Applications of Systems of Equations 417DEFINITION Autonomous System
An autonomous system of differential equations has the formdxdt = f(x , y)
(1)
dydt = g(x, y).
System (1) is call ed autonomous because the functions f and g depend
explicitly only on the dependent variables x and y and not upon the inde-
pendent variable t (which often represents time).In performing a qualitative analysis of an autonomous system of the form (1 ),
we are interested in answering the following questions:
"Are there any equilibrium points?" That is, "Are there any constant
solutions?"
"Is a particular equilibrium point stable or unstable?"
In chapter 7, we stated that if f, g , fx, fy, gx, and gy are continuous
functions of x and y in some rectangle R in the xy-plane and if (xo, Yo) E
R, then there is a unique solution to system (1) which satisfies the initial
conditions x(to) = xo, y(to) =Yo· Furthermore, the solution can be extended
in a unique manner until the boundary of R is reached. In the discussions
which follow, we will assume that f(x, y) and g(x, y) and their first partial
derivatives are all continuous functions in some rectangle R.
DEFINITIONS Phase-Plane, Trajectory, and
Phase-Plane Portrait
The xy-plane is called the phase-plane.A solution (x(t), y(t)) of (1) traces out a curve in the phase-plane. Thiscurve is called a trajectory or orbit.
A phase-plane portrait is a sketch of a few trajectories of (1) together
with arrows indicating the direction a particle will fl.ow along the trajectory
as t (time) increases.