18 1 Mathematical Physics
Type IV equations reducible to linear form
Some equations that are not linear can be reduced to the linear form by a suitable
substitution, for example
(A)
dy
dx+Py=QynwhereP,Qare functions ofxalone, or constants. Equation (A) may be reduced to
the linear form (A), Type III by means of the substitutionx=y−n+^1.
Differential equations of the nth Order and of the nth degree
Consider special cases of linear differential equations.
Type I – The linear differential equation
(A)
dny
dxn+P 1
dn−^1 y
dxn−^1+P 2
dn−^2 y
dxn−^2+···+Pny= 0in which coefficientsP 1 ,P 2 ,...Pnare constants.
Consider the differential equation of third order
(B)
d^3 y
dx^3+P 1
d^2 y
dx^2+P 2
dy
dx+P 3 y= 0whereP 1 ,P 2 andP 3 are constants. The corresponding auxiliary equation is
r^3 +P 1 r^2 +P 2 r+P 3 = 0Let the roots ber 1 ,r 2 ,r 3.
Ifr 1 ,r 2 ,r 3 are real and distinct,
y=C 1 er^1 x+C 2 er^2 x+C 3 er^3 xIfr 1 ,r 2 ,r 3 are real and equaly=C 1 e−r^1 x+C 2 xe−r^2 x+C 3 x^2 e−r^3 xIn casea+bianda−biare each multiple roots of the auxiliary equation occur-
ringstimes, the solutions would be
C 1 eaxcosbx,C 2 xeaxcosbx,C 3 x^2 eaxcosbx,...Csxs−^1 eaxcosbx
C 1 ′eaxsinbx,C 2 ′xeaxsinbx,C 3 ′x^2 eaxsinbx,...Cs′xs−^1 eaxsinbxSummary for the rule for solving differential equations of the typedny
dxn+P 1
dn−^1 y
dxn−^1+P 2
dn−^2 y
dxn−^2+···+Pny= 0whereP 1 ,P 2 ,...Pnare constants.