https://murray.cds.caltech.edu/index.php?action=history&feed=atom&title=Exponential_Stabilization_of_Driftless_Nonlinear_Control_SystemsExponential Stabilization of Driftless Nonlinear Control Systems - Revision history2026-05-28T05:28:49ZRevision history for this page on the wikiMediaWiki 1.44.2https://murray.cds.caltech.edu/index.php?title=Exponential_Stabilization_of_Driftless_Nonlinear_Control_Systems&diff=20064&oldid=prevMurray: htdb2wiki: creating page for 1994_rtm94-phd.html2016-05-15T06:20:53Z<p>htdb2wiki: creating page for 1994_rtm94-phd.html</p>
<p><b>New page</b></p><div>{{HTDB paper<br />
| authors = Robert T. M'Closkey<br />
| title = Exponential Stabilization of Driftless Nonlinear Control Systems<br />
| source = PhD Dissertation, Caltech, Dec 1994<br />
| year = <br />
| type = CDS Technical Report<br />
| funding = AFOSR<br />
| url = http://www.cds.caltech.edu/~murray/preprints/rtm94-phd.pdf<br />
| abstract = <br />
This dissertation lays the foundation for practical exponential<br />
stabilization of driftless control systems. Driftless systems have<br />
the form $$\dot x = X_1(x)u_1+\cdots +X_m(x)u_m, \quad x\in\real^n$$.<br />
Such systems arise when modeling mechanical systems with nonholonomic<br />
constraints. In engineering applications it is often required to<br />
maintain the mechanical system around a desired configuration. This<br />
task is treated as a stabilization problem where the desired<br />
configuration is made an asymptotically stable equilibrium point. The<br />
control design is carried out on an approximate system. The<br />
approximation process yields a nilpotent set of input vector fields<br />
which, in a special coordinate system, are homogeneous with respect to<br />
a non-standard dilation. Even though the approximation can be given a<br />
coordinate-free interpretation, the homogeneous structure is useful to<br />
exploit: the feedbacks are required to be homogeneous functions and<br />
thus preserve the homogeneous structure in the closed-loop system.<br />
The stability achieved is called {\em $\rho$-exponential stability}.<br />
The closed-loop system is stable and the equilibrium point is<br />
exponentially attractive. This extended notion of exponential<br />
stability is required since the feedback, and hence the closed-loop<br />
system, is not Lipschitz. However, it is shown that the convergence<br />
rate of a Lipschitz closed-loop driftless system cannot be bounded by<br />
an exponential envelope.<br />
<p><br />
The synthesis methods generate feedbacks which are smooth on<br />
\rminus. The solutions of the closed-loop system are proven to be<br />
unique in this case. In addition, the control inputs for many<br />
driftless systems are velocities. For this class of systems it is<br />
more appropriate for the control law to specify actuator forces<br />
instead of velocities. We have extended the kinematic velocity<br />
controllers to controllers which command forces and still<br />
$\rho$-exponentially stabilize the system.<br />
<p><br />
Perhaps the ultimate justification of the methods proposed in this<br />
thesis are the experimental results. The experiments demonstrate the<br />
superior convergence performance of the $\rho$-exponential stabilizers<br />
versus traditional smooth feedbacks. The experiments also highlight<br />
the importance of transformation conditioning in the feedbacks. Other<br />
design issues, such as scaling the measured states to eliminate<br />
hunting, are discussed. The methods in this thesis bring the<br />
practical control of strongly nonlinear systems one step closer.<br />
<p><br />
<br />
| flags = NoRequest<br />
| tag = rtm94-phd<br />
| id = 1994<br />
}}</div>Murray