A Noise Resilient Transformation for Streaming Algorithms

In a streaming algorithm, Bob receives an input $x \in \{0,1\}^n$ via a stream and must compute a function $f$ in low space. However, this function may be fragile to errors in the input stream. In this work, we investigate what happens when the input stream is corrupted. Our main result is an encoding of the incoming stream so that Bob is still able to compute any such function $f$ in low space when a constant fraction of the stream is corrupted. More precisely, we describe an encoding function $\mathsf{enc}(x)$ of length $\text{poly}(n)$ so that for any streaming algorithm $A$ that on input $x$ computes $f(x)$ in space $s$, there is an explicit streaming algorithm $B$ that computes $f(x)$ in space $s \cdot \text{polylog}(n)$ as long as there were not more than $\frac14 - \varepsilon$ fraction of (adversarial) errors in the input stream $\mathsf{enc}(x)$.