Question 2.29: Find the complete and singular solution (s), if any, of the ......
Find the complete and singular solution (s), if any, of the following nonlinear PDEs of first order:
a) 1 + p²= zq;
b) z=p x+q y+p^2+p q+q^2;
c) z^2\left(p^2+q^2+1\right)=1.
a) Putting
F(x, y, z, p, q)=1+p^2-z q
we obtain
\frac{\partial F}{\partial x} \frac{\partial F}{\partial x}+p \frac{\partial F}{\partial z}=-p q \text { and } \frac{\partial F}{\partial y}+q \frac{\partial F}{\partial z}=-q^2
Then from system 2.38 we get
\frac{d x}{\frac{\partial F}{\partial p}}=\frac{d y}{\frac{\partial F}{\partial q}}=\frac{d z}{p \frac{\partial F}{\partial p}+q \frac{\partial F}{\partial q}}=\frac{-d p}{\frac{\partial F}{\partial x}+p \frac{\partial F}{\partial z}}=\frac{-d q}{\frac{\partial F}{\partial y}+q \frac{\partial F}{\partial z}} (2.38)
\frac{-d p}{-p q}=\frac{-d q}{-q^2}
and thus we can take q = ap for an arbitrary constant a. Solving in p the quadratic equation 1+p^2-z \cdot(a p)=0, we obtain
p_{1,2}=\frac{-a z \pm \sqrt{a^2 z^2-4}}{2} (2.46)
Let us take the sign ”+ ” in (2.46); then it holds
\int \frac{2 d z}{-a z+\sqrt{a^2 z^2-4}}=x+a y+b
where b is another arbitrary constant, and thus the complete solution is
x+a y+b+\frac{z}{4} \sqrt{a^2 z^2-4}-\frac{1}{a} \ln \left|a z+\sqrt{a^2 z^2-4}\right|+\frac{a z^2}{4}=0 .
There is no singular solution.
Remark 2.29.1 The reader should check that any nonlinear first order PDE of the form F(p, q) = 0 has a first integral q = ap, for an arbitrary constant a.
Remark 2.29.2 If we took the sign ”-” in (2.46), we would get another complete solution. This shows that the complete solution of a nonlinear first order PDE is not unique; in fact, it even might have infinitely many complete solutions.
b) One easily gets the complete solution
z=a x+b y+a^2+a b+b^2 \quad(a, b \text { arbitrary constants }) .
Taking the partial derivatives in a and b of the complete solution, respectively, we obtain the system
x + 2a + b = 0, y + a + 2b = 0.
Solving it in a and b, we get the singular solution
z=\frac{1}{3}\left(x y-x^2-y^2\right)
Remark 2.29.3 The equation of the form z = px + qy + f(p, q), for some given function f is called “generalized Clairaut’s equation” .
c ) The fist integral is p=\frac{\sqrt{1-z^2}}{z \sqrt{1+a^2}}, and thus t he complete integral is
-\sqrt{1-z^2}=\frac{1}{\sqrt{1+a^2}}(x+a y)+b
The singular integrals are z = 1 and z = -1.