LIMDD A Decision Diagram for Simulation of Quantum Computing Including Stabilizer States

Efficient methods for the representation of relevant quantum states and quantum operations are crucial for the simulation and optimization of quantum circuits. Decision diagrams (DDs), a well-studied data structure originally used to represent Boolean functions, have proven capable of capturing interesting aspects of quantum systems, but their limits are not well understood. In this work, we investigate and bridge the gap between existing DD-based structures and the stabilizer formalism, a well-studied method for simulating quantum circuits in the tractable regime. We first show that although DDs were suggested to succinctly represent important quantum states, they actually require exponential space for a subset of stabilizer states. To remedy this, we introduce a more powerful decision diagram variant, called Local Invertible Map-DD (LIMDD). We prove that the set of quantum states represented by poly-sized LIMDDs strictly contains the union of stabilizer states and other decision diagram variants. We also provide evidence that LIMDD-based simulation is capable of efficiently simulating some circuits for which both stabilizer-based and other DD-based methods require exponential time. By uniting two successful approaches, LIMDDs thus pave the way for fundamentally more powerful solutions for simulation and analysis of quantum computing.