TY - GEN
T1 - Communication Complexity of Inner Product in Symmetric Normed Spaces
AU - Andoni, Alexandr
AU - Błasiok, Jarosław
AU - Filtser, Arnold
N1 - Publisher Copyright:
© Alexandr Andoni, Jarosław Błasiok, and Arnold Filtser; licensed under Creative Commons License CC-BY 4.0.
PY - 2023/1/1
Y1 - 2023/1/1
N2 - We introduce and study the communication complexity of computing the inner product of two vectors, where the input is restricted w.r.t. a norm N on the space Rn. Here, Alice and Bob hold two vectors v, u such that ∥v∥N ≤ 1 and ∥u∥N∗ ≤ 1, where N∗ is the dual norm. The goal is to compute their inner product up to an ε additive term. The problem is denoted by IPN, and generalizes important previously studied problems, such as: (1) Computing the expectation Ex∼D[f(x)] when Alice holds D and Bob holds f is equivalent to IPℓ1. (2) Computing vTAv where Alice has a symmetric matrix with bounded operator norm (denoted S∞) and Bob has a vector v where ∥v∥2 = 1. This problem is complete for quantum communication complexity and is equivalent to IPS∞. We systematically study IPN, showing the following results, near tight in most cases: 1. For any symmetric norm N, given ∥v∥N ≤ 1 and ∥u∥N∗ ≤ 1 there is a randomized protocol using Õ(ε−6 log n) bits of communication that returns a value in ± ϵ with probability 23 -we will denote this by Rε1/3(IPN) ≤ Õ(ε−6 log n). In a special case where N = ℓp and N∗ = ℓq for p−1 + q−1 = 1, we obtain an improved bound Rε1/3(IPℓp) ≤ O(ε−2 log n), nearly matching the lower bound Rε1/3(IPℓp) ≥ Ω(min(n, ε−2)). 2. One way communication complexity −→Rε,δ(IPℓp) ≤ O(ε−max(2,p) · log nε ), and a nearly matching lower bound −→Rε1/3(IPℓp) ≥ Ω(ε−max(2,p)) for ε−max(2,p) ≪ n. 3. One way communication complexity −→Rε,δ(N) for a symmetric norm N is governed by the distortion of the embedding ℓk∞ into N. Specifically, while a small distortion embedding easily implies a lower bound Ω(k), we show that, conversely, non-existence of such an embedding implies protocol with communication kO(log log k) log2 n. 4. For arbitrary origin symmetric convex polytope P, we show Rε1/3(IPN) ≤ O(ε−2 log xc(P)), where N is the unique norm for which P is a unit ball, and xc(P) is the extension complexity of P (i.e. the smallest number of inequalities describing some polytope P′ s.t. P is projection of P′).
AB - We introduce and study the communication complexity of computing the inner product of two vectors, where the input is restricted w.r.t. a norm N on the space Rn. Here, Alice and Bob hold two vectors v, u such that ∥v∥N ≤ 1 and ∥u∥N∗ ≤ 1, where N∗ is the dual norm. The goal is to compute their inner product up to an ε additive term. The problem is denoted by IPN, and generalizes important previously studied problems, such as: (1) Computing the expectation Ex∼D[f(x)] when Alice holds D and Bob holds f is equivalent to IPℓ1. (2) Computing vTAv where Alice has a symmetric matrix with bounded operator norm (denoted S∞) and Bob has a vector v where ∥v∥2 = 1. This problem is complete for quantum communication complexity and is equivalent to IPS∞. We systematically study IPN, showing the following results, near tight in most cases: 1. For any symmetric norm N, given ∥v∥N ≤ 1 and ∥u∥N∗ ≤ 1 there is a randomized protocol using Õ(ε−6 log n) bits of communication that returns a value in ± ϵ with probability 23 -we will denote this by Rε1/3(IPN) ≤ Õ(ε−6 log n). In a special case where N = ℓp and N∗ = ℓq for p−1 + q−1 = 1, we obtain an improved bound Rε1/3(IPℓp) ≤ O(ε−2 log n), nearly matching the lower bound Rε1/3(IPℓp) ≥ Ω(min(n, ε−2)). 2. One way communication complexity −→Rε,δ(IPℓp) ≤ O(ε−max(2,p) · log nε ), and a nearly matching lower bound −→Rε1/3(IPℓp) ≥ Ω(ε−max(2,p)) for ε−max(2,p) ≪ n. 3. One way communication complexity −→Rε,δ(N) for a symmetric norm N is governed by the distortion of the embedding ℓk∞ into N. Specifically, while a small distortion embedding easily implies a lower bound Ω(k), we show that, conversely, non-existence of such an embedding implies protocol with communication kO(log log k) log2 n. 4. For arbitrary origin symmetric convex polytope P, we show Rε1/3(IPN) ≤ O(ε−2 log xc(P)), where N is the unique norm for which P is a unit ball, and xc(P) is the extension complexity of P (i.e. the smallest number of inequalities describing some polytope P′ s.t. P is projection of P′).
KW - communication complexity
KW - symmetric norms
UR - http://www.scopus.com/inward/record.url?scp=85147548436&partnerID=8YFLogxK
U2 - 10.4230/LIPIcs.ITCS.2023.4
DO - 10.4230/LIPIcs.ITCS.2023.4
M3 - Conference contribution
AN - SCOPUS:85147548436
T3 - Leibniz International Proceedings in Informatics, LIPIcs
BT - 14th Innovations in Theoretical Computer Science Conference, ITCS 2023
A2 - Kalai, Yael Tauman
PB - Schloss Dagstuhl- Leibniz-Zentrum fur Informatik GmbH, Dagstuhl Publishing
T2 - 14th Innovations in Theoretical Computer Science Conference, ITCS 2023
Y2 - 10 January 2023 through 13 January 2023
ER -