We give one more proof of the first linear programming bound for binary codes, following the line of work initiated by Friedman and Tillich. The new argument is somewhat similar to previous proofs, but we believe it to be both simpler and more intuitive. Moreover, it provides the following 'geometric' explanation for the bound. A binary code with minimal distance $\delta n$ is small because the projections of the characteristic functions of its elements on the subspace spanned by the Walsh-Fourier characters of weight up to $\left(\frac 12 - \sqrt{\delta(1-\delta)}\right) \cdot n$ are essentially independent. Hence the cardinality of the code is bounded by the dimension of the subspace. We present two conjectures, suggested by the new proof, one for linear and one for general binary codes which, if true, would lead to an improvement of the first linear programming bound. The conjecture for linear codes is related to and is influenced by conjectures of H\r{a}stad and of Kalai and Linial. We verify the conjectures for the (simple) cases of random linear codes and general random codes.
翻译:我们根据Friedman 和 Tillich 启动的工作线,对第一个线性编程进行二进制代码约束的第一个线性编程,我们给出了另一个证据。新的论据与以前的证据有些相似,但我们认为它既简单又直观。此外,它为约束提供了以下的“几何”解释。一个最小距离的二进制代码很小,因为对其元素在以沃尔什-福里尔字符为单位的子空间上的特性功能的预测,其重量最高为$left(\frac 12 -\ sqrt69delta(1-delta)\\\cdolta)\\\cdolt n$基本上是独立的。因此,该代码的基点受子空间的维度的约束。我们根据新证据提出了两个假设,一个是线性代码,一个是普通的二进制代码,如果是真实的话,将导致对第一个线性编程约束的改进。线性代码的猜想与H\r} 和Kalai 和 Lina 通性总代码的配置有关并受其影响。