How to quickly solve partial fractions equation? The 2019 Stack Overflow Developer Survey...

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How to quickly solve partial fractions equation?

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How to quickly solve partial fractions equation?



The 2019 Stack Overflow Developer Survey Results Are InHow can this indefinite integral be solved without partial fractions?Separation of variables and substituion; first integral from the Euler-Differential Equation for the minimal surface problemHow to set up partial fractions?How to solve $int frac{,dx}{(x^3 + x + 1)^3}$?How to solve this integral by parts?Integration of rational functions by partial fractionsCompute $int _0 ^infty frac{x^alpha}{1+x^2}, mathrm d x$ for $-1<alpha<1$How can $int frac{dx}{(x+a)^2(x+b)^2}$ be found?Solve $int frac{1}{cos^2(x)+cos(x)+1}dx$How do I solve this trivial complex integral $int^w_0 frac{bz}{(z-a)(z+a)}textrm{d}z$?












2












$begingroup$


Often I am dealing with an integral of let's say:



$$intfrac{dt}{(t-2)(t+3)}$$



or



$$int frac{dt}{t(t-4)}$$



or to make this a more general case in which I am interested the most:



$$int frac{dt}{(t+alpha)(t+beta)} quad quad alpha, beta in mathbb{R}$$



Basically any integral with decomposed polynomial of second degree in the denominator. Obviously this leads to sum of two natural logarithms.



What I do is write down partial fractions equation and then solve system of linear equations (2 variables here):



$$frac{1}{(t+alpha)(t+beta)} = frac{A}{t+alpha} + frac{B}{t+beta}$$



After solving this I end up with some $A, B$ coefficients and I can solve the integral.



Is there faster way to find $A, B$ ? Some algorithm or anything that I can follow and would always work for such case? Surely, solving that does not take much time but I just wonder if it could be done even faster.



(bonus question: what if there were more variables, like 3 variables?)



I would greatly appreciate all feedback as it could help me save countless number of minutes in the future.










share|cite|improve this question











$endgroup$








  • 1




    $begingroup$
    Don't you mean find $A,B$? $alpha,beta$ are usually given.
    $endgroup$
    – Eevee Trainer
    4 hours ago










  • $begingroup$
    Yes. Fixed. Thank you!
    $endgroup$
    – weno
    4 hours ago










  • $begingroup$
    Also when I think about it, I wonder if there's even a general method (beyond the one you referred to). I can see very easily a general solution for when (i) the numerator is $1$ (ii) $alpha ne beta$ (iii) we only have a product of two factors in the denominator, but that's such a narrow set of circumstances that I wonder if it's worth it. Maybe someone has a more general form though.
    $endgroup$
    – Eevee Trainer
    4 hours ago
















2












$begingroup$


Often I am dealing with an integral of let's say:



$$intfrac{dt}{(t-2)(t+3)}$$



or



$$int frac{dt}{t(t-4)}$$



or to make this a more general case in which I am interested the most:



$$int frac{dt}{(t+alpha)(t+beta)} quad quad alpha, beta in mathbb{R}$$



Basically any integral with decomposed polynomial of second degree in the denominator. Obviously this leads to sum of two natural logarithms.



What I do is write down partial fractions equation and then solve system of linear equations (2 variables here):



$$frac{1}{(t+alpha)(t+beta)} = frac{A}{t+alpha} + frac{B}{t+beta}$$



After solving this I end up with some $A, B$ coefficients and I can solve the integral.



Is there faster way to find $A, B$ ? Some algorithm or anything that I can follow and would always work for such case? Surely, solving that does not take much time but I just wonder if it could be done even faster.



(bonus question: what if there were more variables, like 3 variables?)



I would greatly appreciate all feedback as it could help me save countless number of minutes in the future.










share|cite|improve this question











$endgroup$








  • 1




    $begingroup$
    Don't you mean find $A,B$? $alpha,beta$ are usually given.
    $endgroup$
    – Eevee Trainer
    4 hours ago










  • $begingroup$
    Yes. Fixed. Thank you!
    $endgroup$
    – weno
    4 hours ago










  • $begingroup$
    Also when I think about it, I wonder if there's even a general method (beyond the one you referred to). I can see very easily a general solution for when (i) the numerator is $1$ (ii) $alpha ne beta$ (iii) we only have a product of two factors in the denominator, but that's such a narrow set of circumstances that I wonder if it's worth it. Maybe someone has a more general form though.
    $endgroup$
    – Eevee Trainer
    4 hours ago














2












2








2





$begingroup$


Often I am dealing with an integral of let's say:



$$intfrac{dt}{(t-2)(t+3)}$$



or



$$int frac{dt}{t(t-4)}$$



or to make this a more general case in which I am interested the most:



$$int frac{dt}{(t+alpha)(t+beta)} quad quad alpha, beta in mathbb{R}$$



Basically any integral with decomposed polynomial of second degree in the denominator. Obviously this leads to sum of two natural logarithms.



What I do is write down partial fractions equation and then solve system of linear equations (2 variables here):



$$frac{1}{(t+alpha)(t+beta)} = frac{A}{t+alpha} + frac{B}{t+beta}$$



After solving this I end up with some $A, B$ coefficients and I can solve the integral.



Is there faster way to find $A, B$ ? Some algorithm or anything that I can follow and would always work for such case? Surely, solving that does not take much time but I just wonder if it could be done even faster.



(bonus question: what if there were more variables, like 3 variables?)



I would greatly appreciate all feedback as it could help me save countless number of minutes in the future.










share|cite|improve this question











$endgroup$




Often I am dealing with an integral of let's say:



$$intfrac{dt}{(t-2)(t+3)}$$



or



$$int frac{dt}{t(t-4)}$$



or to make this a more general case in which I am interested the most:



$$int frac{dt}{(t+alpha)(t+beta)} quad quad alpha, beta in mathbb{R}$$



Basically any integral with decomposed polynomial of second degree in the denominator. Obviously this leads to sum of two natural logarithms.



What I do is write down partial fractions equation and then solve system of linear equations (2 variables here):



$$frac{1}{(t+alpha)(t+beta)} = frac{A}{t+alpha} + frac{B}{t+beta}$$



After solving this I end up with some $A, B$ coefficients and I can solve the integral.



Is there faster way to find $A, B$ ? Some algorithm or anything that I can follow and would always work for such case? Surely, solving that does not take much time but I just wonder if it could be done even faster.



(bonus question: what if there were more variables, like 3 variables?)



I would greatly appreciate all feedback as it could help me save countless number of minutes in the future.







calculus integration indefinite-integrals quadratics partial-fractions






share|cite|improve this question















share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited 4 hours ago







weno

















asked 4 hours ago









wenoweno

42311




42311








  • 1




    $begingroup$
    Don't you mean find $A,B$? $alpha,beta$ are usually given.
    $endgroup$
    – Eevee Trainer
    4 hours ago










  • $begingroup$
    Yes. Fixed. Thank you!
    $endgroup$
    – weno
    4 hours ago










  • $begingroup$
    Also when I think about it, I wonder if there's even a general method (beyond the one you referred to). I can see very easily a general solution for when (i) the numerator is $1$ (ii) $alpha ne beta$ (iii) we only have a product of two factors in the denominator, but that's such a narrow set of circumstances that I wonder if it's worth it. Maybe someone has a more general form though.
    $endgroup$
    – Eevee Trainer
    4 hours ago














  • 1




    $begingroup$
    Don't you mean find $A,B$? $alpha,beta$ are usually given.
    $endgroup$
    – Eevee Trainer
    4 hours ago










  • $begingroup$
    Yes. Fixed. Thank you!
    $endgroup$
    – weno
    4 hours ago










  • $begingroup$
    Also when I think about it, I wonder if there's even a general method (beyond the one you referred to). I can see very easily a general solution for when (i) the numerator is $1$ (ii) $alpha ne beta$ (iii) we only have a product of two factors in the denominator, but that's such a narrow set of circumstances that I wonder if it's worth it. Maybe someone has a more general form though.
    $endgroup$
    – Eevee Trainer
    4 hours ago








1




1




$begingroup$
Don't you mean find $A,B$? $alpha,beta$ are usually given.
$endgroup$
– Eevee Trainer
4 hours ago




$begingroup$
Don't you mean find $A,B$? $alpha,beta$ are usually given.
$endgroup$
– Eevee Trainer
4 hours ago












$begingroup$
Yes. Fixed. Thank you!
$endgroup$
– weno
4 hours ago




$begingroup$
Yes. Fixed. Thank you!
$endgroup$
– weno
4 hours ago












$begingroup$
Also when I think about it, I wonder if there's even a general method (beyond the one you referred to). I can see very easily a general solution for when (i) the numerator is $1$ (ii) $alpha ne beta$ (iii) we only have a product of two factors in the denominator, but that's such a narrow set of circumstances that I wonder if it's worth it. Maybe someone has a more general form though.
$endgroup$
– Eevee Trainer
4 hours ago




$begingroup$
Also when I think about it, I wonder if there's even a general method (beyond the one you referred to). I can see very easily a general solution for when (i) the numerator is $1$ (ii) $alpha ne beta$ (iii) we only have a product of two factors in the denominator, but that's such a narrow set of circumstances that I wonder if it's worth it. Maybe someone has a more general form though.
$endgroup$
– Eevee Trainer
4 hours ago










3 Answers
3






active

oldest

votes


















1












$begingroup$

Here's your answer
for general $n$.



$dfrac1{prod_{k=1}^n (x-a_k)}
=sum_{k=1}^n dfrac{b_k}{x-a_k}
$
.



Therefore
$1
=sum_{k=1}^n dfrac{b_kprod_{j=1}^n (x-a_j)}{x-a_k}
=sum_{k=1}^n b_kprod_{j=1, jne k}^n (x-a_j)
$
.



Setting
$x = a_i$
for each $i$,
all the terms
except the one with $k=i$
have the factor $a_i-a_i$,
so
$1 = b_iprod_{j=1, jne i}^n (a_i-a_j)
$

so that
$b_i
=dfrac1{prod_{j=1, jne i}^n (a_i-a_j)}
$
.



For $n=2$,
$b_1
=dfrac1{a_1-a_2}
$
,
$b_2
=dfrac1{a_2-a_1}
$
.



For $n=3$,
$b_1
=dfrac1{(a_1-a_2)(a_1-a_3)}
$
,
$b_2
=dfrac1{(a_2-a_1)(a_2-a_3)}
$
,
$b_3
=dfrac1{(a_3-a_1)(a_3-a_2)}
$
.






share|cite|improve this answer









$endgroup$





















    3












    $begingroup$

    Unless I am misunderstanding the question, by "root rotation" (when $beta neq alpha$):



    $$frac{1}{(t + alpha)(t + beta)} = frac{A}{t + alpha} + frac{B}{t + beta}$$



    $$1 = A(t + beta) + B(t + alpha)$$



    Evaluating $beta$ for $t$:



    $$1 = B(alpha - beta)$$



    $$B = frac{1}{alpha - beta}$$



    Similarly, for $A$, sub in $-alpha$:



    $$1 = A(beta - alpha)$$



    $$A = frac{1}{beta - alpha}$$






    share|cite|improve this answer









    $endgroup$













    • $begingroup$
      I'll be coming back to this post. This is what I was looking for.
      $endgroup$
      – weno
      3 hours ago










    • $begingroup$
      Unless that takes you too much time, would you be able to derive formulas for $A, B, C$, please? Function of form $frac{1}{(t+alpha)(t+beta)(t+gamma)}$ and $alpha neq beta neq gamma$
      $endgroup$
      – weno
      3 hours ago





















    2












    $begingroup$

    If your fraction is in form of $$ frac {1}{(t-alpha_1)(t-alpha_2)(t-alpha_3)...(t-alpha_k)}$$ where the $alpha s$ are different, there is an easy way to find the partial fraction decomposition.



    Let $t=alpha_i$ and cover $(t-alpha_i)$ while evaluating the above fraction to get your $A_i$



    For example $$ frac{1}{(t-1)(t-3)(t+4)} = frac {A_1}{(t-1)} + frac{ A_2}{(t-3)} +frac { A_3}{(t+4)}$$
    Where $$A_1 = frac {1}{(1-3)(1+4)}=frac{-1}{10}$$
    $$A_2 = frac {1}{(3-1)(3+4)} = frac{1}{14}$$



    $$A_3=frac {1}{(-4-1)(-4-3)}=frac{1}{35}$$






    share|cite|improve this answer









    $endgroup$














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      3 Answers
      3






      active

      oldest

      votes








      3 Answers
      3






      active

      oldest

      votes









      active

      oldest

      votes






      active

      oldest

      votes









      1












      $begingroup$

      Here's your answer
      for general $n$.



      $dfrac1{prod_{k=1}^n (x-a_k)}
      =sum_{k=1}^n dfrac{b_k}{x-a_k}
      $
      .



      Therefore
      $1
      =sum_{k=1}^n dfrac{b_kprod_{j=1}^n (x-a_j)}{x-a_k}
      =sum_{k=1}^n b_kprod_{j=1, jne k}^n (x-a_j)
      $
      .



      Setting
      $x = a_i$
      for each $i$,
      all the terms
      except the one with $k=i$
      have the factor $a_i-a_i$,
      so
      $1 = b_iprod_{j=1, jne i}^n (a_i-a_j)
      $

      so that
      $b_i
      =dfrac1{prod_{j=1, jne i}^n (a_i-a_j)}
      $
      .



      For $n=2$,
      $b_1
      =dfrac1{a_1-a_2}
      $
      ,
      $b_2
      =dfrac1{a_2-a_1}
      $
      .



      For $n=3$,
      $b_1
      =dfrac1{(a_1-a_2)(a_1-a_3)}
      $
      ,
      $b_2
      =dfrac1{(a_2-a_1)(a_2-a_3)}
      $
      ,
      $b_3
      =dfrac1{(a_3-a_1)(a_3-a_2)}
      $
      .






      share|cite|improve this answer









      $endgroup$


















        1












        $begingroup$

        Here's your answer
        for general $n$.



        $dfrac1{prod_{k=1}^n (x-a_k)}
        =sum_{k=1}^n dfrac{b_k}{x-a_k}
        $
        .



        Therefore
        $1
        =sum_{k=1}^n dfrac{b_kprod_{j=1}^n (x-a_j)}{x-a_k}
        =sum_{k=1}^n b_kprod_{j=1, jne k}^n (x-a_j)
        $
        .



        Setting
        $x = a_i$
        for each $i$,
        all the terms
        except the one with $k=i$
        have the factor $a_i-a_i$,
        so
        $1 = b_iprod_{j=1, jne i}^n (a_i-a_j)
        $

        so that
        $b_i
        =dfrac1{prod_{j=1, jne i}^n (a_i-a_j)}
        $
        .



        For $n=2$,
        $b_1
        =dfrac1{a_1-a_2}
        $
        ,
        $b_2
        =dfrac1{a_2-a_1}
        $
        .



        For $n=3$,
        $b_1
        =dfrac1{(a_1-a_2)(a_1-a_3)}
        $
        ,
        $b_2
        =dfrac1{(a_2-a_1)(a_2-a_3)}
        $
        ,
        $b_3
        =dfrac1{(a_3-a_1)(a_3-a_2)}
        $
        .






        share|cite|improve this answer









        $endgroup$
















          1












          1








          1





          $begingroup$

          Here's your answer
          for general $n$.



          $dfrac1{prod_{k=1}^n (x-a_k)}
          =sum_{k=1}^n dfrac{b_k}{x-a_k}
          $
          .



          Therefore
          $1
          =sum_{k=1}^n dfrac{b_kprod_{j=1}^n (x-a_j)}{x-a_k}
          =sum_{k=1}^n b_kprod_{j=1, jne k}^n (x-a_j)
          $
          .



          Setting
          $x = a_i$
          for each $i$,
          all the terms
          except the one with $k=i$
          have the factor $a_i-a_i$,
          so
          $1 = b_iprod_{j=1, jne i}^n (a_i-a_j)
          $

          so that
          $b_i
          =dfrac1{prod_{j=1, jne i}^n (a_i-a_j)}
          $
          .



          For $n=2$,
          $b_1
          =dfrac1{a_1-a_2}
          $
          ,
          $b_2
          =dfrac1{a_2-a_1}
          $
          .



          For $n=3$,
          $b_1
          =dfrac1{(a_1-a_2)(a_1-a_3)}
          $
          ,
          $b_2
          =dfrac1{(a_2-a_1)(a_2-a_3)}
          $
          ,
          $b_3
          =dfrac1{(a_3-a_1)(a_3-a_2)}
          $
          .






          share|cite|improve this answer









          $endgroup$



          Here's your answer
          for general $n$.



          $dfrac1{prod_{k=1}^n (x-a_k)}
          =sum_{k=1}^n dfrac{b_k}{x-a_k}
          $
          .



          Therefore
          $1
          =sum_{k=1}^n dfrac{b_kprod_{j=1}^n (x-a_j)}{x-a_k}
          =sum_{k=1}^n b_kprod_{j=1, jne k}^n (x-a_j)
          $
          .



          Setting
          $x = a_i$
          for each $i$,
          all the terms
          except the one with $k=i$
          have the factor $a_i-a_i$,
          so
          $1 = b_iprod_{j=1, jne i}^n (a_i-a_j)
          $

          so that
          $b_i
          =dfrac1{prod_{j=1, jne i}^n (a_i-a_j)}
          $
          .



          For $n=2$,
          $b_1
          =dfrac1{a_1-a_2}
          $
          ,
          $b_2
          =dfrac1{a_2-a_1}
          $
          .



          For $n=3$,
          $b_1
          =dfrac1{(a_1-a_2)(a_1-a_3)}
          $
          ,
          $b_2
          =dfrac1{(a_2-a_1)(a_2-a_3)}
          $
          ,
          $b_3
          =dfrac1{(a_3-a_1)(a_3-a_2)}
          $
          .







          share|cite|improve this answer












          share|cite|improve this answer



          share|cite|improve this answer










          answered 51 mins ago









          marty cohenmarty cohen

          75.3k549130




          75.3k549130























              3












              $begingroup$

              Unless I am misunderstanding the question, by "root rotation" (when $beta neq alpha$):



              $$frac{1}{(t + alpha)(t + beta)} = frac{A}{t + alpha} + frac{B}{t + beta}$$



              $$1 = A(t + beta) + B(t + alpha)$$



              Evaluating $beta$ for $t$:



              $$1 = B(alpha - beta)$$



              $$B = frac{1}{alpha - beta}$$



              Similarly, for $A$, sub in $-alpha$:



              $$1 = A(beta - alpha)$$



              $$A = frac{1}{beta - alpha}$$






              share|cite|improve this answer









              $endgroup$













              • $begingroup$
                I'll be coming back to this post. This is what I was looking for.
                $endgroup$
                – weno
                3 hours ago










              • $begingroup$
                Unless that takes you too much time, would you be able to derive formulas for $A, B, C$, please? Function of form $frac{1}{(t+alpha)(t+beta)(t+gamma)}$ and $alpha neq beta neq gamma$
                $endgroup$
                – weno
                3 hours ago


















              3












              $begingroup$

              Unless I am misunderstanding the question, by "root rotation" (when $beta neq alpha$):



              $$frac{1}{(t + alpha)(t + beta)} = frac{A}{t + alpha} + frac{B}{t + beta}$$



              $$1 = A(t + beta) + B(t + alpha)$$



              Evaluating $beta$ for $t$:



              $$1 = B(alpha - beta)$$



              $$B = frac{1}{alpha - beta}$$



              Similarly, for $A$, sub in $-alpha$:



              $$1 = A(beta - alpha)$$



              $$A = frac{1}{beta - alpha}$$






              share|cite|improve this answer









              $endgroup$













              • $begingroup$
                I'll be coming back to this post. This is what I was looking for.
                $endgroup$
                – weno
                3 hours ago










              • $begingroup$
                Unless that takes you too much time, would you be able to derive formulas for $A, B, C$, please? Function of form $frac{1}{(t+alpha)(t+beta)(t+gamma)}$ and $alpha neq beta neq gamma$
                $endgroup$
                – weno
                3 hours ago
















              3












              3








              3





              $begingroup$

              Unless I am misunderstanding the question, by "root rotation" (when $beta neq alpha$):



              $$frac{1}{(t + alpha)(t + beta)} = frac{A}{t + alpha} + frac{B}{t + beta}$$



              $$1 = A(t + beta) + B(t + alpha)$$



              Evaluating $beta$ for $t$:



              $$1 = B(alpha - beta)$$



              $$B = frac{1}{alpha - beta}$$



              Similarly, for $A$, sub in $-alpha$:



              $$1 = A(beta - alpha)$$



              $$A = frac{1}{beta - alpha}$$






              share|cite|improve this answer









              $endgroup$



              Unless I am misunderstanding the question, by "root rotation" (when $beta neq alpha$):



              $$frac{1}{(t + alpha)(t + beta)} = frac{A}{t + alpha} + frac{B}{t + beta}$$



              $$1 = A(t + beta) + B(t + alpha)$$



              Evaluating $beta$ for $t$:



              $$1 = B(alpha - beta)$$



              $$B = frac{1}{alpha - beta}$$



              Similarly, for $A$, sub in $-alpha$:



              $$1 = A(beta - alpha)$$



              $$A = frac{1}{beta - alpha}$$







              share|cite|improve this answer












              share|cite|improve this answer



              share|cite|improve this answer










              answered 3 hours ago









              DairDair

              1,95211124




              1,95211124












              • $begingroup$
                I'll be coming back to this post. This is what I was looking for.
                $endgroup$
                – weno
                3 hours ago










              • $begingroup$
                Unless that takes you too much time, would you be able to derive formulas for $A, B, C$, please? Function of form $frac{1}{(t+alpha)(t+beta)(t+gamma)}$ and $alpha neq beta neq gamma$
                $endgroup$
                – weno
                3 hours ago




















              • $begingroup$
                I'll be coming back to this post. This is what I was looking for.
                $endgroup$
                – weno
                3 hours ago










              • $begingroup$
                Unless that takes you too much time, would you be able to derive formulas for $A, B, C$, please? Function of form $frac{1}{(t+alpha)(t+beta)(t+gamma)}$ and $alpha neq beta neq gamma$
                $endgroup$
                – weno
                3 hours ago


















              $begingroup$
              I'll be coming back to this post. This is what I was looking for.
              $endgroup$
              – weno
              3 hours ago




              $begingroup$
              I'll be coming back to this post. This is what I was looking for.
              $endgroup$
              – weno
              3 hours ago












              $begingroup$
              Unless that takes you too much time, would you be able to derive formulas for $A, B, C$, please? Function of form $frac{1}{(t+alpha)(t+beta)(t+gamma)}$ and $alpha neq beta neq gamma$
              $endgroup$
              – weno
              3 hours ago






              $begingroup$
              Unless that takes you too much time, would you be able to derive formulas for $A, B, C$, please? Function of form $frac{1}{(t+alpha)(t+beta)(t+gamma)}$ and $alpha neq beta neq gamma$
              $endgroup$
              – weno
              3 hours ago













              2












              $begingroup$

              If your fraction is in form of $$ frac {1}{(t-alpha_1)(t-alpha_2)(t-alpha_3)...(t-alpha_k)}$$ where the $alpha s$ are different, there is an easy way to find the partial fraction decomposition.



              Let $t=alpha_i$ and cover $(t-alpha_i)$ while evaluating the above fraction to get your $A_i$



              For example $$ frac{1}{(t-1)(t-3)(t+4)} = frac {A_1}{(t-1)} + frac{ A_2}{(t-3)} +frac { A_3}{(t+4)}$$
              Where $$A_1 = frac {1}{(1-3)(1+4)}=frac{-1}{10}$$
              $$A_2 = frac {1}{(3-1)(3+4)} = frac{1}{14}$$



              $$A_3=frac {1}{(-4-1)(-4-3)}=frac{1}{35}$$






              share|cite|improve this answer









              $endgroup$


















                2












                $begingroup$

                If your fraction is in form of $$ frac {1}{(t-alpha_1)(t-alpha_2)(t-alpha_3)...(t-alpha_k)}$$ where the $alpha s$ are different, there is an easy way to find the partial fraction decomposition.



                Let $t=alpha_i$ and cover $(t-alpha_i)$ while evaluating the above fraction to get your $A_i$



                For example $$ frac{1}{(t-1)(t-3)(t+4)} = frac {A_1}{(t-1)} + frac{ A_2}{(t-3)} +frac { A_3}{(t+4)}$$
                Where $$A_1 = frac {1}{(1-3)(1+4)}=frac{-1}{10}$$
                $$A_2 = frac {1}{(3-1)(3+4)} = frac{1}{14}$$



                $$A_3=frac {1}{(-4-1)(-4-3)}=frac{1}{35}$$






                share|cite|improve this answer









                $endgroup$
















                  2












                  2








                  2





                  $begingroup$

                  If your fraction is in form of $$ frac {1}{(t-alpha_1)(t-alpha_2)(t-alpha_3)...(t-alpha_k)}$$ where the $alpha s$ are different, there is an easy way to find the partial fraction decomposition.



                  Let $t=alpha_i$ and cover $(t-alpha_i)$ while evaluating the above fraction to get your $A_i$



                  For example $$ frac{1}{(t-1)(t-3)(t+4)} = frac {A_1}{(t-1)} + frac{ A_2}{(t-3)} +frac { A_3}{(t+4)}$$
                  Where $$A_1 = frac {1}{(1-3)(1+4)}=frac{-1}{10}$$
                  $$A_2 = frac {1}{(3-1)(3+4)} = frac{1}{14}$$



                  $$A_3=frac {1}{(-4-1)(-4-3)}=frac{1}{35}$$






                  share|cite|improve this answer









                  $endgroup$



                  If your fraction is in form of $$ frac {1}{(t-alpha_1)(t-alpha_2)(t-alpha_3)...(t-alpha_k)}$$ where the $alpha s$ are different, there is an easy way to find the partial fraction decomposition.



                  Let $t=alpha_i$ and cover $(t-alpha_i)$ while evaluating the above fraction to get your $A_i$



                  For example $$ frac{1}{(t-1)(t-3)(t+4)} = frac {A_1}{(t-1)} + frac{ A_2}{(t-3)} +frac { A_3}{(t+4)}$$
                  Where $$A_1 = frac {1}{(1-3)(1+4)}=frac{-1}{10}$$
                  $$A_2 = frac {1}{(3-1)(3+4)} = frac{1}{14}$$



                  $$A_3=frac {1}{(-4-1)(-4-3)}=frac{1}{35}$$







                  share|cite|improve this answer












                  share|cite|improve this answer



                  share|cite|improve this answer










                  answered 3 hours ago









                  Mohammad Riazi-KermaniMohammad Riazi-Kermani

                  41.6k42061




                  41.6k42061






























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