arXiv:2510.15340v2 Announce Type: replace-cross Abstract: State preparation is a cornerstone of quantum technologies, underpinning applications in computation, communication, and sensing. Its importance becomes even more pronounced in non-Markovian open quantum systems, where environmental memory and model uncertainties pose significant challenges to achieving high-fidelity control. Invariant-based inverse engineering provides a principled framework for synthesizing analytic control fields, yet existing parameterizations often lead to experimentally infeasible, singular pulses and are limited
The continuous advancements in quantum computing research necessitate more robust and practical control mechanisms, which this paper addresses by improving state preparation techniques.
Improved quantum control, particularly a singularity-free approach, is critical for making quantum technologies more reliable and experimentally feasible, accelerating their development and adoption.
The development of singularity-free invariant-based inverse engineering could lead to more stable and efficient control pulses for quantum systems, reducing experimental hurdles in quantum state preparation.
- · Quantum computing researchers
- · Quantum hardware developers
- · Quantum technology companies
- · Labs reliant on highly complex, singular pulse generation methods
More reliable and less error-prone quantum state preparation will become achievable.
This reliability will accelerate the development of practical quantum computers and sensors.
The widespread adoption of quantum technologies could disrupt industries relying on classical computation for complex tasks.
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Read at arXiv cs.LG