The progress made so far beyond the state-of-the-art results in the literature, as part of the current ERC project, can be summarized as follows:
Space bounded derandomization. In a joint work with my co authors, we obtained the first polynomial improvement over the seminal Saks-Zhou algorithm in nearly 30 years. The result has been obtained concurrently and independently by researchers from Harvard and MIT, based on an earlier manuscript we have published. This work will appear in STOC 2023.
Locally correctable codes. In a joint work with my PhD student Tal Yankovitz, that appeared in FOCS 2022, we significantly improved upon the state-of-the-art relaxed locally correctable codes by introducing an alternative to tensoring, which is one of the most prevailing techniques in the field.
Tree codes. In a STOC 2022 paper, joint with two students of mine, we improved upon the previous best construction of tree codes. We obtained the state-of-the-art tree code constructions both in terms of the number of colors, improving upon an earlier result from STOC 2018, and in terms of the distance, improving exponentially upon a result from SODA 2016.
Much of this progress ended up being based on techniques that are not directly related to randomness extractors. For the results we obtained in space bounded derandomization, spectral methods were used. This motivated us to initiate the study of problems in spectral graph theory, resulting in a sequence of papers (STOC 2021, ICALP 2022, STOC 2023). For our result on tree codes, we used a somewhat involved combinatorial approach. Finally, for our results on locally correctable codes, we used certain pseudorandom objects that are tailor-made for the task rather than extractors which we understood to be pseudorandom objects that are too general for the task at hand.
Looking forward, we expect to continue and develop the spectral methods used for space bounded derandomization, with the goal of improving the Saks-Zhou algorithm. Moreover, we consider using spectral methods for the construction of randomness extractors in novel ways. The technique we used, bypassing the limitations of tensoring, or variant thereof may be used in many of the other applications of tensoring, and we attempt to understand its potential. Lastly, the sequence of works we initiated on spectral methods took on a life of its own, and we wish to further investigate its potential with an eye towards the goals of this ERC project.