Ordinary Differential Equations/Frobenius Solution to the Hypergeometric Equation

In the following we solve the second-order differential equation called the hypergeometric differential equation using Frobenius method, named after Ferdinand Georg Frobenius. This is a method that uses the series solution for a differential equation, where we assume the solution takes the form of a series. This is usually the method we use for complicated ordinary differential equations.

The solution of the hypergeometric differential equation is very important. For instance, Legendre's differential equation can be shown to be a special case of the hypergeometric differential equation. Hence, by solving the hypergeometric differential equation, one may directly compare its solutions to get the solutions of Legendre's differential equation, after making the necessary substitutions. For more details, please check the hypergeometric differential equation

We shall prove that this equation has three singularities, namely at x = 0, x = 1 and around infinity. However, as these will turn out to be regular singular points, we will be able to assume a solution on the form of a series. Since this is a second-order differential equation, we must have two linearly independent solutions.

The problem however will be that our assumed solutions may or not be independent, or worse, may not even be defined (depending on the value of the parameters of the equation). This is why we shall study the different cases for the parameters and modify our assumed solution accordingly.

Solve the hypergeometric equation around all singularities:

${\displaystyle x(1-x)y^{″}+\{\gamma -(1+\alpha +\beta )x\}{y}^{\prime }-\alpha \beta y=0}$

Let

${\displaystyle \begin{array}{ccccc}{P}_0(x)=-\alpha \beta ,& & P_1(x)=\gamma -(1+\alpha +\beta )x,& & P_2(x)=x(1-x)\end{array}}$

Then

${\displaystyle P_2(0)=0,P_2(1)=0.}$

Hence, x = 0 and x = 1 are singular points. Let's start with x = 0. To see if it is regular, we study the following limits:

${\displaystyle \begin{array}{cc}\underset{x\to a}{\lim }\frac{(x-a)P_1(x)}{P_2(x)}& =\underset{x\to 0}{\lim }\frac{(x-0)(\gamma -(1+\alpha +\beta )x)}{x(1-x)}=\underset{x\to 0}{\lim }\frac{x(\gamma -(1+\alpha +\beta )x)}{x(1-x)}=\gamma \\ \underset{x\to a}{\lim }\frac{(x-a{)}^2{P}_0(x)}{P_2(x)}& =\underset{x\to 0}{\lim }\frac{(x-0{)}^2(-\alpha \beta )}{x(1-x)}=\underset{x\to 0}{\lim }\frac{x^2(-\alpha \beta )}{x(1-x)}=0\end{array}}$

Hence, both limits exist and x = 0 is a regular singular point. Therefore, we assume the solution takes the form

${\displaystyle y={\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r{x}^{r+c}}$

with a₀ ≠ 0. Hence,

${\displaystyle \begin{array}{ccc}{y}^{\prime }={\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(r+c)x^{r+c-1}& & y^{″}={\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(r+c)(r+c-1)x^{r+c-2}.\end{array}}$

Substituting these into the hypergeometric equation, we get

${\displaystyle \begin{array}{cc}& x{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(r+c)(r+c-1)x^{r+c-2}-x^2{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(r+c)(r+c-1)x^{r+c-2}+\gamma {\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(r+c)x^{r+c-1}\\ & -(1+\alpha +\beta )x{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(r+c)x^{r+c-1}-\alpha \beta {\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r{x}^{r+c}=0\end{array}}$

That is,

${\displaystyle \begin{array}{cc}& {\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(r+c)(r+c-1)x^{r+c-1}-{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(r+c)(r+c-1)x^{r+c}+\gamma {\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(r+c)x^{r+c-1}\\ & -(1+\alpha +\beta ){\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(r+c)x^{r+c}-\alpha \beta {\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r{x}^{r+c}=0\end{array}}$

In order to simplify this equation, we need all powers to be the same, equal to r + c - 1, the smallest power. Hence, we switch the indices as follows:

${\displaystyle \begin{array}{cc}& {\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(r+c)(r+c-1)x^{r+c-1}-{\displaystyle \sum _{r=1}^{\mathrm{\infty }}}{a}_{r-1}(r+c-1)(r+c-2)x^{r+c-1}+\gamma {\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(r+c)x^{r+c-1}\\ & -(1+\alpha +\beta ){\displaystyle \sum _{r=1}^{\mathrm{\infty }}}{a}_{r-1}(r+c-1)x^{r+c-1}-\alpha \beta {\displaystyle \sum _{r=1}^{\mathrm{\infty }}}{a}_{r-1}{x}^{r+c-1}=0\end{array}}$

Thus, isolating the first term of the sums starting from 0 we get

${\displaystyle \begin{array}{cc}& a_0(c(c-1)+\gamma c)x^{c-1}+{\displaystyle \sum _{r=1}^{\mathrm{\infty }}}{a}_r(r+c)(r+c-1)x^{r+c-1}-{\displaystyle \sum _{r=1}^{\mathrm{\infty }}}{a}_{r-1}(r+c-1)(r+c-2)x^{r+c-1}\\ & +\gamma {\displaystyle \sum _{r=1}^{\mathrm{\infty }}}{a}_r(r+c)x^{r+c-1}-(1+\alpha +\beta ){\displaystyle \sum _{r=1}^{\mathrm{\infty }}}{a}_{r-1}(r+c-1)x^{r+c-1}-\alpha \beta {\displaystyle \sum _{r=1}^{\mathrm{\infty }}}{a}_{r-1}{x}^{r+c-1}=0\end{array}}$

Now, from the linear independence of all powers of x, that is, of the functions 1, x, x², etc., the coefficients of x^k vanish for all k. Hence, from the first term, we have

${\displaystyle a_0(c(c-1)+\gamma c)=0}$

which is the indicial equation. Since a₀ ≠ 0, we have

${\displaystyle c(c-1+\gamma )=0.}$

Hence,

${\displaystyle \begin{array}{ccc}{c}_1=0& & c_2=1-\gamma \end{array}}$

Also, from the rest of the terms, we have

${\displaystyle \begin{array}{cc}& ((r+c)(r+c-1)+\gamma (r+c))a_r\\ & +(-(r+c-1)(r+c-2)-(1+\alpha +\beta )(r+c-1)-\alpha \beta )a_{r-1}=0\end{array}}$

Hence,

${\displaystyle \begin{array}{cc}{a}_r& =\frac{(r+c-1)(r+c-2)+(1+\alpha +\beta )(r+c-1)+\alpha \beta }{(r+c)(r+c-1)+\gamma (r+c)}{a}_{r-1}\\ & =\frac{(r+c-1)(r+c+\alpha +\beta -1)+\alpha \beta }{(r+c)(r+c+\gamma -1)}{a}_{r-1}\end{array}}$

But

${\displaystyle \begin{array}{cc}& (r+c-1)(r+c+\alpha +\beta -1)+\alpha \beta \\ & =(r+c-1)(r+c+\alpha -1)+(r+c-1)\beta +\alpha \beta \\ & =(r+c-1)(r+c+\alpha -1)+\beta (r+c+\alpha -1)\end{array}}$

Hence, we get the recurrence relation

${\displaystyle a_r=\frac{(r+c+\alpha -1)(r+c+\beta -1)}{(r+c)(r+c+\gamma -1)}{a}_{r-1},\text{ for }r\ge 1.}$

Let's now simplify this relation by giving a_r in terms of a₀ instead of a_r − 1. From the recurrence relation (note: below, expressions of the form (u)_r refer to the Pochhammer symbol).

${\displaystyle \begin{array}{cc}{a}_1& =\frac{(c+\alpha )(c+\beta )}{(c+1)(c+\gamma )}{a}_0\\ a_2& =\frac{(c+\alpha +1)(c+\beta +1)}{(c+2)(c+\gamma +1)}{a}_1=\frac{(c+\alpha +1)(c+\alpha )(c+\beta +1)}{(c+2)(c+1)(c+\gamma )(c+\gamma +1)}{a}_0=\frac{(c+\alpha {)}_2(c+\beta {)}_2}{(c+1{)}_2(c+\gamma {)}_2}{a}_0\\ a_3& =\frac{(c+\alpha +2)(c+\beta +2)}{(c+3)(c+\gamma +2)}{a}_2=\frac{(c+\alpha {)}_2(c+\alpha +2)(c+\beta {)}_2(c+\beta +2}{(c+1{)}_2(c+3)(c+\gamma {)}_2(c+\gamma +2)}{a}_0\\ & =\frac{(c+\alpha {)}_3(c+\beta {)}_3}{(c+1{)}_3(c+\gamma {)}_3}{a}_0\end{array}}$

As we can see,

${\displaystyle a_r=\frac{(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}{a}_0,\text{ for }r\ge 0}$

Hence, our assumed solution takes the form

${\displaystyle y=a_0{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}{x}^{r+c}.}$

We are now ready to study the solutions corresponding to the different cases for c₁ − c₂ = γ − 1 (it should be noted that this reduces to study the nature of the parameter γ: whether it is an an integer or not).

Then y₁ = y|_{c = 0} and y₂ = y|_{c = 1 − γ}. Since

${\displaystyle y=a_0{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}{x}^{r+c},}$

we have

${\displaystyle \begin{array}{cc}{y}_1& =a_0{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(\alpha {)}_r(\beta {)}_r}{(1{)}_r(\gamma {)}_r}{x}^r\\ & =a_0\cdot {}_2{F}_1(\alpha ,\beta ;\gamma ;x)\\ y_2& =a_0{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(\alpha +1-\gamma {)}_r(\beta +1-\gamma {)}_r}{(1-\gamma +1{)}_r(1-\gamma +\gamma {)}_r}{x}^{r+1-\gamma }=a_0{x}^{1-\gamma }{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(\alpha +1-\gamma {)}_r(\beta +1-\gamma {)}_r}{(1{)}_r(2-\gamma {)}_r}{x}^r\\ & =a_0{x}^{1-\gamma }{}_2{F}_1(\alpha -\gamma +1,\beta -\gamma +1;2-\gamma ;x)\end{array}}$

Hence, ${\displaystyle y=A^{\prime }{y}_1+B^{\prime }{y}_2.}$ Let A′ a₀ = a and B′ a₀ = B. Then

${\displaystyle y=A{}_2{F}_1(\alpha ,\beta ;\gamma ;x)+B{x}^{1-\gamma }{}_2{F}_1(\alpha -\gamma +1,\beta -\gamma +1;2-\gamma ;x)}$

Then y₁ = y|_{c = 0}. Since γ = 1, we have

${\displaystyle y=a_0{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r^2}{x}^{r+c}.}$

Hence,

${\displaystyle \begin{array}{cc}{y}_1& =a_0{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(\alpha {)}_r(\beta {)}_r}{(1{)}_r(1{)}_r}{x}^r=a_0{}_2{F}_1(\alpha ,\beta ;1;x)\\ y_2& ={\frac{\partial y}{\partial c}|}_{c=0}.\end{array}}$

To calculate this derivative, let

${\displaystyle M_r=\frac{(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r^2}.}$

Then

${\displaystyle \ln (M_r)=\ln \left(\frac{(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r^2}\right)=\ln (c+\alpha {)}_r+\ln (c+\beta {)}_r-2\ln (c+1{)}_r}$

But

${\displaystyle \ln (c+\alpha {)}_r=\ln ((c+\alpha )(c+\alpha +1)\cdots (c+\alpha +r-1))={\displaystyle \sum _{k=0}^{r-1}}\ln (c+\alpha +k).}$

Hence,

${\displaystyle \begin{array}{cc}\ln (M_r)& ={\displaystyle \sum _{k=0}^{r-1}}\ln (c+\alpha +k)+{\displaystyle \sum _{k=0}^{r-1}}\ln (c+\beta +k)-2{\displaystyle \sum _{k=0}^{r-1}}\ln (c+1+k)\\ & ={\displaystyle \sum _{k=0}^{r-1}}(\ln (c+\alpha +k)+\ln (c+\beta +k)-2\ln (c+1+k))\end{array}}$

Differentiating both sides of the equation with respect to c, we get:

${\displaystyle \frac{1}{M_r}\frac{\partial M_r}{\partial c}={\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+\alpha +k}+\frac{1}{c+\beta +k}-\frac{2}{c+1+k}).}$

Hence,

${\displaystyle \frac{\partial M_r}{\partial c}=\frac{(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r^2}{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+\alpha +k}+\frac{1}{c+\beta +k}-\frac{2}{c+1+k}).}$

Now,

${\displaystyle y=a_0{x}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r^2}{x}^r=a_0{x}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{M}_r{x}^r.}$

Hence,

${\displaystyle \begin{array}{cc}\frac{\partial y}{\partial c}& =a_0{x}^c\ln (x){\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r^2}{x}^r\\ & +a_0{x}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\left(\frac{(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r^2}\left\{{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+\alpha +k}+\frac{1}{c+\beta +k}-\frac{2}{c+1+k})\right\}\right)x^r\\ & =a_0{x}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r{)}^2}(\ln x+{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+\alpha +k}+\frac{1}{c+\beta +k}-\frac{2}{c+1+k}))x^r.\end{array}}$

For c = 0, we get

${\displaystyle y_2=a_0{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(\alpha {)}_r(\beta {)}_r}{(1{)}_r^2}(\ln x+{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{\alpha +k}+\frac{1}{\beta +k}-\frac{2}{1+k}))x^r.}$

Hence, y = C′ y₁ + D′ y₂. Let C′ a₀ = C and D′ a₀ = D. Then

${\displaystyle y=C{}_2{F}_1(\alpha ,\beta ;1;x)+D{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(\alpha {)}_r(\beta {)}_r}{(1{)}_r^2}(\ln x+{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{\alpha +k}+\frac{1}{\beta +k}-\frac{2}{1+k}))x^r}$

From the recurrence relation

${\displaystyle a_r=\frac{(r+c+\alpha -1)(r+c+\beta -1)}{(r+c)(r+c+\gamma -1)}{a}_{r-1},}$

we see that when c = 0 (the smaller root), a_{1 − γ} → ∞. Hence, we must make the substitution a₀ = b₀ (c - c_i), where c_i is the root for which our solution is infinite. Hence, we take a₀ = b₀ c and our assumed solution takes the new form

${\displaystyle y_b=b_0{x}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{c(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}{x}^r}$

Then y₁ = y_b|_{c = 0}. As we can see, all terms before

${\displaystyle \frac{c(c+\alpha {)}_{1-\gamma }(c+\beta {)}_{1-\gamma }}{(c+1{)}_{1-\gamma }(c+\gamma {)}_{1-\gamma }}{x}^{1-\gamma }}$

vanish because of the c in the numerator. Starting from this term however, the c in the numerator vanishes. To see this, note that

${\displaystyle (c+\gamma {)}_{1-\gamma }=(c+\gamma )(c+\gamma +1)\cdots c.}$

Hence, our solution takes the form

${\displaystyle \begin{array}{cc}{y}_1& =b_0(\frac{(\alpha {)}_{1-\gamma }(\beta {)}_{1-\gamma }}{(1{)}_{1-\gamma }(\gamma {)}_{-\gamma }}{x}^{1-\gamma }+\frac{(\alpha {)}_{2-\gamma }(\beta {)}_{2-\gamma }}{(1{)}_{2-\gamma }(\gamma {)}_{-\gamma }(1)}{x}^{2-\gamma }+\frac{(\alpha {)}_{3-\gamma }(\beta {)}_{3-\gamma }}{(1{)}_{3-\gamma }(\gamma {)}_{-\gamma }(1)(2)}{x}^{3-\gamma }+\cdots )\\ & =\frac{b_0}{(\gamma {)}_{-\gamma }}{\displaystyle \sum _{r=1-\gamma }^{\mathrm{\infty }}}\frac{(\alpha {)}_r(\beta {)}_r}{(1{)}_r(1{)}_{r+\gamma -1}}{x}^r.\end{array}}$

Now,

${\displaystyle y_2={\frac{\partial y_b}{\partial c}|}_{c=1-\gamma }.}$

To calculate this derivative, let

${\displaystyle M_r=\frac{c(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}.}$

Then following the method in the previous case, we get

${\displaystyle \frac{\partial M_r}{\partial c}=\frac{c(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}\{\frac{1}{c}+{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+\alpha +k}+\frac{1}{c+\beta +k}-\frac{1}{c+1+k}-\frac{1}{c+\gamma +k})\}.}$

Now,

${\displaystyle y_b=b_0\sum {r=0}^{\mathrm{\infty }}\frac{c(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}{x}^{r+c}=b_0{x}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{M}_r{x}^r.}$

Hence,

${\displaystyle \begin{array}{cc}\frac{\partial y}{\partial c}& =b_0{x}^c\ln (x){\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{c(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}{x}^r\\ & +b_0{x}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{c(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}\{\frac{1}{c}+{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+\alpha +k}+\frac{1}{c+\beta +k}-\frac{1}{c+1+k}-\frac{1}{c+\gamma +k})\}{x}^r\end{array}}$

Hence,

${\displaystyle \begin{array}{cc}\frac{\partial y}{\partial c}=b_0{x}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}& \frac{c(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}(\ln x+\frac{1}{c}+\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+\alpha +k}+\frac{1}{c+\beta +k}-\frac{1}{c+1+k}-\frac{1}{c+\gamma +k}))x^r.\end{array}}$

At c = 1- γ, we get y₂. Hence, y = E′ y₁ + F′ y₂. Let E′ b₀ = E and F′ b₀ = F. Then

${\displaystyle \begin{array}{cc}y& =\frac{E}{(\gamma {)}_{-\gamma }}{\displaystyle \sum _{r=1-\gamma }^{\mathrm{\infty }}}\frac{(\alpha {)}_r(\beta {)}_r}{(1{)}_r(1{)}_{r+\gamma -1}}{x}^r\\ & \begin{array}{cc}+F{x}^{1-\gamma }{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}& \frac{(1-\gamma )(\alpha +1-\gamma {)}_r(\beta +1-\gamma {)}_r}{(2-\gamma {)}_r(1{)}_r}(\ln x+\frac{1}{1-\gamma }+\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{\alpha +k+1-\gamma }+\frac{1}{\beta +k+1-\gamma }-\frac{1}{2+k-\gamma }-\frac{1}{1+k}))x^r.\end{array}\end{array}}$

From the recurrence relation

${\displaystyle a_r=\frac{(r+c+\alpha -1)(r+c+\beta -1)}{(r+c)(r+c+\gamma -1)}{a}_{r-1},}$

we see that when c = 1 - γ (the smaller root), a_{γ − 1} → ∞. Hence, we must make the substitution a₀ = b₀(c − c_i), where c_i is the root for which our solution is infinite. Hence, we take a₀ = b₀(c + γ - 1) and our assumed solution takes the new form:

${\displaystyle y_b=b_0{x}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(c+\gamma -1)(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}{x}^r.}$

Then y₁ = y_b|_{c = 1 - γ}. All terms before

${\displaystyle \frac{(c+\gamma -1)(c+\alpha {)}_{\gamma -1}(c+\beta {)}_{\gamma -1}}{(c+1{)}_{\gamma -1}(c+\gamma {)}_{\gamma -1}}{x}^{\gamma -1}}$

vanish because of the c + γ - 1 in the numerator. Starting from this term, however, the c + γ - 1 in the numerator vanishes. To see this, note that

${\displaystyle (c+1{)}_{\gamma -1}=(c+1)(c+2)\cdots (c+\gamma -1).}$

Hence, our solution takes the form

${\displaystyle \begin{array}{cc}{y}_1& =b_0{x}^{1-\gamma }(\frac{(\alpha +1-\gamma {)}_{\gamma -1}(\beta +1-\gamma {)}_{\gamma -1}}{(2-\gamma {)}_{\gamma -2}(1{)}_{\gamma -1}}{x}^{\gamma -1}+\frac{(\alpha +1-\gamma {)}_{\gamma }(\beta +1-\gamma {)}_{\gamma }}{(2-\gamma {)}_{\gamma -2}(1)(1{)}_{\gamma }}{x}^{\gamma }+\cdots )\\ & =\frac{b_0}{(2-\gamma {)}_{\gamma -2}}{x}^{1-\gamma }{\displaystyle \sum _{r=\gamma -1}^{\mathrm{\infty }}}\frac{(\alpha +1-\gamma {)}_r(\beta +1-\gamma {)}_r}{(1{)}_r(1{)}_{r+1-\gamma }}{x}^r.\end{array}}$

Now,

${\displaystyle y_2={\frac{\partial y_b}{\partial c}|}_{c=0}.}$

To calculate this derivative, let

${\displaystyle M_r=\frac{(c+\gamma -1)(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}.}$

Then following the method in the second case above,

${\displaystyle \begin{array}{cc}\frac{\partial M_r}{\partial c}& =\frac{(c+\gamma -1)(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}(\frac{1}{c+\gamma -1}+\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+\alpha +k}+\frac{1}{c+\beta +k}-\frac{1}{c+1+k}-\frac{1}{c+\gamma +k}))\end{array}}$

Now,

${\displaystyle y_b=b_0{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(c+\gamma -1)(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}{x}^{r+c}=b_0{x}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{M}_r{x}^r.}$

Hence,

${\displaystyle \begin{array}{cc}\frac{\partial y}{\partial c}& =b_0{x}^c\ln (x){\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(c+\gamma -1)(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}{x}^r+\\ & \begin{array}{cc}+b_0{x}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}& \frac{(c+\gamma -1)(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}(\frac{1}{c+\gamma -1}+\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+\alpha +k}+\frac{1}{c+\beta +k}-\frac{1}{c+1+k}-\frac{1}{c+\gamma +k}))x^r\end{array}\\ & \begin{array}{cc}=b_0{x}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}& \frac{(c+\gamma -1)(c+\alpha {)}_r(c+\beta {)}_r}{(c+1{)}_r(c+\gamma {)}_r}(\ln x+\frac{1}{c+\gamma -1}+\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+\alpha +k}+\frac{1}{c+\beta +k}-\frac{1}{c+1+k}-\frac{1}{c+\gamma +k}))x^r.\end{array}\end{array}}$

At c = 0 we get y₂. Hence, y = G′y₁ + H′y₂. Let G′b₀ = E and H′b₀ = F. Then

${\displaystyle \begin{array}{cc}y=\frac{G}{(2-\gamma {)}_{\gamma -2}}& x^{1-\gamma }{\displaystyle \sum _{r=\gamma -1}^{\mathrm{\infty }}}\frac{(\alpha +1-\gamma {)}_r(\beta +1-\gamma {)}_r}{(1{)}_r(1{)}_{r+1-\gamma }}{x}^r\\ & \begin{array}{cc}+H{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}& \frac{(1-\gamma )(\alpha +1-\gamma {)}_r(\beta +1-\gamma {)}_r}{(2-\gamma {)}_r(1{)}_r}(\ln x+\frac{1}{\gamma -1}+\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{\alpha +k}+\frac{1}{\beta +k}-\frac{1}{1+k}-\frac{1}{\gamma +k}))x^r.\end{array}\end{array}}$

Let us now study the singular point x = 1. To see if it is regular,

${\displaystyle \begin{array}{cc}& \underset{x\to a}{\lim }\frac{(x-a)P_1(x)}{P_2(x)}=\underset{x\to 1}{\lim }\frac{(x-1)(\gamma -(1+\alpha +\beta )x)}{x(1-x)}\\ & =\underset{x\to 1}{\lim }\frac{-(\gamma -(1+\alpha +\beta )x)}{x}=1+\alpha +\beta -\gamma \\ & \underset{x\to a}{\lim }\frac{(x-a{)}^2{P}_0(x)}{P_2(x)}=\underset{x\to 1}{\lim }\frac{(x-1{)}^2(-\alpha \beta )}{x(1-x)}=\underset{x\to 1}{\lim }\frac{(x-1)\alpha \beta }{x}=0\end{array}}$

Hence, both limits exist and x = 1 is a regular singular point. Now, instead of assuming a solution on the form

${\displaystyle y={\displaystyle \sum _{r=0}^{\mathrm{\infty }}}{a}_r(x-1{)}^{r+c},}$

we will try to express the solutions of this case in terms of the solutions for the point x = 0. We proceed as follows: we had the hypergeometric equation

${\displaystyle x(1-x)y^{″}+(\gamma -(1+\alpha +\beta )x)y^{\prime }-\alpha \beta y=0.}$

Let z = 1 - x. Then

${\displaystyle \begin{array}{cc}& \frac{dy}{dx}=\frac{dy}{dz}\times \frac{dz}{dx}=-\frac{dy}{dz}=-y^{\prime }\\ & \frac{d^{2}y}{d{x}^2}=\frac{d}{dx}\left(\frac{dy}{dx}\right)=\frac{d}{dx}(-\frac{dy}{dz})=\frac{d}{dz}(-\frac{dy}{dz})\times \frac{dz}{dx}=\frac{d^{2}y}{d{z}^2}=y^{″}\end{array}}$

Hence, the equation takes the form

${\displaystyle z(1-z)y^{″}+(\alpha +\beta -\gamma +1-(1+\alpha +\beta )z)y^{\prime }-\alpha \beta y=0.}$

Since z = 1 - x, the solution of the hypergeometric equation at x = 1 is the same as the solution for this equation at z = 0. But the solution at z = 0 is identical to the solution we obtained for the point x = 0, if we replace each γ by α + β - γ + 1. Hence, to get the solutions, we just make this substitution in the previous results. Note also that for x = 0, c₁ = 0 and c₂ = 1 - γ. Hence, in our case, c₁ = 0 while c₂ = γ - α - β. Let us now write the solutions. It should be noted in the following we replaced each z by 1 - x.

${\displaystyle \begin{array}{cc}y& =A\cdot {}_2{F}_1(\alpha ,\beta ;\alpha +\beta -\gamma +1;1-x)\\ & +B(1-x{)}^{\gamma -\alpha -\beta }{}_2{F}_1(\gamma -\alpha ,\gamma -\beta ;\gamma -\alpha -\beta +1;1-x)\end{array}}$

${\displaystyle \begin{array}{cc}y& =C\cdot {}_2{F}_1(\alpha ,\beta ;1;1-x)\\ & +D{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(\alpha {)}_r(\beta {)}_r}{(1{)}_r^2}(\ln (1-x)+{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{\alpha +k}+\frac{1}{\beta +k}-\frac{2}{1+k}))(1-x{)}^r\end{array}}$

${\displaystyle \begin{array}{cc}y& =\frac{E}{(\alpha +\beta -\gamma +1{)}_{\gamma -\alpha -\beta -1}}{\displaystyle \sum _{r=1-\gamma }^{\mathrm{\infty }}}\frac{(\alpha {)}_r(\beta {)}_r}{(1{)}_r(1{)}_{r+\alpha +\beta -\gamma }}(1-x{)}^r+\\ & \begin{array}{cc}+F(1-x{)}^{\gamma -\alpha -\beta }{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}& \frac{(\gamma -\alpha -\beta )(\gamma -\beta {)}_r(\gamma -\alpha {)}_r}{(1+\gamma -\alpha -\beta {)}_r(1{)}_r}(\ln (1-x)+\frac{1}{\gamma -\alpha -\beta }+\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{k+\gamma -\beta }+\frac{1}{k+\gamma -\alpha }-\frac{1}{1+k+\gamma -\alpha -\beta }-\frac{1}{1+k}))(1-x{)}^r\end{array}\end{array}}$

${\displaystyle \begin{array}{cc}y& =\frac{G}{(1+\gamma -\alpha -\beta {)}_{\alpha +\beta -\gamma -1}}(1-x{)}^{\gamma -\alpha -\beta }{\displaystyle \sum _{r=\alpha +\beta -\gamma }^{\mathrm{\infty }}}\frac{(\gamma -\beta {)}_r(\gamma -\alpha {)}_r}{(1{)}_r(1{)}_{r+\gamma -\alpha -\beta }}(1-x{)}^r+\\ & \begin{array}{cc}+H{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}& \frac{(\gamma -\alpha -\beta )(\gamma -\beta {)}_r(\gamma -\alpha {)}_r}{(1+\gamma -\alpha -\beta {)}_r(1{)}_r}(\ln (1-x)+\frac{1}{\alpha +\beta -\gamma }+\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{\alpha +k}+\frac{1}{\beta +k}-\frac{1}{1+k}-\frac{1}{\alpha +\beta -\gamma +1+k}))(1-x{)}^r\end{array}\end{array}}$

Finally, we study the singularity as x → ∞. Since we can't study this directly, we let x = s⁻¹. Then the solution of the equation as x → ∞ is identical to the solution of the modified equation when s = 0. We had

${\displaystyle \begin{array}{cc}& x(1-x)y^{″}+\{\gamma -(1+\alpha +\beta )x\}{y}^{\prime }-\alpha \beta y=0\\ & \frac{dy}{dx}=\frac{dy}{ds}\times \frac{ds}{dx}=-s^{{}^2}\times \frac{dy}{ds}=-s^{{}^2}{y}^{\prime }\\ & \frac{d^{2}y}{d{x}^2}=\frac{d}{dx}\left(\frac{dy}{dx}\right)=\frac{d}{dx}(-s^{{}^2}\times \frac{dy}{ds})=\frac{d}{ds}(-s^{{}^2}\times \frac{dy}{ds})\times \frac{ds}{dx}\\ & ((-2s)\times \frac{dy}{ds}+(-s^2)\frac{d^{2}y}{d{s}^2})\times (-s^2)=2s^3{y}^{\prime }+s^4{y}^{″}\end{array}}$

Hence, the equation takes the new form

${\displaystyle \frac{1}{s}(1-\frac{1}{s})(2s^3{y}^{\prime }+s^4{y}^{″})+(\gamma -(1+\alpha +\beta )\frac{1}{s})(-s^2{y}^{\prime })-\alpha \beta y=0}$

which reduces to

${\displaystyle (s^3-s^2)y^{″}+((2-\gamma )s^2+(\alpha +\beta -1)s)y^{\prime }-\alpha \beta y=0.}$

Let

${\displaystyle P_0(s)=-\alpha \beta ,P_1(s)=((2-\gamma )s^2+(\alpha +\beta -1)s),P_2(s)=(s^3-s^2).}$

As we said, we shall only study the solution when s = 0. As we can see, this is a singular point since P₂(0) = 0. To see if it's regular,

${\displaystyle \begin{array}{cc}& \underset{s\to a}{\lim }\frac{(s-a)P_1(s)}{P_2(s)}=\underset{s\to 0}{\lim }\frac{(s-0)((2-\gamma )s^2+(\alpha +\beta -1)s)}{(s^3-s^2)}=\underset{s\to 0}{\lim }\frac{((2-\gamma )s^2+(\alpha +\beta -1)s)}{s^2-s}\\ & =\underset{s\to 0}{\lim }\frac{((2-\gamma )s+(\alpha +\beta -1))}{s-1}=1-\alpha -\beta \text{. }\\ & \underset{s\to a}{\lim }\frac{{(s-a)}^2{P}_0(s)}{P_2(s)}=\underset{s\to 0}{\lim }\frac{{(s-0)}^2(-\alpha \beta )}{(s^3-s^2)}=\underset{x\to 0}{\lim }\frac{(-\alpha \beta )}{s-1}=\alpha \beta \text{.}\end{array}}$

Hence, both limits exist and s = 0 is a regular singular point. Therefore, we assume the solution takes the form

${\displaystyle y=\sum _{r=0}^{\mathrm{\infty }}{a}_r{s}^{r+c}}$

with a₀ ≠ 0.

Hence,

${\displaystyle y^{\prime }=\sum _{r=0}^{\mathrm{\infty }}{a}_r(r+c)s^{r+c-1}}$ and ${\displaystyle y^{″}=\sum _{r=0}^{\mathrm{\infty }}{a}_r(r+c)(r+c-1)s^{r+c-2}.}$

Substituting in the modified hypergeometric equation we get

${\displaystyle \begin{array}{cc}& (s^3-s^2)y^{″}+((2-\gamma )s^2+(\alpha +\beta -1)s)y^{\prime }-\alpha \beta y=0\\ & s^3\sum _{r=0}^{\mathrm{\infty }}{a}_r(r+c)(r+c-1)s^{r+c-2}-s^2\sum _{r=0}^{\mathrm{\infty }}{a}_r(r+c)(r+c-1)x^{r+c-2}\\ & +(2-\gamma )s^2\sum _{r=0}^{\mathrm{\infty }}{a}_r(r+c)s^{r+c-1}+(\alpha +\beta -1)s\sum _{r=0}^{\mathrm{\infty }}{a}_r(r+c)s^{r+c-1}-\alpha \beta \sum _{r=0}^{\mathrm{\infty }}{a}_r{s}^{r+c}=0\end{array}}$

i.e.,

${\displaystyle \begin{array}{cc}\sum _{r=0}^{\mathrm{\infty }}& a_r(r+c)(r+c-1)s^{r+c+1}-\sum _{r=0}^{\mathrm{\infty }}{a}_r(r+c)(r+c-1)x^{r+c}\\ & +(2-\gamma )\sum _{r=0}^{\mathrm{\infty }}{a}_r(r+c)s^{r+c+1}+(\alpha +\beta -1)\sum _{r=0}^{\mathrm{\infty }}{a}_r(r+c)s^{r+c}-\alpha \beta \sum _{r=0}^{\mathrm{\infty }}{a}_r{s}^{r+c}=0\end{array}}$

In order to simplify this equation, we need all powers to be the same, equal to r + c, the smallest power. Hence, we switch the indices as follows

${\displaystyle \begin{array}{cc}& \sum _{r=1}^{\mathrm{\infty }}{a}_{r-1}(r+c-1)(r+c-2)s^{r+c}-\sum _{r=0}^{\mathrm{\infty }}{a}_r(r+c)(r+c-1)x^{r+c}\\ & +(2-\gamma )\sum _{r=1}^{\mathrm{\infty }}{a}_{r-1}(r+c-1)s^{r+c}+(\alpha +\beta -1)\sum _{r=0}^{\mathrm{\infty }}{a}_r(r+c)s^{r+c}-\alpha \beta \sum _{r=0}^{\mathrm{\infty }}{a}_r{s}^{r+c}=0\end{array}}$

Thus, isolating the first term of the sums starting from 0 we get

${\displaystyle \begin{array}{cc}& a_0\{-(c)(c-1)+(\alpha +\beta -1)(c)-\alpha \beta \}{s}^c+\sum _{r=1}^{\mathrm{\infty }}{a}_{r-1}(r+c-1)(r+c-2)s^{r+c}\\ & -\sum _{r=1}^{\mathrm{\infty }}{a}_r(r+c)(r+c-1)x^{r+c}+(2-\gamma )\sum _{r=1}^{\mathrm{\infty }}{a}_{r-1}(r+c-1)s^{r+c}\\ & +(\alpha +\beta -1)\sum _{r=1}^{\mathrm{\infty }}{a}_r(r+c)s^{r+c}-\alpha \beta \sum _{r=1}^{\mathrm{\infty }}{a}_r{s}^{r+c}=0\\ \end{array}}$

Now, from the linear independence of all powers of s (i.e., of the functions 1, s, s², ..., the coefficients of s^k vanish for all k. Hence, from the first term we have

${\displaystyle a_0\{-(c)(c-1)+(\alpha +\beta -1)(c)-\alpha \beta \}=0}$

which is the indicial equation. Since a₀ ≠ 0, we have

${\displaystyle (c)(-c+1+\alpha +\beta -1)-\alpha \beta )=0.}$

Hence, c₁ = α and c₂ = β.

Also, from the rest of the terms we have

${\displaystyle \begin{array}{cc}& \{(r+c-1)(r+c-2)+(2-\gamma )(r+c-1)\}{a}_{r-1}\\ & +\{-(r+c)(r+c-1)+(\alpha +\beta -1)(r+c)-\alpha \beta \}{a}_r=0\end{array}}$

Hence,

${\displaystyle \begin{array}{cc}& a_r=-\frac{\{(r+c-1)(r+c-2)+(2-\gamma )(r+c-1)\}}{\{-(r+c)(r+c-1)+(\alpha +\beta -1)(r+c)-\alpha \beta \}}{a}_{r-1}\\ & =\frac{\{(r+c-1)(r+c-\gamma )\}}{\{(r+c)(r+c-\alpha -\beta )+\alpha \beta \}}{a}_{r-1}\end{array}}$

But

${\displaystyle \begin{array}{cc}(r+c)(r+c-\alpha -\beta )+\alpha \beta & =(r+c-\alpha )(r+c)-\beta (r+c)+\alpha \beta \\ & =(r+c-\alpha )(r+c)-\beta (r+c-\alpha ).\end{array}}$

Hence, we get the recurrence relation

${\displaystyle a_r=\frac{(r+c-1)(r+c-\gamma )}{(r+c-\alpha )(r+c-\beta )}{a}_{r-1},\mathrm{\forall }r\ge 1}$

Let's now simplify this relation by giving a_r in terms of a₀ instead of a_{r − 1}. From the recurrence relation,

${\displaystyle \begin{array}{cc}& a_1=\frac{(c)(c+1-\gamma )}{(c+1-\alpha )(c+1-\beta )}{a}_0\\ & a_2=\frac{(c+1)(c+2-\gamma )}{(c+2-\alpha )(c+2-\beta )}{a}_1=\frac{(c+1)(c)(c+2-\gamma )(c+1-\gamma )}{(c+2-\alpha )(c+1-\alpha )(c+2-\beta )(c+1-\beta )}{a}_0\\ & =\frac{(c{)}_2(c+1-\gamma {)}_2}{(c+1-\alpha {)}_2(c+1-\beta {)}_2}{a}_0\end{array}}$

As we can see,

${\displaystyle a_r=\frac{(c{)}_r(c+1-\gamma {)}_r}{(c+1-\alpha {)}_r(c+1-\beta {)}_r}{a}_0\mathrm{\forall }\text{r}\ge \text{0}}$

Hence, our assumed solution takes the form

${\displaystyle y=a_0\sum _{r=0}^{\mathrm{\infty }}\left(\frac{(c{)}_r(c+1-\gamma {)}_r}{(c+1-\alpha {)}_r(c+1-\beta {)}_r}{s}^{r+c}\right)}$

We are now ready to study the solutions corresponding to the different cases for c₁ − c₂ = α − β.

Then y₁ = y|_{c = α} and y₂ = y|_{c = β}. Since

${\displaystyle y=a_0\sum _{r=0}^{\mathrm{\infty }}\left(\frac{(c{)}_r(c+1-\gamma {)}_r}{(c+1-\alpha {)}_r(c+1-\beta {)}_r}{s}^{r+c}\right)}$,

we have

${\displaystyle \begin{array}{cc}{y}_1& =a_0\sum _{r=0}^{\mathrm{\infty }}\left(\frac{(\alpha {)}_r(\alpha +1-\gamma {)}_r}{(1{)}_r(\alpha +1-\beta {)}_r}{s}^{r+\alpha }\right)=a_0{s}_2^{\alpha }{F}_1(\alpha ,\alpha +1-\gamma ;\alpha +1-\beta ;\text{ s)}\\ y_2& =a_0\sum _{r=0}^{\mathrm{\infty }}\left(\frac{(\beta {)}_r(\beta +1-\gamma {)}_r}{(\beta +1-\alpha {)}_r(1{)}_r}{s}^{r+\beta }\right)=a_0{s}_2^{\beta }{F}_1(\beta ,\beta +1-\gamma ;\beta +1-\alpha ;\text{ s)}\end{array}}$

Hence, y = A′y₁ + B′y₂. Let A′a₀ = A and B′a₀ = B. Then, noting that s = x^-1,

${\displaystyle \begin{array}{cc}& y=A{x}_2^{-\alpha }{F}_1(\alpha ,\alpha +1-\gamma ;\alpha +1-\beta ;{\text{ x}}^{-1})+B{x}_2^{-\beta }{F}_1(\beta ,\beta +1-\gamma ;\beta +1-\alpha ;{\text{ x}}^{-1})\\ \end{array}}$

Then y₁ = y|_{c = α}. Since α = β, we have

${\displaystyle y=a_0\sum _{r=0}^{\mathrm{\infty }}\left(\frac{(c{)}_r(c+1-\gamma {)}_r}{{((c+1-\alpha {)}_r)}^2}{s}^{r+c}\right)}$

Hence,

${\displaystyle \begin{array}{cc}& y_1=a_0\sum _{r=0}^{\mathrm{\infty }}\left(\frac{(\alpha {)}_r(\alpha +1-\gamma {)}_r}{(1{)}_r(1{)}_r}{s}^{r+\alpha }\right)=a_0{s}_2^{\alpha }{F}_1(\alpha ,\alpha +1-\gamma ;\text{ 1; s)}\\ & y_2=\frac{\partial y}{\partial c}\text{ at }c=\alpha \end{array}}$

To calculate this derivative, let

${\displaystyle \begin{array}{cc}& M_r=\frac{(c{)}_r(c+1-\gamma {)}_r}{{((c+1-\alpha {)}_r)}^2}\end{array}}$

Then using the method in the case γ = 1 above, we get

${\displaystyle \begin{array}{cc}& \frac{\partial M_r}{\partial c}=\frac{(c{)}_r(c+1-\gamma {)}_r}{{((c+1-\alpha {)}_r)}^2}\left\{\sum _{k=0}^{r-1}(\frac{1}{c+k}+\frac{1}{c+1-\gamma +k}-\frac{2}{c+1-\alpha +k})\right\}\\ \end{array}}$

Now,

${\displaystyle \begin{array}{c}y=a_0{s}^c\sum _{r=0}^{\mathrm{\infty }}\left(\frac{(c{)}_r(c+1-\gamma {)}_r}{{((c+1-\alpha {)}_r)}^2}{s}^r\right)=a_0{s}^c\sum _{r=0}^{\mathrm{\infty }}{M}_r{s}^r\end{array}}$

Hence

${\displaystyle \begin{array}{cc}& =a_0{s}^c\text{ ln(s)}\sum _{r=0}^{\mathrm{\infty }}\left(\frac{(c{)}_r(c+1-\gamma {)}_r}{{((c+1-\alpha {)}_r)}^2}{s}^r\right)\\ & +a_0{s}^c\sum _{r=0}^{\mathrm{\infty }}\left(\frac{(c{)}_r(c+1-\gamma {)}_r}{{((c+1-\alpha {)}_r)}^2}\left\{\sum _{k=0}^{r-1}(\frac{1}{c+k}+\frac{1}{c+1-\gamma +k}-\frac{2}{c+1-\alpha +k})\right\}{s}^r\right)\\ \end{array}}$

Hence,

${\displaystyle \begin{array}{cc}& \frac{\partial y}{\partial c}=a_0{s}^c\sum _{r=0}^{\mathrm{\infty }}\left(\left(\frac{(c{)}_r(c+1-\gamma {)}_r}{{((c+1-\alpha {)}_r)}^2}\right)(\ln s+\sum _{k=0}^{r-1}(\frac{1}{c+k}+\frac{1}{c+1-\gamma +k}-\frac{2}{c+1-\alpha +k}))s^r\right)\\ \end{array}}$

For c = α we get

${\displaystyle \begin{array}{cc}& y_2=a_0{s}^{\alpha }\sum _{r=0}^{\mathrm{\infty }}\left(\left(\frac{(\alpha {)}_r(\alpha +1-\gamma {)}_r}{{((1{)}_r)}^2}\right)(\ln s+\sum _{k=0}^{r-1}(\frac{1}{\alpha +k}+\frac{1}{\alpha +1-\gamma +k}-\frac{2}{1+k}))s^r\right)\\ & \end{array}}$

Hence, y = C′y₁ + D′y₂. Let C′a₀ = C and D′a₀ = D. Noting that s = x^-1,

${\displaystyle y=C{x}_2^{-\alpha }{F}_1(\alpha ,\alpha +1-\gamma ;1;x^{-1})}$

${\displaystyle +D{x}^{-\alpha }\sum _{r=0}^{\mathrm{\infty }}\left(\left(\frac{(\alpha {)}_r(\alpha +1-\gamma {)}_r}{{((1{)}_r)}^2}\right)(\ln x^{-1}+\sum _{k=0}^{r-1}(\frac{1}{\alpha +k}+\frac{1}{\alpha +1-\gamma +k}-\frac{2}{1+k}))x^{-r}\right)}$

From the recurrence relation

${\displaystyle a_r=\frac{(r+c-1)(r+c-\gamma )}{(r+c-\alpha )(r+c-\beta )}{a}_{r-1}}$

we see that when c = β (the smaller root), a_{α - β} → ∞. Hence, we must make the substitution a₀ = b₀(c − c_i), where c_i is the root for which our solution is infinite. Hence, we take a₀ = b₀(c − β) and our assumed solution takes the new form

${\displaystyle y_b=b_0\sum _{r=0}^{\mathrm{\infty }}\left(\frac{(c-\beta )(c{)}_r(c+1-\gamma {)}_r}{(c+1-\alpha {)}_r(c+1-\beta {)}_r}{s}^{r+c}\right)}$

Then y₁ = y_b|_{c = β}. As we can see, all terms before

${\displaystyle \frac{(c-\beta )(c{)}_{\alpha -\beta }(c+1-\gamma {)}_{\alpha -\beta }}{(c+1-\alpha {)}_{\alpha -\beta }(c+1-\beta {)}_{\alpha -\beta }}{s}^{\alpha -\beta }}$

vanish because of the c − β in the numerator.

But starting from this term, the c − β in the numerator vanishes. To see this, note that

${\displaystyle (c+1-\alpha {)}_{\alpha -\beta }=(c+1-\alpha )(c+2-\alpha )\cdots (c-\beta ).}$

Hence, our solution takes the form

${\displaystyle \begin{array}{cc}& y_1=b_0(\frac{(\beta {)}_{\alpha -\beta }(\beta +1-\gamma {)}_{\alpha -\beta }}{(\beta +1-\alpha {)}_{\alpha -\beta -1}(1{)}_{\alpha -\beta }}{s}^{\alpha -\beta }+\frac{(\beta {)}_{\alpha -\beta +1}(\beta +1-\gamma {)}_{\alpha -\beta +1}}{(\beta +1-\alpha {)}_{\alpha -\beta -1}(1)(1{)}_{\alpha -\beta +1}}{s}^{\alpha -\beta +1}+...)\\ & =\frac{b_0}{(\beta +1-\alpha {)}_{\alpha -\beta -1}}\sum _{r=\alpha -\beta }^{\mathrm{\infty }}\left(\frac{(\beta {)}_r(\beta +1-\gamma {)}_r}{(1{)}_r(1{)}_{r+\beta -\alpha }}{s}^r\right)\\ & \\ \end{array}}$

Now,

${\displaystyle y_2={\frac{\partial y_b}{\partial c}|}_{c=\alpha }.}$

To calculate this derivative, let

${\displaystyle M_r=\frac{(c-\beta )(c{)}_r(c+1-\gamma {)}_r}{(c+1-\alpha {)}_r(c+1-\beta {)}_r}.}$

Then using the method in the case γ = 1 above we get

${\displaystyle \begin{array}{cc}\frac{\partial M_r}{\partial c}& =\frac{(c-\beta )(c{)}_r(c+1-\gamma {)}_r}{(c+1-\alpha {)}_r(c+1-\beta {)}_r}(\frac{1}{c-\beta }+\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+k}+\frac{1}{c+1-\gamma +k}-\frac{1}{c+1-\alpha +k}-\frac{1}{c+1-\beta +k}))\end{array}}$

Now,

${\displaystyle y_b=b_0\sum _{r=0}^{\mathrm{\infty }}\left(\frac{(c-\beta )(c{)}_r(c+1-\gamma {)}_r}{(c+1-\alpha {)}_r(c+1-\beta {)}_r}{s}^{r+c}\right)=b_0{x}^c\sum _{r=0}^{\mathrm{\infty }}{M}_r{s}^r}$

Hence,

${\displaystyle \begin{array}{cc}\frac{\partial y}{\partial c}& =b_0{s}^c\ln (s){\displaystyle \sum _{r=0}^{\mathrm{\infty }}}\frac{(c-\beta )(c{)}_r(c+1-\gamma {)}_r}{(c+1-\alpha {)}_r(c+1-\beta {)}_r}{s}^r\\ & \begin{array}{cc}+b_0{s}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}& \frac{(c-\beta )(c{)}_r(c+1-\gamma {)}_r}{(c+1-\alpha {)}_r(c+1-\beta {)}_r}(\frac{1}{c-\beta }+\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+k}+\frac{1}{c+1-\gamma +k}-\frac{1}{c+1-\alpha +k}-\frac{1}{c+1-\beta +k}))s^r\end{array}\end{array}}$

Hence,

${\displaystyle \begin{array}{cc}\frac{\partial y}{\partial c}=b_0{s}^c{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}& \frac{(c-\beta )(c{)}_r(c+1-\gamma {)}_r}{(c+1-\alpha {)}_r(c+1-\beta {)}_r}(\ln s+\frac{1}{c-\beta }+\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{c+k}+\frac{1}{c+1-\gamma +k}-\frac{1}{c+1-\alpha +k}-\frac{1}{c+1-\beta +k}))s^r\end{array}}$

At c = α we get y₂. Hence, y = E′y₁ + F′y₂. Let E′b₀ = E and F′b₀ = F. Noting that s = x^-1 we get

${\displaystyle \begin{array}{cc}y& =\frac{E}{(\beta +1-\alpha {)}_{\alpha -\beta -1}}{\displaystyle \sum _{r=\alpha -\beta }^{\mathrm{\infty }}}\frac{(\beta {)}_r(\beta +1-\gamma {)}_r}{(1{)}_r(1{)}_{r+\beta -\alpha }}{x}^{-r}\\ & \begin{array}{cc}+F{x}^{-\alpha }{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}& \frac{(\alpha -\beta )(\alpha {)}_r(\alpha +1-\gamma {)}_r}{(1{)}_r(\alpha +1-\beta {)}_r}(\ln x^{-1}+\frac{1}{\alpha -\beta }\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{\alpha +k}+\frac{1}{\alpha +1+k-\gamma }-\frac{1}{1+k}-\frac{1}{\alpha +1+k-\beta }))x^{-r}\end{array}\end{array}}$

From the symmetry of the situation here, we see that

${\displaystyle \begin{array}{cc}y& =\frac{G}{(\alpha +1-\beta {)}_{\beta -\alpha -1}}{\displaystyle \sum _{r=\beta -\alpha }^{\mathrm{\infty }}}\frac{(\alpha {)}_r(\alpha +1-\gamma {)}_r}{(1{)}_r(1{)}_{r+\alpha -\beta }}{x}^{-r}\\ & \begin{array}{cc}+H{x}^{-\beta }{\displaystyle \sum _{r=0}^{\mathrm{\infty }}}& \frac{(\beta -\alpha )(\beta {)}_r(\beta +1-\gamma {)}_r}{(1{)}_r(\beta +1-\alpha {)}_r}(\ln x^{-1}+\frac{1}{\beta -\alpha }\\ & +{\displaystyle \sum _{k=0}^{r-1}}(\frac{1}{\beta +k}+\frac{1}{\beta +1+k-\gamma }-\frac{1}{1+k}-\frac{1}{\beta +1+k-\alpha }))x^{-r}\end{array}\end{array}}$

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