MicroCloud Hologram Inc.（纳斯达克股票代码：HOLO）宣布利用数字模拟量子计算（DAQC）范式在量子计算领域取得突破

MicroCloud Hologram Inc.（纳斯达克股票代码：HOLO）宣布推出新的数字模拟量子计算（DAQC）范例，在量子计算领域取得重大突破。

MicroCloud Hologram Inc. (NASDAQ: HOLO) announced a major breakthrough in quantum computing with the launch of its Digital Simulated Quantum Computing (DAQC) paradigm. This innovative approach blends the flexibility of digital quantum computing with the robustness of simulated quantum simulations, opening new avenues for advancing quantum computing technology.

MicroCloud Hologram Inc.（纳斯达克股票代码：HOLO）宣布推出数字模拟量子计算（DAQC）范例，在量子计算领域取得重大突破。这种创新方法将数字量子计算的灵活性与模拟量子模拟的稳健性相结合，为推进量子计算技术开辟了新途径。

A key area of focus for HOLO’s DAQC is the Quantum Fourier Transform (QFT), a fundamental subroutine used in a variety of quantum algorithms. The company has developed a highly efficient digital simulated quantum algorithm specifically aimed at improving the computational efficiency and accuracy of the QFT. This advancement plays a crucial role in enhancing the broader quantum algorithm framework.

HOLO DAQC 关注的一个关键领域是量子傅里叶变换 (QFT)，这是各种量子算法中使用的基本子程序。该公司开发了一种高效的数字模拟量子算法，专门旨在提高 QFT 的计算效率和准确性。这一进步在增强更广泛的量子算法框架方面发挥着至关重要的作用。

Through detailed research, HOLO discovered that as the number of quantum bits (qubits) increases, the fidelity of the Quantum Fourier Transform performed using DAQC improves significantly, especially when incorporating reasonable noise models. This finding highlights the potential of DAQC to overcome limitations faced by traditional quantum algorithms, particularly in the noisy intermediate-scale quantum (NISQ) era.

通过详细研究，HOLO 发现，随着量子比特（qubit）数量的增加，使用 DAQC 执行的量子傅里叶变换的保真度显着提高，尤其是在结合合理的噪声模型时。这一发现凸显了 DAQC 克服传统量子算法所面临的限制的潜力，特别是在嘈杂的中尺度量子 (NISQ) 时代。

To implement DAQC, HOLO utilized the homogeneous all-to-all (ATA) two-body Ising model as the foundational resource, further enhancing it with a non-homogeneous ATA two-body Ising model for greater accuracy. This approach laid the groundwork for efficient algorithm implementation.

为了实现 DAQC，HOLO 利用同质全对全 (ATA) 二体 Ising 模型作为基础资源，并使用非同质 ATA 二体 Ising 模型进一步增强它，以提高准确性。这种方法为高效算法实现奠定了基础。

HOLO’s extensive numerical simulation experiments were conducted on quantum devices with 3, 5, 6, and 7 qubits. The experiments incorporated a realistic noise model to replicate real-world quantum computing environments. Notably, the DAQC method outperformed purely digital methods in terms of the fidelity between the ideal transformation and the achieved transformation, demonstrating a significant improvement as the number of qubits increased.

HOLO 广泛的数值模拟实验是在具有 3、5、6 和 7 个量子位的量子器件上进行的。这些实验结合了现实的噪声模型来复制现实世界的量子计算环境。值得注意的是，就理想变换和实现变换之间的保真度而言，DAQC 方法优于纯数字方法，随着量子位数量的增加，DAQC 方法表现出显着的改进。

One of the key challenges in the current NISQ era is the noise introduced by quantum computing devices, especially errors generated by entangling two-qubit gates. HOLO’s DAQC paradigm successfully mitigates these errors, offering a significant advantage over existing technologies. This achievement suggests that hybrid protocols combining digital and simulated quantum computing could be a highly effective path toward “useful quantum supremacy” — the ability to solve real-world problems using quantum computers.

当前 NISQ 时代的关键挑战之一是量子计算设备引入的噪声，特别是由两个量子位门纠缠产生的错误。 HOLO 的 DAQC 范例成功地减少了这些错误，与现有技术相比具有显着的优势。这一成就表明，结合数字和模拟量子计算的混合协议可能是实现“有用的量子霸权”（使用量子计算机解决现实世界问题的能力）的高效途径。

Looking ahead, HOLO remains committed to further exploring and optimizing the DAQC paradigm. The company is focused on advancing quantum computing technology, with the goal of contributing to global progress and collaborating with partners across various sectors to shape the future of quantum computing.

展望未来，HOLO仍致力于进一步探索和优化DAQC范式。该公司专注于推进量子计算技术，目标是为全球进步做出贡献，并与各行业的合作伙伴合作，塑造量子计算的未来。

With this groundbreaking achievement, MicroCloud Hologram Inc. is positioned as a key player in the development of quantum computing, setting the stage for significant advancements in the field.

凭借这一突破性成就，MicroCloud Hologram Inc. 被定位为量子计算发展的关键参与者，为该领域的重大进步奠定了基础。