ECCC-Report TR10-066https://eccc.weizmann.ac.il/report/2010/066Comments and Revisions published for TR10-066en-usMon, 13 Dec 2010 16:43:36 +0200
Revision 1
| New Algorithms for Learning in Presence of Errors |
Sanjeev Arora,
Rong Ge
https://eccc.weizmann.ac.il/report/2010/066#revision1We give new algorithms for a variety of randomly-generated instances of computational problems using a linearization technique that reduces to solving a system of linear equations.
These algorithms are derived in the context of learning with structured noise, a notion introduced in this paper. This notion is best illustrated with the learning parities with noise (LPN) problem ---well-studied in learning theory and cryptography. In the standard version, we have access to an oracle that, each time we press a button, returns a random vector $ a \in GF(2)^n$ together with a bit $b \in GF(2)$ that was computed as
$a\cdot u +\eta$, where $u\in GF(2)^n$ is a secret vector, and $\eta \in GF(2)$ is a noise bit that is $1$ with some probability $p$. Say $p=1/3$. The goal is to recover $u$. This task is conjectured to be intractable.
In the structured noise setting we introduce a slight (?) variation of the model: upon pressing a button, we receive (say) $10$ random vectors
$a_1, a_2, \ldots, a_{10} \in GF(2)^n$, and corresponding bits $b_1, b_2, \ldots, b_{10}$, of which at most $3$ are noisy. The oracle may arbitrarily decide which of the $10$ bits to make noisy. We exhibit a polynomial-time algorithm to recover the secret vector $u$ given such an oracle. We think this structured noise model may be of independent interest in machine learning.
We discuss generalizations of our result, including learning with more general noise patterns. We also give the first nontrivial algorithms
for two problems, which we show fit in our structured noise framework.
We give a slightly subexponential algorithm for the well-known learning with errors (LWE) problem over $GF(q)$ introduced by Regev for cryptographic uses. Our algorithm works for the case when the gaussian noise is small; which was an open problem.
We also give polynomial-time algorithms for learning the MAJORITY OF PARITIES function of Applebaum et al. for certain parameter
values. This function is a special case of Goldreich's pseudorandom generator.Mon, 13 Dec 2010 16:43:36 +0200https://eccc.weizmann.ac.il/report/2010/066#revision1
Paper TR10-066
| Learning Parities with Structured Noise |
Sanjeev Arora,
Rong Ge
https://eccc.weizmann.ac.il/report/2010/066In the {\em learning parities with noise} problem ---well-studied in learning theory and cryptography--- we
have access to an oracle that, each time we press a button,
returns a random vector $ a \in \GF(2)^n$ together with a bit $b \in \GF(2)$ that was computed as
$a\cdot u +\eta$, where $u\in \GF(2)^n$ is a {\em secret} vector, and $\eta \in \GF(2)$ is a {\em noise} bit
that is $1$ with some probability $p$. Say $p=1/3$. The goal is to recover $u$. This task is
conjectured to be intractable.
Here we introduce a slight (?) variation of the model: upon pressing a button, we receive (say) $10$ random vectors
$a_1, a_2, \ldots, a_{10} \in \GF(2)^n$, and corresponding bits $b_1, b_2, \ldots, b_{10}$, of which at most $3$ are
noisy. The oracle may arbitrarily decide which of the $10$ bits to make noisy.
We exhibit a polynomial-time algorithm to recover the secret vector $u$ given such an oracle.
We discuss generalizations of our result, including learning with more general noise patterns.
We can also learn
low-depth decision trees in the above structured noise model. We also consider the {\em learning with errors} problem
over $\GF(q)$ and give (a) a $2^{\tilde{O}(\sqrt{n})}$ algorithm in our structured noise setting (b) a slightly subexponential algorithm when the gaussian noise is small.Wed, 14 Apr 2010 02:21:53 +0300https://eccc.weizmann.ac.il/report/2010/066