Mirror descent: Difference between revisions

In mathematics, mirror descent is an iterative optimization algorithm for finding a local minimum of a differentiable function.

It generalizes algorithms such as gradient descent and multiplicative weights.

Mirror descent was originally proposed by Nemirovski and Yudin in 1983.^[1]

In gradient descent with the sequence of learning rates ${\displaystyle ({\eta }_n{)}_{n\ge 0}}$ applied to a differentiable function ${\displaystyle F}$, one starts with a guess ${\displaystyle {𝐱}_0}$ for a local minimum of ${\displaystyle F,}$ and considers the sequence ${\displaystyle {𝐱}_0,{𝐱}_1,{𝐱}_2,\dots }$ such that

${\displaystyle {𝐱}_{n+1}={𝐱}_n-{\eta }_n\mathrm{\nabla }F({𝐱}_n),n\ge 0.}$

This can be reformulated by noting that

${\displaystyle {𝐱}_{n+1}=\arg \underset{𝐱}{\min }(F({𝐱}_n)+\mathrm{\nabla }F({𝐱}_n{)}^T(𝐱-{𝐱}_n)+\frac{1}{2{\eta }_n}\Vert 𝐱-{𝐱}_n{\Vert }^2)}$

In other words, ${\displaystyle {𝐱}_{n+1}}$ minimizes the first-order approximation to ${\displaystyle F}$ at ${\displaystyle {𝐱}_n}$ with added proximity term ${\displaystyle \Vert 𝐱-{𝐱}_n{\Vert }^2}$.

This squared Euclidean distance term is a particular example of a Bregman distance. Using other Bregman distances will yield other algorithms such as Hedge which may be more suited to optimization over particular geometries.^[2][3]

We are given convex function ${\displaystyle f}$ to optimize over a convex set ${\displaystyle K\subset {ℝ}^n}$, and given some norm ${\displaystyle \Vert \cdot \Vert }$ on ${\displaystyle {ℝ}^n}$.

We are also given differentiable convex function ${\displaystyle h:{ℝ}^n\to ℝ}$, ${\displaystyle \alpha }$-strongly convex with respect to the given norm. This is called the distance-generating function, and its gradient ${\displaystyle \mathrm{\nabla }h:{ℝ}^n\to {ℝ}^n}$ is known as the mirror map.

Starting from initial ${\displaystyle x_0\in K}$, in each iteration of Mirror Descent:

• Map to the dual space: ${\displaystyle {\theta }_t\leftarrow \mathrm{\nabla }h(x_t)}$
• Update in the dual space using a gradient step: ${\displaystyle {\theta }_{t+1}\leftarrow {\theta }_t-{\eta }_t\mathrm{\nabla }f(x_t)}$
• Map back to the primal space: ${\displaystyle x{\text{'}}_{t+1}\leftarrow (\mathrm{\nabla }h{)}^{-1}({\theta }_{t+1})}$
• Project back to the feasible region ${\displaystyle K}$: ${\displaystyle x_{t+1}\leftarrow \mathrm{a}\mathrm{r}\mathrm{g}\underset{x\in K}{\min }{D}_h(x||x{\text{'}}_{t+1})}$, where ${\displaystyle D_h}$ is the Bregman divergence.

Mirror descent in the online optimization setting is known as Online Mirror Descent (OMD).^[4]

• Gradient descent
• Multiplicative weight update method
• Hedge algorithm
• Bregman divergence

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