Find remainder when $ 2x^{4}-x^{3}+4x-2 $ is divided by $ x-1 $.
Answer
The synthetic division table is:
$$ \begin{array}{c|rrrrr}1&2&-1&0&4&-2\\& & 2& 1& 1& \color{black}{5} \\ \hline &\color{blue}{2}&\color{blue}{1}&\color{blue}{1}&\color{blue}{5}&\color{orangered}{3} \end{array} $$The remainder when $ 2x^{4}-x^{3}+4x-2 $ is divided by $ x-1 $ is $ \, \color{red}{ 3 } $.
Explanation
We can find remainder using synthetic division method.
Step 1 : Write down the coefficients of the dividend into division table. Put the zero from $ x -1 = 0 $ ( $ x = \color{blue}{ 1 } $ ) at the left.
$$ \begin{array}{c|rrrrr}\color{blue}{1}&2&-1&0&4&-2\\& & & & & \\ \hline &&&&& \end{array} $$Step 1 : Bring down the leading coefficient to the bottom row.
$$ \begin{array}{c|rrrrr}1&\color{orangered}{ 2 }&-1&0&4&-2\\& & & & & \\ \hline &\color{orangered}{2}&&&& \end{array} $$Step 2 : Multiply by the number on the left, and carry the result into the next column: $ \color{blue}{ 1 } \cdot \color{blue}{ 2 } = \color{blue}{ 2 } $.
$$ \begin{array}{c|rrrrr}\color{blue}{1}&2&-1&0&4&-2\\& & \color{blue}{2} & & & \\ \hline &\color{blue}{2}&&&& \end{array} $$Step 3 : Add down last column: $ \color{orangered}{ -1 } + \color{orangered}{ 2 } = \color{orangered}{ 1 } $
$$ \begin{array}{c|rrrrr}1&2&\color{orangered}{ -1 }&0&4&-2\\& & \color{orangered}{2} & & & \\ \hline &2&\color{orangered}{1}&&& \end{array} $$Step 4 : Multiply by the number on the left, and carry the result into the next column: $ \color{blue}{ 1 } \cdot \color{blue}{ 1 } = \color{blue}{ 1 } $.
$$ \begin{array}{c|rrrrr}\color{blue}{1}&2&-1&0&4&-2\\& & 2& \color{blue}{1} & & \\ \hline &2&\color{blue}{1}&&& \end{array} $$Step 5 : Add down last column: $ \color{orangered}{ 0 } + \color{orangered}{ 1 } = \color{orangered}{ 1 } $
$$ \begin{array}{c|rrrrr}1&2&-1&\color{orangered}{ 0 }&4&-2\\& & 2& \color{orangered}{1} & & \\ \hline &2&1&\color{orangered}{1}&& \end{array} $$Step 6 : Multiply by the number on the left, and carry the result into the next column: $ \color{blue}{ 1 } \cdot \color{blue}{ 1 } = \color{blue}{ 1 } $.
$$ \begin{array}{c|rrrrr}\color{blue}{1}&2&-1&0&4&-2\\& & 2& 1& \color{blue}{1} & \\ \hline &2&1&\color{blue}{1}&& \end{array} $$Step 7 : Add down last column: $ \color{orangered}{ 4 } + \color{orangered}{ 1 } = \color{orangered}{ 5 } $
$$ \begin{array}{c|rrrrr}1&2&-1&0&\color{orangered}{ 4 }&-2\\& & 2& 1& \color{orangered}{1} & \\ \hline &2&1&1&\color{orangered}{5}& \end{array} $$Step 8 : Multiply by the number on the left, and carry the result into the next column: $ \color{blue}{ 1 } \cdot \color{blue}{ 5 } = \color{blue}{ 5 } $.
$$ \begin{array}{c|rrrrr}\color{blue}{1}&2&-1&0&4&-2\\& & 2& 1& 1& \color{blue}{5} \\ \hline &2&1&1&\color{blue}{5}& \end{array} $$Step 9 : Add down last column: $ \color{orangered}{ -2 } + \color{orangered}{ 5 } = \color{orangered}{ 3 } $
$$ \begin{array}{c|rrrrr}1&2&-1&0&4&\color{orangered}{ -2 }\\& & 2& 1& 1& \color{orangered}{5} \\ \hline &\color{blue}{2}&\color{blue}{1}&\color{blue}{1}&\color{blue}{5}&\color{orangered}{3} \end{array} $$Remainder is the last entry in the bottom row $ \left(\color{red}{ 3 }\right) $.