## Solve 2nd Order Differential Equations

## Apps.2ndOrderDifferential History

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Another scenario is when the damping coefficient *c = (0.9 + 0.7 t)* is not known but must be estimated from data. The value of *c* is allowed to change every 0.5 seconds. The true and estimated values of *c* are shown on the plot below. Predicted and actual values of *y* give excellent agreement.

Another scenario is when the damping coefficient *c = (0.9 + 0.7 t)* is not known but must be estimated from data. The value of *c* is allowed to change every 0.5 seconds. The true and estimated values of *c* are shown on the plot below. Predicted and actual values of *y* are in agreement even though the estimate is not continuous but only changes at discrete time points.

Another scenario is when the damping coefficient *c = (0.9 + 0.7 t)* is not known but must be estimated from data. The value of *c* is allowed to change every 0.5 seconds. The true and estimated values of *c* are shown on the plot below. Predicted and actual values of *y* give excellent agreement.

(:title Solve 2nd Order ODE:)

(:title Solve 2nd Order Differential Equations:)

(:html:) <iframe width="560" height="315" src="https://www.youtube.com/embed/JLtRK4Z1tEg" frameborder="0" allowfullscreen></iframe> (:htmlend:)

A numerical solution to this equation can be computed with a variety of different solvers and programming environments. Solution files are available in Julia, MATLAB, and Python below or through a web-interface. Each of these example problems can be easily modified for solutions to other differential equations as well.

To numerically solve a differential equation with higher-order terms, it can be broken into multiple first-order differential equations as shown below.

A numerical solution to this equation can be computed with a variety of different solvers and programming environments. Solution files are available in MATLAB, Python, and Julia below or through a web-interface. Each of these example problems can be easily modified for solutions to other second-order differential equations as well.

A differential equation relates some function with the derivatives of the function. Functions typically represent physical quantities and the derivatives represent a rate of change. The differential equation defines a relationship between the quantity and the derivative. Differential equations are very common in fields such as biology, engineering, economics, and physics.

Differential equations may be studied from several different perspectives. Only simple differential equations are solvable by explicit formulas while more complex systems are typically solved with numerical methods. Numerical methods have been developed to determine solutions with a given degree of accuracy.

The term with highest number of derivatives describes the order of the differential equation. A first-order differential equation only contains single derivatives. A second-order differential equation has at least one term with a double derivative. Higher order differential equations are also possible.

Below is an example of a second-order differential equation.

A numerical solution to this equation can be computed with a variety of different solvers and programming environments. Solution files are available in Julia, MATLAB, and Python below or through a web-interface. Each of these example problems can be easily modified for solutions to other differential equations as well.

(:title Solve 2nd Order ODE:) (:keywords nonlinear, linear, differential equation, ODE:) (:description APMonitor Documentation: Simulation, optimization, estimation, and control of differential equations with solutions in Python, MATLAB, and Julia:)