formula method \[x = \dfrac{{ - b \pm \sqrt {{b^2} - 4ac} }}{{2a}}\]
Here,
a=1
b=-4 and c=-4
so,
\[
x = \dfrac{{ - ( - 4) \pm \sqrt {{{( - 4)}^2} - 4(1)( - 4)} }}{{2(1)}} \\
x = \dfrac{{4 \pm \sqrt {16 + 16} }}{2} \\
x = \dfrac{{4 \pm \sqrt {32} }}{2} \\
x = \dfrac{{4 \pm \sqrt {16 \times 2} }}{2} \\
x = \dfrac{{4 \pm 4\sqrt 2 }}{2} \\
x = \dfrac{{2\left( {2 \pm 2\sqrt 2 } \right)}}{2} \\
x = 2 \pm 2\sqrt 2 \\
\]
Note: You must not simply add and subtract the arguments inside the log to solve these problems. Logs don’t work that way. For addition and subtraction of logs, you must use the above mentioned formulas. Logs are special terms in mathematics and hence, their addition, subtraction is quite different from others. If you do it the normal way, you will end up getting the wrong answers.
The very first step to solve these types of problems is to use the addition and subtraction log properties. We know that $\log a + \log b = \log (ab)$ and $\log a - \log b = \log \dfrac{a}{b}$. So, after using the given properties on the above question, we will get a much simplified version of the question. To move forward we will use the $\log a - \log b = \log \dfrac{a}{b}$ property and then move forward to equate the argument part inside the equation to 0. Solving the equation we will get our final answer.
Complete step by step solution:
The given question we have is ${\log _5}(x - 1) + {\log _5}(x - 2) - {\log _5}(x + 6) = 0$
Now, we will use a simple property of log, and that is
$\log a - \log b = \log \dfrac{a}{b}$
So, applying this rule to the question, the modified version of the question will be:-
$
{\log _5}(x - 1) + \left[ {{{\log }_5}(x - 2) - {{\log }_5}(x + 6)} \right] = 0 \\
{\log _5}(x - 1) + \left[ {{{\log }_5}\left( {\dfrac{{x - 2}}{{x + 6}}} \right)} \right] = 0 \\
$
Now, we will use another log property which states that:-
$\log a + \log b = \log (ab)$
So, when we use this property, our modified version of the question will be:-
$
{\log _5}(x - 1) + \left[ {{{\log }_5}\left( {\dfrac{{x - 2}}{{x + 6}}} \right)} \right] = 0 \\
\Rightarrow {\log _5}\left[ {\left( {x - 1} \right) \times \left( {\dfrac{{x - 2}}{{x + 6}}} \right)} \right] = 0 \\
\Rightarrow {\log _5}\left[ {\dfrac{{\left( {x - 1} \right)\left( {x - 2} \right)}}{{x + 6}}} \right] = 0
\\
\Rightarrow {\log _5}\left[ {\dfrac{{{x^2} - 2x - x + 2}}{{x + 6}}} \right] = 0 \\
\Rightarrow {\log _5}\left[ {\dfrac{{{x^2} - 3x + 2}}{{x + 6}}} \right] = 0 \\
$
To further simplify this step, we will use another property which states that:-
If,
$
{\log _b}a = x \\
\Rightarrow {b^x} = a \\
$
So, if we use this property on the above question, we will get:-
\[
{\log _5}\left[ {\dfrac{{{x^2} - 3x + 2}}{{x + 6}}} \right] = 0 \\
\Rightarrow {5^0} = \dfrac{{{x^2} - 3x + 2}}{{x + 6}} \\
\Rightarrow 1 = \dfrac{{{x^2} - 3x + 2}}{{x + 6}} \\
\Rightarrow x + 6 = {x^2} - 3x + 2 \\
\]
Subtracting x from both the sides we will get:-
\[
x + 6 = {x^2} - 3x + 2 \\
x + 6 - x = {x^2} - 3x + 2 - x \\
6 = {x^2} - 4x + 2 \\
\]
Subtracting 2 from both the sides we will get:-
\[
6 = {x^2} - 4x + 2 \\
6 - 2 = {x^2} - 4x + 2 - 2 \\
4 = {x^2} - 4x \\
\]
Subtracting 4 from both the sides we will get:-
\[
4 = {x^2} - 4x \\
4 - 4 = {x^2} - 4x - 4 \\
{x^2} - 4x - 4 = 0 \\
\]
To solve this step we will use the quadratic formula method \[x = \dfrac{{ - b \pm \sqrt {{b^2} - 4ac} }}{{2a}}\]
Here,
a=1
b=-4 and c=-4
so,
\[
x = \dfrac{{ - ( - 4) \pm \sqrt {{{( - 4)}^2} - 4(1)( - 4)} }}{{2(1)}} \\
x = \dfrac{{4 \pm \sqrt {16 + 16} }}{2} \\
x = \dfrac{{4 \pm \sqrt {32} }}{2} \\
x = \dfrac{{4 \pm \sqrt {16 \times 2} }}{2} \\
x = \dfrac{{4 \pm 4\sqrt 2 }}{2} \\
x = \dfrac{{2\left( {2 \pm 2\sqrt 2 } \right)}}{2} \\
x = 2 \pm 2\sqrt 2 \\
\]
Note: You must not simply add and subtract the arguments inside the log to solve these problems. Logs don’t work that way. For addition and subtraction of logs, you must use the above mentioned formulas. Logs are special terms in mathematics and hence, their addition, subtraction is quite different from others. If you do it the normal way, you will end up getting the wrong answers.
Recently Updated Pages
How many sigma and pi bonds are present in HCequiv class 11 chemistry CBSE
Mark and label the given geoinformation on the outline class 11 social science CBSE
When people say No pun intended what does that mea class 8 english CBSE
Name the states which share their boundary with Indias class 9 social science CBSE
Give an account of the Northern Plains of India class 9 social science CBSE
Change the following sentences into negative and interrogative class 10 english CBSE
Trending doubts
Difference between Prokaryotic cell and Eukaryotic class 11 biology CBSE
Fill the blanks with the suitable prepositions 1 The class 9 english CBSE
Differentiate between homogeneous and heterogeneous class 12 chemistry CBSE
Which are the Top 10 Largest Countries of the World?
10 examples of evaporation in daily life with explanations
Give 10 examples for herbs , shrubs , climbers , creepers
Change the following sentences into negative and interrogative class 10 english CBSE
Write a letter to the principal requesting him to grant class 10 english CBSE
Difference Between Plant Cell and Animal Cell