Neural Information Processing Systems http://nips.cc/

Neural Information Processing Systems http://nips.cc/

The COVID-19 pandemic has led to more and more businesses implementing digital transformation to revolutionize their customer communication systems and augment internal processes. Artificial Intelligence (AI) is playing a fundamental role in 2021 as it is being adopted by large-scale as well as small businesses and enterprises. Many businesses across industries are planning to adopt or have already adopted a digital-first business strategy for growth and scale. With the implementation of any new technology, it takes a while for businesses to truly accrue its benefits. With Robotic Process Automation (RPA), software users develop software robots, or "bots", that can learn, imitate, and then execute algorithm-based business processes thereby creating a systematic structure and reducing errors.

We study the decades-old problem of online portfolio management and propose the first algorithm with logarithmic regret that is not based on Cover's Universal Portfolio algorithm and admits much faster implementation. Specifically Universal Portfolio enjoys optimal regret $\mathcal{O}(N\ln T)$ for $N$ financial instruments over $T$ rounds, but requires log-concave sampling and has a large polynomial running time. Our algorithm, on the other hand, ensures a slightly larger but still logarithmic regret of $\mathcal{O}(N^2(\ln T)^4)$, and is based on the well-studied Online Mirror Descent framework with a novel regularizer that can be implemented via standard optimization methods in time $\mathcal{O}(TN^{2.5})$ per round. The regret of all other existing works is either polynomial in $T$ or has a potentially unbounded factor such as the inverse of the smallest price relative.

We study the decades-old problem of online portfolio management and propose the first algorithm with logarithmic regret that is not based on Cover's Universal Portfolio algorithm and admits much faster implementation. Specifically Universal Portfolio enjoys optimal regret $\mathcal{O}(N\ln T)$ for $N$ financial instruments over $T$ rounds, but requires log-concave sampling and has a large polynomial running time. Our algorithm, on the other hand, ensures a slightly larger but still logarithmic regret of $\mathcal{O}(N^2(\ln T)^4)$, and is based on the well-studied Online Mirror Descent framework with a novel regularizer that can be implemented via standard optimization methods in time $\mathcal{O}(TN^{2.5})$ per round. The regret of all other existing works is either polynomial in $T$ or has a potentially unbounded factor such as the inverse of the smallest price relative.