MicroCloud Hologram studies quantum computing methods

The company said, “Regarding the optimization problem of variable selection and computation methods in quantum computing, they proposed a quantum computing method based on the universal “quantum variable” form. This method breaks the dependence of traditional quantum computing on quantum variables of specific dimensions and demonstrates strong flexibility. In this method, the “auxiliary” plays a key role, with its core function being to mediate gate operations on well-isolated “quantum memory” registers. The “quantum memory” registers here are the core units for storing and processing quantum information, while the auxiliary, through specific interactions, enables the control of gate operations on the registers without directly interfering with the core quantum state of the registers. More importantly, this method is not limited to a specific type of quantum variable; it is applicable to traditional qubits, high-dimensional qubits with dimension dgreater than2, or quantum continuous variable settings. This universality allows the quantum computing method to flexibly select the most suitable quantum variables based on different application scenarios and technical conditions, greatly expanding its range of applications. To enable this quantum computing method to achieve universal quantum computing stably and efficiently, HOLO further proposed a specific implementation model. In this model, the realization of universal quantum computing relies solely on three core elements: the repeated application of a single fixed two-body auxiliary-register interaction gate, auxiliaries prepared in a single state, and local measurements of these auxiliaries. First, the two-body auxiliary-register interaction gate serves as the foundation for implementing quantum operations. Through the repeated use of this gate, it is possible to construct various basic quantum gate operations required for universal quantum computing, avoiding the system complexity introduced by using multiple complex gate structures. Second, auxiliaries prepared in a single state ensure that each auxiliary participating in the computation has a consistent initial state, reducing computational errors caused by variations in the initial states of auxiliaries. Finally, local measurements of auxiliaries are a critical step in obtaining key information during the computation process and advancing the computation. Through local measurements, it is possible to regulate the computation process without destroying the quantum state of the register.”