An initial value problem is a differential equation

${\displaystyle y'(t)=f(t,y(t))}$  with ${\displaystyle f\colon \Omega \subset \mathbb {R} \times \mathbb {R} ^{n}\to \mathbb {R} ^{n}}$  where ${\displaystyle \Omega }$  is an open set of ${\displaystyle \mathbb {R} \times \mathbb {R} ^{n}}$ ,

together with a point in the domain of ${\displaystyle f}$ 

${\displaystyle (t_{0},y_{0})\in \Omega ,}$ 

called the initial condition.

A solution to an initial value problem is a function ${\displaystyle y}$  that is a solution to the differential equation and satisfies

${\displaystyle y(t_{0})=y_{0}.}$ 

In higher dimensions, the differential equation is replaced with a family of equations ${\displaystyle y_{i}'(t)=f_{i}(t,y_{1}(t),y_{2}(t),\dotsc )}$ , and ${\displaystyle y(t)}$  is viewed as the vector ${\displaystyle (y_{1}(t),\dotsc ,y_{n}(t))}$ , most commonly associated with the position in space. More generally, the unknown function ${\displaystyle y}$  can take values on infinite dimensional spaces, such as Banach spaces or spaces of distributions.

Initial value problems are extended to higher orders by treating the derivatives in the same way as an independent function, e.g. ${\displaystyle y''(t)=f(t,y(t),y'(t))}$ .

The Picard–Lindelöf theorem guarantees a unique solution on some interval containing t₀ if f is continuous on a region containing t₀ and y₀ and satisfies the Lipschitz condition on the variable y. The proof of this theorem proceeds by reformulating the problem as an equivalent integral equation. The integral can be considered an operator which maps one function into another, such that the solution is a fixed point of the operator. The Banach fixed point theorem is then invoked to show that there exists a unique fixed point, which is the solution of the initial value problem.

An older proof of the Picard–Lindelöf theorem constructs a sequence of functions which converge to the solution of the integral equation, and thus, the solution of the initial value problem. Such a construction is sometimes called "Picard's method" or "the method of successive approximations". This version is essentially a special case of the Banach fixed point theorem.

Hiroshi Okamura obtained a necessary and sufficient condition for the solution of an initial value problem to be unique. This condition has to do with the existence of a Lyapunov function for the system.

In some situations, the function f is not of class C¹, or even Lipschitz, so the usual result guaranteeing the local existence of a unique solution does not apply. The Peano existence theorem however proves that even for f merely continuous, solutions are guaranteed to exist locally in time; the problem is that there is no guarantee of uniqueness. The result may be found in Coddington & Levinson (1955, Theorem 1.3) or Robinson (2001, Theorem 2.6). An even more general result is the Carathéodory existence theorem, which proves existence for some discontinuous functions f.

A simple example is to solve ${\displaystyle y'(t)=0.85y(t)}$  and ${\displaystyle y(0)=19}$ . We are trying to find a formula for ${\displaystyle y(t)}$  that satisfies these two equations.

Rearrange the equation so that ${\displaystyle y}$  is on the left hand side

${\displaystyle {\frac {y'(t)}{y(t)}}=0.85}$ 

Now integrate both sides with respect to ${\displaystyle t}$  (this introduces an unknown constant ${\displaystyle B}$ ).

${\displaystyle \int {\frac {y'(t)}{y(t)}}\,dt=\int 0.85\,dt}$ 

${\displaystyle \ln |y(t)|=0.85t+B}$ 

Eliminate the logarithm with exponentiation on both sides

${\displaystyle |y(t)|=e^{B}e^{0.85t}}$ 

Let ${\displaystyle C}$  be a new unknown constant, ${\displaystyle C=\pm e^{B}}$ , so

${\displaystyle y(t)=Ce^{0.85t}}$ 

Now we need to find a value for ${\displaystyle C}$ . Use ${\displaystyle y(0)=19}$  as given at the start and substitute 0 for ${\displaystyle t}$  and 19 for ${\displaystyle y}$ 

${\displaystyle 19=Ce^{0.85\cdot 0}}$ 

${\displaystyle C=19}$ 

this gives the final solution of ${\displaystyle y(t)=19e^{0.85t}}$ .

Second example

The solution of

${\displaystyle y'+3y=6t+5,\qquad y(0)=3}$ 

can be found to be

${\displaystyle y(t)=2e^{-3t}+2t+1.\,}$ 

Indeed,

${\displaystyle {\begin{aligned}y'+3y&={\tfrac {d}{dt}}(2e^{-3t}+2t+1)+3(2e^{-3t}+2t+1)\\&=(-6e^{-3t}+2)+(6e^{-3t}+6t+3)\\&=6t+5.\end{aligned}}}$ 

• Boundary value problem
• Constant of integration
• Integral curve