Abstract
In this work, we present a generalization of the recently proposed quantum Tanner codes by Leverrier and Zémor, which contains a construction of asymptotically good quantum low-density parity-check codes. Quantum Tanner codes have so far been constructed equivalently from groups, Cayley graphs, or square complexes constructed from groups. We show how to enlarge this to group actions on finite sets, Schreier graphs, and a family of square complexes, which is the largest possible in a certain sense. We show that the proposed generalization contains a family of asymptotically good quantum codes that are based on non-Cayley Schreier graphs, i.e., a new family of (generalized) quantum Tanner codes is provided. Moreover, we evaluate the performance of the generalized codes and compare with those based on Cayley graphs both in terms of minimum distance and logical error rate on the depolarizing channel, demonstrating that the proposed generalized codes based on Schreier graphs outperform those based on Cayley graphs.