BGV

In 2011, Brakerski, Gentry and Vaikuntanathan (BGV) published the paper ^[1] in which they introduce a new (leveled) fully homomorphic encryption (FHE) that improves performance and bases security on weaker assumptions than schemes from the previous generation.

A central conceptual contribution of this work is a new way of constructing leveled fully homomorphic encryption schemes (capable of evaluating arbitrary polynomial-size circuits), without Gentry’s bootstrapping procedure.

Until recently, the BGV scheme was considered to be the most efficient homomorphic encryption scheme when performing the same operations on multiple ciphertexts at once.

Modulus switching

@TODO

New noise management technique

@TODO

Leveled Fully Homomorphic Encryption

Most of the work done by the will focus on the construction of a leveled fully homomorphic scheme, in the sense that the parameters of the scheme depend (polynomially) on the depth of the circuits that the scheme is capable of evaluating.

Definition. We say that a family of homomorphic encryption schemes ${\displaystyle {\mathcal {E}}^{(L)}:L\in \mathbb {Z} ^{+}}$ is leveled fully homomorphic if, for all ${\displaystyle L\in \mathbb {Z} ^{+}}$, they all use the same decryption circuit, ${\displaystyle {\mathcal {E}}^{(L)}}$ compactly evaluates all circuits of depth at most ${\displaystyle L}$ (that use some specified complete set of gates), and the computational complexity of ${\displaystyle {\mathcal {E}}^{(L)}}$'s algorithms is polynomial (a fixed polynomial for all ${\displaystyle L}$) in the security parameter ${\displaystyle L}$, and the size of the circuit (in the case of the evaluation algorithm).

The construction: FHE without bootstrapping

The authors base the security of their scheme on the hardness of Ring-Learning with errors problems, a generalisation of the classical LWE problem.

Let ${\displaystyle \lambda }$ be a security parameter, representing ${\displaystyle 2^{\lambda }}$ security against known attacks.

Let ${\displaystyle R=\mathbb {Z} [X]/(x^{d}+1)}$ and ${\displaystyle d=d(\lambda )}$ a power of $2$.

Let ${\displaystyle q=q(\lambda )}$ be an odd modulus and ${\displaystyle \chi =\chi (\lambda )}$ a ``noise" distribution over ${\displaystyle R}$. Let ${\displaystyle N=N(\lambda )}$ be an additional parameter of the system which is larger than ${\displaystyle 3\cdot \log {q}}$.

Let us assume that the plaintext is ${\displaystyle R_{2}=R/2R}$.

References