Midpoint method

For the midpoint rule in numerical quadrature, see rectangle method.

Illustration of the midpoint method assuming that

y_{n}

equals the exact value

y(t_{n}).

The midpoint method computes

y_{n+1}

so that the red chord is approximately parallel to the tangent line at the midpoint (the green line).

In numerical analysis, a branch of applied mathematics, the midpoint method is a one-step method for numerically solving the differential equation,

y'(t)=f(t,y(t)),\quad y(t_{0})=y_{0}

The explicit midpoint method is given by the formula

y_{n+1}=y_{n}+hf\left(t_{n}+{\frac {h}{2}},y_{n}+{\frac {h}{2}}f(t_{n},y_{n})\right),\qquad \qquad (1e)

the implicit midpoint method by

y_{n+1}=y_{n}+hf\left(t_{n}+{\frac {h}{2}},{\frac {1}{2}}(y_{n}+y_{n+1})\right),\qquad \qquad (1i)

for $n=0,1,2,\dots$ Here, $h$ is the step size — a small positive number, $t_{n}=t_{0}+nh,$ and $y_{n}$ is the computed approximate value of $y(t_{n}).$ The explicit midpoint method is also known as the modified Euler method,^[1] the implicit method is the most simple collocation method, and, applied to Hamiltionian dynamics, a symplectic integrator.

The name of the method comes from the fact that in the formula above the function $f$ giving the slope of the solution is evaluated at $t=t_{n}+h/2,$ which is the midpoint between $t_{n}$ at which the value of y(t) is known and $t_{n+1}$ at which the value of y(t) needs to be found.

The local error at each step of the midpoint method is of order $O\left(h^{3}\right)$ , giving a global error of order $O\left(h^{2}\right)$ . Thus, while more computationally intensive than Euler's method, the midpoint method's error generally decreases faster as $h\to 0$ .

The methods are examples of a class of higher-order methods known as Runge-Kutta methods.

Derivation of the midpoint method

Illustration of numerical integration for the equation

y'=y,y(0)=1.

Blue: the Euler method, green: the midpoint method, red: the exact solution,

y=e^{t}.

The step size is

h=1.0.

The same illustration for

h=0.25.

It is seen that the midpoint method converges faster than the Euler method.

The midpoint method is a refinement of the Euler's method

y_{n+1}=y_{n}+hf(t_{n},y_{n}),\,

and is derived in a similar manner. The key to deriving Euler's method is the approximate equality

y(t+h)\approx y(t)+hf(t,y(t))\qquad \qquad (2)

which is obtained from the slope formula

y'(t)\approx {\frac {y(t+h)-y(t)}{h}}\qquad \qquad (3)

and keeping in mind that $y'=f(t,y).$

For the midpoint methods, one replaces (3) with the more accurate

y'\left(t+{\frac {h}{2}}\right)\approx {\frac {y(t+h)-y(t)}{h}}

when instead of (2) we find

y(t+h)\approx y(t)+hf\left(t+{\frac {h}{2}},y\left(t+{\frac {h}{2}}\right)\right).\qquad \qquad (4)

One cannot use this equation to find $y(t+h)$ as one does not know $y$ at $t+h/2$ . The solution is then to use a Taylor series expansion exactly as if using the Euler method to solve for $y(t+h/2)$ :

y\left(t+{\frac {h}{2}}\right)\approx y(t)+{\frac {h}{2}}y'(t)=y(t)+{\frac {h}{2}}f(t,y(t)),

which, when plugged in (4), gives us

y(t+h)\approx y(t)+hf\left(t+{\frac {h}{2}},y(t)+{\frac {h}{2}}f(t,y(t))\right)

and the explicit midpoint method (1e).

The implicit method (1i) is obtained by approximating the value at the half step $t+h/2$ by the midpoint of the line segment from $y(t)$ to $y(t+h)$

y\left(t+{\frac {h}{2}}\right)\approx {\frac {1}{2}}{\bigl (}y(t)+y(t+h){\bigr )}

and thus

{\frac {y(t+h)-y(t)}{h}}\approx y'\left(t+{\frac {h}{2}}\right)\approx k=f\left(t+{\frac {h}{2}},{\frac {1}{2}}{\bigl (}y(t)+y(t+h){\bigr )}\right)

Inserting the approximation $y_{n}+h\,k$ for $y(t_{n}+h)$ results in the implicit Runge-Kutta method

{\begin{aligned}k&=f\left(t_{n}+{\frac {h}{2}},y_{n}+{\frac {h}{2}}k\right)\\y_{n+1}&=y_{n}+h\,k\end{aligned}}

which contains the implicit Euler method with step size $h/2$ as its first part.

Because of the time symmetry of the implicit method, all terms of even degree in $h$ of the local error cancel, so that the local error is automatically of order ${\mathcal {O}}(h^{3})$ . Replacing the implicit with the explicit Euler method in the determination of $k$ results again in the explicit midpoint method.

Notes

↑ Süli & Mayers 2003, p. 328

References

Griffiths,D. V.; Smith, I. M. (1991). Numerical methods for engineers: a programming approach. Boca Raton: CRC Press. p. 218. ISBN 0-8493-8610-1.
Süli, Endre; Mayers, David (2003), An Introduction to Numerical Analysis, Cambridge University Press, ISBN 0-521-00794-1 .

Numerical methods for integration

First-order methods	Euler method Backward Euler Semi-implicit Euler Exponential Euler

Second-order methods	Verlet integration Velocity Verlet Trapezoidal rule Beeman's algorithm Midpoint method Heun's method Newmark-beta method Leapfrog integration

Higher-order methods	Exponential integrators Runge–Kutta methods List of Runge–Kutta methods Linear multistep method General linear methods Backward differentiation formula

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Midpoint method

Derivation of the midpoint method

See also

Notes

References