SHENZHEN, China, Jan. 23,
2025 /PRNewswire/ -- MicroCloud Hologram Inc.
(NASDAQ: HOLO), ("HOLO" or the "Company"), a technology service
provider, have proposed a novel
theory of Wasserstein distance extended to quantum states,
which provides a fresh perspective and powerful tools for the
research and analysis of quantum states.
Wasserstein distance is a fundamental metric in classical
probability distributions, defined based on the minimization of
transport costs. It measures the minimal cost required to transform
one probability distribution into another. HOLO has innovatively
extended this concept to the domain of quantum states. In the
quantum world, the description and manipulation of quantum states
are far more complex than classical probability distributions, and
HOLO's approach is undoubtedly a significant innovation.
HOLO reveals a natural correspondence between the transport
plans of quantum states and quantum channels. This means that in
quantum systems, the transport process can be precisely interpreted
as a physical operation on the system. The discovery of this
correspondence provides a more intuitive and accurate understanding
of quantum information transmission and processing. In traditional
quantum research, the transmission of quantum information is often
viewed as an abstract process, but HOLO analyzes and grasps this
process from the perspective of physical operations, laying a
theoretical foundation for further optimization of applications
such as quantum communication and quantum computing.
HOLO's main research focuses on the proof of the modified
triangle inequality. In both mathematics and physics, the triangle
inequality is a fundamental relational inequality that plays a
crucial role in many theories and applications. For the Wasserstein
distance extended to quantum states, HOLO has derived and proven
the modified triangle inequality through rigorous theoretical
derivation. The validity of this inequality not only enriches the
theoretical framework of quantum state Wasserstein distance but
also has significant practical implications. For example, in the
design of quantum error-correcting codes, this modified triangle
inequality can be used to more accurately assess errors and
distortions in quantum information during transmission, thus
enabling the design of more efficient and reliable quantum error
correction schemes.
Additionally, HOLO has proven that the distance between a
quantum state and itself is closely related to the Wigner-Yanase
metric on the quantum state manifold. The quantum state manifold is
an important concept for describing the structure of quantum state
space, while the Wigner-Yanase metric is a key tool for
characterizing the geometric properties of the quantum state
manifold. HOLO's discovery reveals the intrinsic connection between
the Wasserstein distance of quantum states and the geometric
properties of the quantum state manifold. This connection provides
a new approach to studying quantum states from a geometric
perspective, aiding in a deeper understanding of the nature and
characteristics of quantum states. By exploring the relationship
between the distance of a quantum state to itself and the
Wigner-Yanase metric, it is possible to further investigate
important properties such as the stability and distinguishability
of quantum states, thus providing theoretical support for the
optimization of quantum information processing and quantum
computing.
At the same time, HOLO discovered that in the semi-classical
limit, the proposed quantum state Wasserstein distance recovers the
classical Wasserstein distance. This finding reveals the intrinsic
connection between the quantum state Wasserstein distance and the
classical Wasserstein distance, suggesting that under certain
conditions, the behavior of quantum states can transition to
classical states. This connection not only helps us understand
quantum phenomena from the perspective of classical physics but
also provides new insights into the integration of quantum theory
and classical theory. In practical applications, this
characteristic in the semi-classical limit can offer theoretical
support for the combination of quantum and classical technologies,
promoting the application and development of quantum technologies
in a broader range of fields.
HOLO's research on quantum state Wasserstein distance injects
new vitality into the development of quantum information science
and quantum physics. In the future, HOLO will continue to delve
deeper into this field, expanding and refining related theories,
and providing a more solid theoretical foundation for the practical
application of quantum technologies.
About MicroCloud Hologram Inc.
MicroCloud is committed to providing leading holographic
technology services to its customers worldwide. MicroCloud's
holographic technology services include high-precision holographic
light detection and ranging ("LiDAR") solutions, based on
holographic technology, exclusive holographic LiDAR point cloud
algorithms architecture design, breakthrough technical holographic
imaging solutions, holographic LiDAR sensor chip design and
holographic vehicle intelligent vision technology to service
customers that provide reliable holographic advanced driver
assistance systems ("ADAS"). MicroCloud also provides holographic
digital twin technology services for customers and has built a
proprietary holographic digital twin technology resource library.
MicroCloud's holographic digital twin technology resource library
captures shapes and objects in 3D holographic form by utilizing a
combination of MicroCloud's holographic digital twin software,
digital content, spatial data-driven data science, holographic
digital cloud algorithm, and holographic 3D capture technology. For
more information, please visit http://ir.mcholo.com/
Safe Harbor Statement
This press release contains forward-looking statements as
defined by the Private Securities Litigation Reform Act of 1995.
Forward-looking statements include statements concerning plans,
objectives, goals, strategies, future events or performance, and
underlying assumptions and other statements that are other than
statements of historical facts. When the Company uses words such as
"may," "will," "intend," "should," "believe," "expect,"
"anticipate," "project," "estimate," or similar expressions that do
not relate solely to historical matters, it is making
forward-looking statements. Forward-looking statements are not
guarantees of future performance and involve risks and
uncertainties that may cause the actual results to differ
materially from the Company's expectations discussed in the
forward-looking statements. These statements are subject to
uncertainties and risks including, but not limited to, the
following: the Company's goals and strategies; the Company's future
business development; product and service demand and acceptance;
changes in technology; economic conditions; reputation and brand;
the impact of competition and pricing; government regulations;
fluctuations in general economic; financial condition and results
of operations; the expected growth of the holographic industry and
business conditions in China and
the international markets the Company plans to serve and
assumptions underlying or related to any of the foregoing and other
risks contained in reports filed by the Company with the Securities
and Exchange Commission ("SEC"), including the Company's most
recently filed Annual Report on Form 10-K and current report on
Form 6-K and its subsequent filings. For these reasons, among
others, investors are cautioned not to place undue reliance upon
any forward-looking statements in this press release. Additional
factors are discussed in the Company's filings with the SEC, which
are available for review at www.sec.gov. The Company undertakes no
obligation to publicly revise these forward-looking statements to
reflect events or circumstances that arise after the date
hereof.
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SOURCE MicroCloud Hologram Inc.
