Despite the obvious discrepancies between the quantum mechanical and the classical regimes of computation, there has been an inexorable push to establish quantum computation as the dominant methodology for the future. The drive towards miniaturization coupled with the possibility of hitherto unfeasible parallelism overpowers the ugly circuit implementation aspects inherent at quantum scales. Though quantitatively indistinguishable from a classical Turing machine, Quantum computers do not function along with the same operating principles as their classical counterparts. Indeed, analogies to classical computations are limited by the fact that very few algorithms truly show ‘quantum supremacy’. Some of the most difficult aspects of quantum computations are the understanding and reinterpretation of classical terms such as computational power, memory, and intelligence in the quantum domain. One of the more elegant implementations of quantum computing and information relies heavily on optical approaches, at the forefront of which, due scalability and near room temperature operation, our techniques excel. These approaches primarily rely on light-matter interactions, typically at ultrashort timescales. Though not directly realizable, ultrashort times can also be connected to the ultra-small sizes. Spatiotemporal control aspects of pulsed laser experiments rely on the ability to modulate the shape of the generated pulses in an efficient manner. Drawing from current state-of-the-art theoretical aspects of computational simulations to reduce the sim-to-real bottlenecks, we devised a novel schematic for the generation of on-the-fly calibrated pulse trains with more accountability than existing techniques under the domain of optimal control theory. The techniques presented today further diminish the divide between experiment and theory.<\/p>\n","protected":false},"excerpt":{"rendered":"
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