Improved Frequency Estimation Algorithms with and without Predictions
This work addresses frequency estimation for large-scale data analysis, offering incremental improvements over existing sketching algorithms.
The paper tackles the problem of estimating element frequencies in data streams by introducing a novel algorithm that theoretically outperforms a prior learning-based method in some regimes without predictions, and further reduces error when augmented with predictions, achieving superior empirical performance.
Estimating frequencies of elements appearing in a data stream is a key task in large-scale data analysis. Popular sketching approaches to this problem (e.g., CountMin and CountSketch) come with worst-case guarantees that probabilistically bound the error of the estimated frequencies for any possible input. The work of Hsu et al. (2019) introduced the idea of using machine learning to tailor sketching algorithms to the specific data distribution they are being run on. In particular, their learning-augmented frequency estimation algorithm uses a learned heavy-hitter oracle which predicts which elements will appear many times in the stream. We give a novel algorithm, which in some parameter regimes, already theoretically outperforms the learning based algorithm of Hsu et al. without the use of any predictions. Augmenting our algorithm with heavy-hitter predictions further reduces the error and improves upon the state of the art. Empirically, our algorithms achieve superior performance in all experiments compared to prior approaches.