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Improved Lower Bounds for 3-Query Matching Vector Codes

Authors Divesh Aggarwal , Pranjal Dutta , Zeyong Li , Maciej Obremski , Sidhant Saraogi

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ACM Subject Classification
  • Theory of computation → Error-correcting codes
Keywords
  • Locally Decodable Codes
  • Matching Vector Families

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Abstract

A Matching Vector (MV) family modulo a positive integer m ≥ 2 is a pair of ordered lists U = (u_1, ⋯, u_K) and V = (v_1, ⋯, v_K) where u_i, v_j ∈ ℤ_m^n with the following property: for any i ∈ [K], the inner product ⟨u_i, v_i⟩ = 0 mod m, and for any i ≠ j, ⟨u_i, v_j⟩ ≠ 0 mod m. An MV family is called r-restricted if inner products ⟨u_i, v_j⟩, for all i,j, take at most r different values. The r-restricted MV families are extremely important since the only known construction of constant-query subexponential locally decodable codes (LDCs) are based on them. Such LDCs constructed via matching vector families are called matching vector codes. Let MV(m,n) (respectively MV(m, n, r)) denote the largest K such that there exists an MV family (respectively r-restricted MV family) of size K in ℤ_m^n. Such a MV family can be transformed in a black-box manner to a good r-query locally decodable code taking messages of length K to codewords of length N = m^n. 
For small prime m, an almost tight bound MV(m,n) ≤ O(m^{n/2}) was first shown by Dvir, Gopalan, Yekhanin (FOCS'10, SICOMP'11), while for general m, the same paper established an upper bound of O(m^{n-1+o_m(1)}), with o_m(1) denoting a function that goes to zero when m grows. For any arbitrary constant r ≥ 3 and composite m, the best upper bound till date on MV(m,n,r) is O(m^{n/2}), is due to Bhowmick, Dvir and Lovett (STOC'13, SICOMP'14).In a breakthrough work, Alrabiah, Guruswami, Kothari and Manohar (STOC'23) implicitly improve this bound for 3-restricted families to MV(m, n, 3) ≤ O(m^{n/3}). 
In this work, we present an upper bound for r = 3 where MV(m,n,3) ≤ m^{n/6 +O(log n)}, and as a result, any 3-query matching vector code must have codeword length of N ≥ K^{6-o(1)}.

Cite As Get BibTex

Divesh Aggarwal, Pranjal Dutta, Zeyong Li, Maciej Obremski, and Sidhant Saraogi. Improved Lower Bounds for 3-Query Matching Vector Codes. In 16th Innovations in Theoretical Computer Science Conference (ITCS 2025). Leibniz International Proceedings in Informatics (LIPIcs), Volume 325, pp. 2:1-2:19, Schloss Dagstuhl – Leibniz-Zentrum für Informatik (2025) https://doi.org/10.4230/LIPIcs.ITCS.2025.2

Author Details

Divesh Aggarwal
  • Centre for Quantum Technologies, National University of Singapore, Singapore
Pranjal Dutta
  • National University of Singapore, Singapore
Zeyong Li
  • Centre for Quantum Technologies, National University of Singapore, Singapore
Maciej Obremski
  • National University of Singapore, Singapore
Sidhant Saraogi
  • Georgetown University, Washington, DC, USA

Funding

  • Aggarwal, Divesh: Funded by the bridging grant at Centre for Quantum Technologies titled "Quantum algorithms, complexity, and communication".
  • Dutta, Pranjal: Funded by NRF Singapore under the project "Computational Hardness of Lattice Problems and Implications" [NRF-NRFI09-0005].
  • Li, Zeyong: Funded by NRF Singapore under the project "Computational Hardness of Lattice Problems and Implications" [NRF-NRFI09-0005].
  • Obremski, Maciej: Funded by MOE tier 2 grant T2EP20223-0024, Breaking the Box - On Security of Cryptographic Devices.
  • Saraogi, Sidhant: Funded in part by the National Science Foundation CAREER award to Justin Thaler (grant CCF-1845125).

Acknowledgements

The authors would like to thank Sivakanth Gopi and Anup Rao for sharing a proof of Theorem 21. They would also like to thanks anonymous reviewers for their helpful comments.

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