Some properties of nonlinear dynamic systems are

• They do not follow the principle of superposition (linearity and homogeneity).
• They may have multiple isolated equilibrium points.
• They may exhibit properties such as limit cycle, bifurcation, chaos.
• Finite escape time: Solutions of nonlinear systems may not exist for all times.

There are several well-developed techniques for analyzing nonlinear feedback systems:

• Describing function method
• Phase plane method
• Lyapunov stability analysis
• Singular perturbation method
• The Popov criterion and the circle criterion for absolute stability
• Center manifold theorem
• Small-gain theorem
• Passivity analysis

Control design techniques for nonlinear systems also exist. These can be subdivided into techniques which attempt to treat the system as a linear system in a limited range of operation and use (well-known) linear design techniques for each region:

• Gain scheduling

Those that attempt to introduce auxiliary nonlinear feedback in such a way that the system can be treated as linear for purposes of control design:

• Feedback linearization

And Lyapunov based methods:

• Lyapunov redesign
• Control-Lyapunov function
• Nonlinear damping
• Backstepping
• Sliding mode control

An early nonlinear feedback system analysis problem was formulated by A. I. Lur'e. Control systems described by the Lur'e problem have a forward path that is linear and time-invariant, and a feedback path that contains a memory-less, possibly time-varying, static nonlinearity.

The linear part can be characterized by four matrices (A,B,C,D), while the nonlinear part is Φ(y) with ${\displaystyle {\frac {\Phi (y)}{y}}\in [a,b],\quad a<b\quad \forall y}$  (a sector nonlinearity).

Absolute stability problem edit

Consider:

1. (A,B) is controllable and (C,A) is observable
2. two real numbers a, b with a < b, defining a sector for function Φ

The Lur'e problem (also known as the absolute stability problem) is to derive conditions involving only the transfer matrix H(s) and {a,b} such that x = 0 is a globally uniformly asymptotically stable equilibrium of the system.

There are two well-known wrong conjectures on the absolute stability problem:

• The Aizerman's conjecture
• The Kalman's conjecture.

Graphically, these conjectures can be interpreted in terms of graphical restrictions on the graph of Φ(y) x y or also on the graph of dΦ/dy x Φ/y.^[2] There are counterexamples to Aizerman's and Kalman's conjectures such that nonlinearity belongs to the sector of linear stability and unique stable equilibrium coexists with a stable periodic solution—hidden oscillation.

There are two main theorems concerning the Lur'e problem which give sufficient conditions for absolute stability:

• The circle criterion (an extension of the Nyquist stability criterion for linear systems)
• The Popov criterion.

Frobenius theorem edit

The Frobenius theorem is a deep result in differential geometry. When applied to nonlinear control, it says the following: Given a system of the form

${\displaystyle {\dot {x}}=\sum _{i=1}^{k}f_{i}(x)u_{i}(t)\,}$ 

where ${\displaystyle x\in R^{n}}$ , ${\displaystyle f_{1},\dots ,f_{k}}$  are vector fields belonging to a distribution ${\displaystyle \Delta }$  and ${\displaystyle u_{i}(t)}$  are control functions, the integral curves of ${\displaystyle x}$  are restricted to a manifold of dimension ${\displaystyle m}$  if ${\displaystyle \operatorname {span} (\Delta )=m}$  and ${\displaystyle \Delta }$  is an involutive distribution.

• Feedback passivation
• Phase-locked loop
• Small control property

• Wolfram language functions for nonlinear control systems