1 research outputs found
Cost-optimal single-qubit gate synthesis in the Clifford hierarchy
For universal quantum computation, a major challenge to overcome for
practical implementation is the large amount of resources required for
fault-tolerant quantum information processing. An important aspect is
implementing arbitrary unitary operators built from logical gates within the
quantum error correction code. A synthesis algorithm can be used to approximate
any unitary gate up to arbitrary precision by assembling sequences of logical
gates chosen from a small set of universal gates that are fault-tolerantly
performable while encoded in a quantum error-correction code. However, current
procedures do not yet support individual assignment of base gate costs and many
do not support extended sets of universal base gates. We analysed cost-optimal
sequences using an exhaustive search based on Dijkstra's pathfinding algorithm
for the canonical Clifford+ set of base gates and compared them to when
additionally including -rotations from higher orders of the Clifford
hierarchy. Two approaches of assigning base gate costs were used. First, costs
were reduced to -counts by recursively applying a -rotation catalyst
circuit. Second, costs were assigned as the average numbers of raw (i.e.
physical level) magic states required to directly distil and implement the
gates fault-tolerantly. We found that the average sequence cost decreases by up
to when using the -rotation catalyst circuit approach and by up
to when using the magic state distillation approach. In addition,
we investigated observed limitations of certain assignments of base gate costs
by developing an analytic model to estimate the proportion of sets of
-rotation gates from higher orders of the Clifford hierarchy that are found
within sequences approximating random target gates.Comment: 19 pages, 7 figure