{"title":"一个新的非随机异或引理的逆指数相关界和极刚性矩阵","authors":"Lijie Chen, Xin Lyu","doi":"10.1145/3406325.3451132","DOIUrl":null,"url":null,"abstract":"In this work we prove that there is a function f ∈ E NP such that, for every sufficiently large n and d = √n/logn, fn (f restricted to n-bit inputs) cannot be (1/2 + 2−d)-approximated by F2-polynomials of degree d. We also observe that a minor improvement (e.g., improving d to n1/2+ε for any ε > 0) over our result would imply E NP cannot be computed by depth-3 AC0-circuits of 2n1/2 + ε size, which is a notoriously hard open question in complexity theory. Using the same proof techniques, we are also able to construct extremely rigid matrices over F2 in P NP. More specifically, we show that for every constant ε ∈ (0,1), there is a P NP algorithm which on input 1n outputs an n× n F2-matrix Hn satisfying RHn(2log1 − ε n) ≥ (1/2 − exp(−log2/3 · ε n) ) · n2, for every sufficiently large n. This improves the recent P NP constructions of rigid matrices in [Alman and Chen, FOCS 2019] and [Bhangale et al., FOCS 2020], which only give Ω(n2) rigidity. The key ingredient in the proof of our new results is a new derandomized XOR lemma based on approximate linear sums, which roughly says that given an n-input function f which cannot be 0.99-approximated by certain linear sum of s many functions in F within ℓ1-distance, one can construct a new function Ampf with O(n) input bits, which cannot be (1/2+sΩ(1))-approximated by F-functions. Taking F to be a function collection containing low-degree F2-polynomials or low-rank F2-matrices, our results are then obtained by first using the algorithmic method to construct a function which is weakly hard against linear sums of F in the above sense, and then applying the derandomized XOR lemma to f. We obtain our new derandomized XOR lemma by giving a generalization of the famous hardcore lemma by Impagliazzo. Our generalization in some sense constructs a non-Boolean hardcore of a weakly hard function f with respect to F-functions, from the weak inapproximability of f by any linear sum of F with bounded ℓp-norm. This generalization recovers the original hardcore lemma by considering the ℓ∞-norm. Surprisingly, when we switch to the ℓ1-norm, we immediately rediscover Levin’s proof of Yao’s XOR Lemma. That is, these first two proofs of Yao’s XOR Lemma can be unified with our new perspective. For proving the correlation bounds, our new derandomized XOR lemma indeed works with the ℓ4/3-norm.","PeriodicalId":132752,"journal":{"name":"Proceedings of the 53rd Annual ACM SIGACT Symposium on Theory of Computing","volume":"305 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2021-06-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"5","resultStr":"{\"title\":\"Inverse-exponential correlation bounds and extremely rigid matrices from a new derandomized XOR lemma\",\"authors\":\"Lijie Chen, Xin Lyu\",\"doi\":\"10.1145/3406325.3451132\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"In this work we prove that there is a function f ∈ E NP such that, for every sufficiently large n and d = √n/logn, fn (f restricted to n-bit inputs) cannot be (1/2 + 2−d)-approximated by F2-polynomials of degree d. We also observe that a minor improvement (e.g., improving d to n1/2+ε for any ε > 0) over our result would imply E NP cannot be computed by depth-3 AC0-circuits of 2n1/2 + ε size, which is a notoriously hard open question in complexity theory. Using the same proof techniques, we are also able to construct extremely rigid matrices over F2 in P NP. More specifically, we show that for every constant ε ∈ (0,1), there is a P NP algorithm which on input 1n outputs an n× n F2-matrix Hn satisfying RHn(2log1 − ε n) ≥ (1/2 − exp(−log2/3 · ε n) ) · n2, for every sufficiently large n. This improves the recent P NP constructions of rigid matrices in [Alman and Chen, FOCS 2019] and [Bhangale et al., FOCS 2020], which only give Ω(n2) rigidity. The key ingredient in the proof of our new results is a new derandomized XOR lemma based on approximate linear sums, which roughly says that given an n-input function f which cannot be 0.99-approximated by certain linear sum of s many functions in F within ℓ1-distance, one can construct a new function Ampf with O(n) input bits, which cannot be (1/2+sΩ(1))-approximated by F-functions. Taking F to be a function collection containing low-degree F2-polynomials or low-rank F2-matrices, our results are then obtained by first using the algorithmic method to construct a function which is weakly hard against linear sums of F in the above sense, and then applying the derandomized XOR lemma to f. We obtain our new derandomized XOR lemma by giving a generalization of the famous hardcore lemma by Impagliazzo. Our generalization in some sense constructs a non-Boolean hardcore of a weakly hard function f with respect to F-functions, from the weak inapproximability of f by any linear sum of F with bounded ℓp-norm. This generalization recovers the original hardcore lemma by considering the ℓ∞-norm. Surprisingly, when we switch to the ℓ1-norm, we immediately rediscover Levin’s proof of Yao’s XOR Lemma. That is, these first two proofs of Yao’s XOR Lemma can be unified with our new perspective. 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引用次数: 5
摘要
在这个工作我们证明有一个函数f∈E NP,为每一个足够大的n和d =√n / logn fn (f限于n位输入)不能(1/2 + 2−d) F2-polynomials近似的程度。我们还观察到一个小改进(例如,改善d n +任何εε> 0)/我们的结果意味着E NP不能计算depth-3 AC0-circuits 2 n +ε的大小,这是一个难以复杂性理论中悬而未决的问题。使用相同的证明技术,我们也能够在pnp中构造F2上的极刚性矩阵。更具体地说,我们证明了对于每个常数ε∈(0,1),对于每个足够大的n,存在一个P NP算法,该算法在输入1n时输出一个n× n f2 -矩阵Hn,满足RHn(2log1−ε n)≥(1/2−exp(−log2/3·ε n))·n2。这改进了最近在[Alman and Chen, FOCS 2019]和[Bhangale et al., FOCS 2020]中刚性矩阵的P NP结构,它们只给出Ω(n2)刚性。证明我们的新结果的关键是一个新的基于近似线性和的非随机异或引理,它粗略地说,给定一个n输入函数f,它不能被f中s个函数在1-距离内的一定线性和近似为0.99,我们可以构造一个具有O(n)输入位的新函数Ampf,它不能被f函数近似为(1/2+sΩ(1))。取F为包含低次f2多项式或低秩f2矩阵的函数集合,首先用算法方法构造一个对上述意义上F的线性和弱硬的函数,然后将非随机化XOR引理应用于F,得到了我们的结果。我们通过推广Impagliazzo著名的硬引理得到了新的非随机化XOR引理。我们的推广在某种意义上构造了关于f函数的弱硬函数f的非布尔核,从f的弱不可逼近的任何有界的p模的f的线性和出发。这种推广通过考虑l∞范数恢复了原来的核心引理。令人惊讶的是,当我们切换到1-范数时,我们立即重新发现了Levin对Yao异或引理的证明。也就是说,姚的异或引理的前两个证明可以与我们的新视角统一起来。为了证明相关界,我们新的非随机化异或引理确实适用于4/3范数。
Inverse-exponential correlation bounds and extremely rigid matrices from a new derandomized XOR lemma
In this work we prove that there is a function f ∈ E NP such that, for every sufficiently large n and d = √n/logn, fn (f restricted to n-bit inputs) cannot be (1/2 + 2−d)-approximated by F2-polynomials of degree d. We also observe that a minor improvement (e.g., improving d to n1/2+ε for any ε > 0) over our result would imply E NP cannot be computed by depth-3 AC0-circuits of 2n1/2 + ε size, which is a notoriously hard open question in complexity theory. Using the same proof techniques, we are also able to construct extremely rigid matrices over F2 in P NP. More specifically, we show that for every constant ε ∈ (0,1), there is a P NP algorithm which on input 1n outputs an n× n F2-matrix Hn satisfying RHn(2log1 − ε n) ≥ (1/2 − exp(−log2/3 · ε n) ) · n2, for every sufficiently large n. This improves the recent P NP constructions of rigid matrices in [Alman and Chen, FOCS 2019] and [Bhangale et al., FOCS 2020], which only give Ω(n2) rigidity. The key ingredient in the proof of our new results is a new derandomized XOR lemma based on approximate linear sums, which roughly says that given an n-input function f which cannot be 0.99-approximated by certain linear sum of s many functions in F within ℓ1-distance, one can construct a new function Ampf with O(n) input bits, which cannot be (1/2+sΩ(1))-approximated by F-functions. Taking F to be a function collection containing low-degree F2-polynomials or low-rank F2-matrices, our results are then obtained by first using the algorithmic method to construct a function which is weakly hard against linear sums of F in the above sense, and then applying the derandomized XOR lemma to f. We obtain our new derandomized XOR lemma by giving a generalization of the famous hardcore lemma by Impagliazzo. Our generalization in some sense constructs a non-Boolean hardcore of a weakly hard function f with respect to F-functions, from the weak inapproximability of f by any linear sum of F with bounded ℓp-norm. This generalization recovers the original hardcore lemma by considering the ℓ∞-norm. Surprisingly, when we switch to the ℓ1-norm, we immediately rediscover Levin’s proof of Yao’s XOR Lemma. That is, these first two proofs of Yao’s XOR Lemma can be unified with our new perspective. For proving the correlation bounds, our new derandomized XOR lemma indeed works with the ℓ4/3-norm.
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