Teaching and compressing for low VC-dimension
Abstract
In this work we study the quantitative relation between VC-dimension and two other basic parameters related to learning and teaching. Namely, the quality of sample compression schemes and of teaching sets for classes of low VC-dimension. Let be a binary concept class of size and VC-dimension . Prior to this work, the best known upper bounds for both parameters were , while the best lower bounds are linear in . We present significantly better upper bounds on both as follows. Set . We show that there always exists a concept in with a teaching set (i.e. a list of -labeled examples uniquely identifying in ) of size . This problem was studied by Kuhlmann (1999). Our construction implies that the recursive teaching (RT) dimension of is at most as well. The RT-dimension was suggested by Zilles et al. and Doliwa et al. (2010). The same notion (under the name partial-ID width) was independently studied by Wigderson and Yehudayoff (2013). An upper bound on this parameter that depends only on is known just for the very simple case , and is open even for . We also make small progress towards this seemingly modest goal. We further construct sample compression schemes of size for , with additional information of bits. Roughly speaking, given any list of -labelled examples of arbitrary length, we can retain only labeled examples in a way that allows to recover the labels of all others examples in the list, using additional information bits. This problem was first suggested by Littlestone and Warmuth (1986).
Cite
@article{arxiv.1502.06187,
title = {Teaching and compressing for low VC-dimension},
author = {Shay Moran and Amir Shpilka and Avi Wigderson and Amir Yehudayoff},
journal= {arXiv preprint arXiv:1502.06187},
year = {2016}
}
Comments
The final version is due to be published in the collection of papers "A Journey through Discrete Mathematics. A Tribute to Jiri Matousek" edited by Martin Loebl, Jaroslav Nesetril and Robin Thomas, due to be published by Springer