Structure-aware approximate compilation for Hamiltonian dynamics on NISQ devices produces shallower circuits with higher observed fidelity than generic exact synthesis.
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3 Pith papers cite this work. Polarity classification is still indexing.
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2026 3verdicts
UNVERDICTED 3representative citing papers
A geometric formalism yields tight quantum speed limits for quantum gates by mapping unitary evolution to minimal-length curves with curvature bounds.
Geometric complexity of physical maps is bounded below by execution error, forcing divergent resources for zero-error state resets in both classical and quantum settings.
citing papers explorer
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Hardware-Efficient Hamiltonian Simulation via Trotter-Initialized Variational Optimization with Native Placement
Structure-aware approximate compilation for Hamiltonian dynamics on NISQ devices produces shallower circuits with higher observed fidelity than generic exact synthesis.
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How fast can a quantum gate be? Exact speed limits from geometry
A geometric formalism yields tight quantum speed limits for quantum gates by mapping unitary evolution to minimal-length curves with curvature bounds.
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Geometric complexity in thermodynamics
Geometric complexity of physical maps is bounded below by execution error, forcing divergent resources for zero-error state resets in both classical and quantum settings.