The center-of-gravity method is a theoretic algorithm for convex optimization. It can be seen as a generalization of the bisection method from one-dimensional functions to multi-dimensional functions.[1]: Sec.8.2.2 It is theoretically important as it attains the optimal convergence rate. However, it has little practical value as each step is very computationally expensive.
Input
Our goal is to solve a convex optimization problem of the form:
minimize f(x) s.t. x in G,
where f is a convex function, and G is a convex subset of a Euclidean space Rn.
We assume that we have a "subgradient oracle": a routine that can compute a subgradient of f at any given point (if f is differentiable, then the only subgradient is the gradient ; but we do not assume that f is differentiable).
Method
The method is iterative. At each iteration t, we keep a convex region Gt, which surely contains the desired minimum. Initially we have G0 = G. Then, each iteration t proceeds as follows.
- Let xt be the center of gravity of Gt.
- Compute a subgradient at xt, denoted f'(xt).
- By definition of a subgradient, the graph of f is above the subgradient, so for all x in Gt: f(x)−f(xt) ≥ (x−xt)Tf'(xt).
- If f'(xt)=0, then the above implies that xt is an exact minimum point, so we terminate and return xt.
- Otherwise, let Gt+1 := {x in Gt: (x−xt)Tf'(xt) ≤ 0}.
Note that, by the above inequality, every minimum point of f must be in Gt+1.[1]: Sec.8.2.2
Convergence
It can be proved that
.
Therefore,
.
In other words, the method has linear convergence of the residual objective value, with convergence rate . To get an ε-approximation to the objective value, the number of required steps is at most .[1]: Sec.8.2.2
Computational complexity
The main problem with the method is that, in each step, we have to compute the center-of-gravity of a polytope. All the methods known so far for this problem require a number of arithmetic operations that is exponential in the dimension n.[1]: Sec.8.2.2 Therefore, the method is not useful in practice when there are 5 or more dimensions.
See also
The ellipsoid method can be seen as a tractable approximation to the center-of-gravity method. Instead of maintaining the feasible polytope Gt, it maintains an ellipsoid that contains it. Computing the center-of-gravity of an ellipsoid is much easier than of a general polytope, and hence the ellipsoid method can usually be computed in polynomial time.
References
- 1 2 3 4 Nemirovsky and Ben-Tal (2023). "Optimization III: Convex Optimization" (PDF).