WiMi Researches Quantum Linear Solvers, A Resource-Efficient Quantum Algorithm for Linear Systems of Equations
WiMi Hologram Cloud (NASDAQ: WIMI) announced the development of the Holographic Quantum Linear Solver (HQLS), a new quantum algorithm for solving linear systems of equations. The HQLS combines Variational Quantum Algorithms (VQA) with the classical shadow framework to overcome hardware resource limitations of traditional quantum solvers.
The algorithm reduces quantum bit requirements and gate complexity compared to traditional methods like the HHL algorithm, making it more suitable for current noisy intermediate-scale quantum (NISQ) computers. HQLS operates through a process of initialization, parameterized quantum circuit design, iterative optimization, shadow framework approximation, and convergence checking.
The technology shows promise for applications in climate modeling, quantum chemistry, machine learning, and financial modeling, with potential for integration with other quantum algorithms for complex problem-solving.
WiMi Hologram Cloud (NASDAQ: WIMI) ha annunciato lo sviluppo del Holographic Quantum Linear Solver (HQLS), un nuovo algoritmo quantistico per risolvere sistemi lineari di equazioni. L'HQLS combina Algoritmi Quantistici Variazionali (VQA) con il framework classico dello shadow per superare le limitazioni delle risorse hardware dei risolutori quantistici tradizionali.
L'algoritmo riduce i requisiti di qubit quantistici e la complessit脿 dei gate rispetto ai metodi tradizionali come l'algoritmo HHL, rendendolo pi霉 adatto per i computer quantistici attuali a scala intermedia rumorosa (NISQ). L'HQLS funziona attraverso un processo di inizializzazione, progettazione di circuiti quantistici parametrizzati, ottimizzazione iterativa, approssimazione del framework shadow e verifica della convergenza.
La tecnologia mostra promettenti applicazioni nella modellizzazione climatica, chimica quantistica, apprendimento automatico e modellizzazione finanziaria, con potenziale integrazione con altri algoritmi quantistici per la risoluzione di problemi complessi.
WiMi Hologram Cloud (NASDAQ: WIMI) anunci贸 el desarrollo del Holographic Quantum Linear Solver (HQLS), un nuevo algoritmo cu谩ntico para resolver sistemas lineales de ecuaciones. El HQLS combina Algoritmos Cu谩nticos Variacionales (VQA) con el marco cl谩sico de shadow para superar las limitaciones de recursos de hardware de los solucionadores cu谩nticos tradicionales.
El algoritmo reduce los requisitos de qubits cu谩nticos y la complejidad de puertas en comparaci贸n con m茅todos tradicionales como el algoritmo HHL, haci茅ndolo m谩s adecuado para las computadoras cu谩nticas intermedias ruidosas actuales (NISQ). El HQLS opera a trav茅s de un proceso de inicializaci贸n, dise帽o de circuitos cu谩nticos parametrizados, optimizaci贸n iterativa, aproximaci贸n del marco shadow y verificaci贸n de convergencia.
La tecnolog铆a muestra promesas para aplicaciones en modelado clim谩tico, qu铆mica cu谩ntica, aprendizaje autom谩tico y modelado financiero, con potencial para integrarse con otros algoritmos cu谩nticos para la resoluci贸n de problemas complejos.
WiMi 頇搿滉犯霝 韥措澕鞖半摐 (NASDAQ: WIMI)電 靹犿槙 氚╈爼鞁 鞁滌姢韰滌潉 頃搓舶頃橁赴 鞙勴暅 靸堧鞖 鞏戩瀽 鞎岅碃毽鞚 頇搿滉犯霝 鞏戩瀽 靹犿槙 頃搓舶旮 (HQLS)鞚 臧滊皽鞚 氚滍憸頄堨姷雼堧嫟. HQLS電 氤攵 鞏戩瀽 鞎岅碃毽 (VQA)鞕 鞝勴喌鞝侅澑 鞏戩瀽 頃搓舶旮办潣 頃橂摐鞗柎 鞛愳洂 鞝滍暅鞚 攴闺车頃橁赴 鞙勴暣 瓿犾爠鞝侅澑 攴鸽鞛 頂勲爤鞛勳泴韥檧 瓴绊暕霅╇媹雼.
鞚 鞎岅碃毽鞚 鞝勴喌鞝侅澑 氚╇矔鞚 HHL 鞎岅碃毽鞐 牍勴暣 鞏戩瀽 牍勴姼 鞖旉惮 靷暛瓿 瓴岇澊韸 氤奠灐靹膘潉 欷勳棳, 順勳灛鞚 靻岇潓 欷戧皠 攴滊 鞏戩瀽(NISQ) 旎错摠韯办棎 雿 鞝來暕頃╇媹雼. HQLS電 齑堦赴頇, 毵り皽氤靾橅檾霅 鞏戩瀽 須岆 靹り硠, 氚橂车 斓滌爜頇, 攴鸽鞛 頂勲爤鞛勳泴韥 攴检偓 氚 靾橂牬 瓴靷 瓿检爼鞚 韱淀暣 鞛戨彊頃╇媹雼.
鞚 旮办垹鞚 旮绊泟 氇嵏毵, 鞏戩瀽 頇旐暀, 旮瓣硠 頃欖姷 氚 旮堨湹 氇嵏毵侅棎靹滌潣 鞚戩毄 臧電レ劚鞚 氤挫棳欤茧┌, 氤奠灐頃 氍胳牅 頃搓舶鞚 鞙勴暅 雼るジ 鞏戩瀽 鞎岅碃毽瓿检潣 韱淀暕 臧電レ劚霃 雮错彫頃橁碃 鞛堨姷雼堧嫟.
WiMi Hologram Cloud (NASDAQ: WIMI) a annonc茅 le d茅veloppement du Holographic Quantum Linear Solver (HQLS), un nouvel algorithme quantique pour r茅soudre des syst猫mes d'茅quations lin茅aires. Le HQLS combine Algorithmes Quantiques Variationnels (VQA) avec le cadre classique de l'ombre pour surmonter les limitations des ressources mat茅rielles des solveurs quantiques traditionnels.
L'algorithme r茅duit les exigences en bits quantiques et la complexit茅 des portes par rapport aux m茅thodes traditionnelles comme l'algorithme HHL, le rendant plus adapt茅 aux ordinateurs quantiques actuels 脿 茅chelle interm茅diaire et bruit茅e (NISQ). HQLS fonctionne 脿 travers un processus d'initialisation, de conception de circuits quantiques param茅tr茅s, d'optimisation it茅rative, d'approximation du cadre d'ombre et de v茅rification de la convergence.
La technologie montre un potentiel prometteur pour des applications dans la mod茅lisation climatique, la chimie quantique, l'apprentissage automatique et la mod茅lisation financi猫re, avec un potentiel d'int茅gration avec d'autres algorithmes quantiques pour la r茅solution de probl猫mes complexes.
WiMi Hologram Cloud (NASDAQ: WIMI) hat die Entwicklung des Holographic Quantum Linear Solver (HQLS) angek眉ndigt, eines neuen quantenmechanischen Algorithmus zur L枚sung linearer Gleichungssysteme. Der HQLS kombiniert Variational Quantum Algorithms (VQA) mit dem klassischen Schatten-Framework, um die Hardware-Ressourcenschw盲chen herk枚mmlicher quantenmechanischer L枚sungsverfahren zu 眉berwinden.
Der Algorithmus reduziert die Anforderungen an Quantenbits und die Komplexit盲t der Tore im Vergleich zu traditionellen Methoden wie dem HHL-Algorithmus, was ihn geeigneter f眉r aktuelle, rauschende Quantencomputer im mittleren Ma脽stab (NISQ) macht. HQLS funktioniert durch einen Prozess der Initialisierung, des Designs parametrisierter quantenmechanischer Schaltkreise, iterativer Optimierung, der Schattensynthese und der Konvergenzpr眉fung.
Die Technologie zeigt vielversprechende Anwendungen in der Klimamodellierung, Quantenchemie, Maschinenlernen und Finanzmodellierung und hat Potenzial zur Integration mit anderen quantenmechanischen Algorithmen zur L枚sung komplexer Probleme.
- Development of resource-efficient quantum algorithm (HQLS) that reduces computational complexity
- Successfully demonstrated lower quantum resource consumption and faster convergence in experiments
- Potential applications in multiple high-value sectors including quantum chemistry and financial modeling
- Current experiments still face challenges of quantum noise and errors
- Technology requires further validation on larger-scale quantum computers
- Dependent on future advancements in quantum error correction techniques
Insights
QLSP refers to the problem of solving linear systems of equations using quantum computing. Solutions to the QLSP often rely on the quantumization of classical linear algebra algorithms used in quantum computing. The most famous quantum linear system solving algorithm is the Harrow-Hassidim-Lloyd (HHL) algorithm, which accelerates the solution of linear systems through quantum superposition and interference. In theory, it can reduce the time complexity from the classical polynomial level to the logarithmic level of quantum computing. However, the HHL algorithm requires the use of large-scale controlled gate operations on quantum hardware, making it difficult to implement on existing quantum computers.
VQAs are a class of algorithms that combine quantum computing with classical optimization methods. VQAs solve problems by implementing parameterized quantum circuits in quantum computing and optimizing the parameters of the quantum circuit using classical optimizers. VQAs are widely applied in fields such as quantum machine learning, quantum chemistry, and quantum linear equation solving.
The core advantage of VQAs lies in their relatively low resource requirements. By using the variational method, VQAs avoid the need to perform complex global operations in quantum circuits, instead optimizing circuit parameters within local spaces. This reduces the number of qubits and quantum gates required.
The classical shadow framework is a strategy used for approximate computations, typically playing a role in scenarios that combine quantum and classical computing. The shadow method obtains approximations by simulating certain computational processes and is widely used in model training in machine learning and algorithm design in quantum computing.
The advantage of the shadow framework is its ability to make efficient estimates with a small number of samples, significantly reducing the need for computational resources. Therefore, combining the shadow framework with quantum computing holds the potential to create more efficient quantum algorithms.
WiMi's HQLS combines the ideas of VQAs and the classical shadow framework. It aims to solve linear systems by optimizing the parameters of the quantum circuit, while avoiding the need for large controlled units. The core idea of the algorithm is to optimize the parameters of the quantum circuit using VQA, and to approximate the computation results at each iteration by combining the classical shadow framework, thus effectively reducing the computational complexity of the algorithm.
The basic process of WiMi's HQLS can be divided into the following steps:
Initialization: Initialize the quantum system and preprocess the linear system using classical algorithms to generate the parameterized quantum circuit.
Parameterized Quantum Circuit: Design the quantum circuit using VQA and initialize the parameters of the circuit.
Iterative Optimization: Optimize the parameters of the quantum circuit using a classical optimizer, and after each optimization, obtain an approximate solution through quantum computation.
Shadow Framework Approximate Calculation: At each parameter update, use the classical shadow framework to approximate the output of the quantum circuit, thereby avoiding high quantum resource consumption.
Convergence Check: Calculate the error between the current solution and the true solution to determine whether the algorithm has converged.
Result Output: Output the solution vector X of the solved system of linear equations.
WiMi's HQLS resource optimization mainly focuses on two aspects:
Quantum Bit Count: Traditional quantum linear system solving algorithms require a large number of quantum bits to represent the different dimensions of the problem. With the introduction of VQAs, HQLS only requires quantum bits that scale logarithmically with the size of the problem, significantly reducing the number of quantum bits needed.
Quantum Gate Complexity: The optimization of the quantum circuit can significantly reduce the number of quantum gates, thereby lowering the complexity of quantum circuit execution. By combining with the classical shadow framework, HQLS avoids the need to perform large-scale controlled operations, making the quantum circuit more compact and efficient.
As a resource-efficient quantum algorithm, WiMi's HQLS successfully overcomes the challenges of solving linear systems under the current limitations of quantum hardware. By combining VQAs and the classical shadow framework, HQLS not only operates efficiently with fewer quantum bits and quantum gates, but also demonstrates significant advantages in experiments involving the solution of multiple linear systems.
In traditional quantum linear solving algorithms (such as the HHL algorithm), the resource requirements are often quite high, particularly in terms of the number of quantum bits and the complexity of quantum gates, making it difficult to implement them on current noisy intermediate-scale quantum (NISQ) computers. However, HQLS significantly reduces the resource requirements for quantum hardware by innovatively introducing the framework of Variational Quantum Algorithms (VQA). Additionally, with the assistance of the classical shadow framework, the computational complexity is further reduced, enabling efficient solutions on practical quantum hardware.
We have verified the effectiveness of WiMi's HQLS through experiments on multiple linear systems (such as solving high-dimensional matrices and discretized Laplace equation problems). The experimental results demonstrate that HQLS excels in both solution accuracy and computational efficiency. In particular, when compared to other quantum linear system solving methods, it shows lower quantum resource consumption and faster convergence.
Currently, the experiments of HQLS still rely on noisy intermediate-scale quantum computers for validation, and thus face the challenges of quantum noise and errors. In the future, the combination of quantum error correction (QEC) techniques and noise suppression algorithms will improve the stability and robustness of HQLS on practical quantum hardware. By introducing quantum fault-tolerant technologies, HQLS will be able to scale to larger quantum computers and operate stably in high-noise environments.
In the future, with the continuous optimization of quantum computing hardware and the increase in the number of quantum bits, HQLS can undergo larger-scale validation on practical quantum computers. Particularly with advancements in error correction techniques and improvements in quantum bit quality, it is expected that the efficiency and accuracy of HQLS will be further enhanced.
In various application scenarios of quantum computing, HQLS can not only be applied independently but also combined with other quantum algorithms to form more complex hybrid quantum algorithms. For example, HQLS can be combined with quantum optimization algorithms, such as the Quantum Approximate Optimization Algorithm (QAOA), to tackle more complex optimization problems. Furthermore, HQLS can be integrated with quantum simulation algorithms to solve large-scale linear systems involved in modeling physical processes.
HQLS has significant application potential, especially in areas like large-scale data processing, physical simulations, and optimization problems. As quantum computing capabilities improve, HQLS could be used to solve more complex linear system problems in fields such as climate modeling, quantum chemistry, machine learning, and financial modeling. For instance, in quantum chemistry, HQLS could be used to solve the electronic structure of molecular orbitals, providing more efficient simulation results; in machine learning, it can accelerate the solution of linear regression and least-squares problems.
WiMi's HQLS, as an interdisciplinary quantum algorithm, is expected to integrate more deeply with other fields (such as quantum information, quantum machine learning, quantum chemistry, etc.) in the future. In particular, in the application of quantum machine learning, HQLS could provide a more efficient computational tool for training large-scale machine learning models. Moreover, with the exploration of emerging fields like quantum consciousness research and quantum neural networks, HQLS may also become a foundational tool for solving complex problems in these areas.
The introduction of WiMi's Holographic Quantum Linear Solver (HQLS) opens up new avenues for the application of quantum computing in solving linear system problems. By combining Variational Quantum Algorithms (VQA) with the classical shadow framework, HQLS effectively reduces the resource requirements for quantum hardware, enabling efficient solutions on current quantum computers. Looking ahead, with continuous advancements in quantum hardware and further optimization of algorithms, HQLS is expected to see widespread application in multiple fields, driving the maturation of quantum computing technology and offering new solutions for solving complex problems in modern science and engineering.
About WiMi Hologram Cloud
WiMi Hologram Cloud, Inc. (NASDAQ:WiMi) is a holographic cloud comprehensive technical solution provider that focuses on professional areas including holographic AR automotive HUD software, 3D holographic pulse LiDAR, head-mounted light field holographic equipment, holographic semiconductor, holographic cloud software, holographic car navigation and others. Its services and holographic AR technologies include holographic AR automotive application, 3D holographic pulse LiDAR technology, holographic vision semiconductor technology, holographic software development, holographic AR advertising technology, holographic AR entertainment technology, holographic ARSDK payment, interactive holographic communication and other holographic AR technologies.
Safe Harbor Statements
This press release contains "forward-looking statements" within the Private Securities Litigation Reform Act of 1995. These forward-looking statements can be identified by terminology such as "will," "expects," "anticipates," "future," "intends," "plans," "believes," "estimates," and similar statements. Statements that are not historical facts, including statements about the Company's beliefs and expectations, are forward-looking statements. Among other things, the business outlook and quotations from management in this press release and the Company's strategic and operational plans contain forward鈭抣ooking statements. The Company may also make written or oral forward鈭抣ooking statements in its periodic reports to the US Securities and Exchange Commission ("SEC") on Forms 20鈭扚 and 6鈭扠, in its annual report to shareholders, in press releases, and other written materials, and in oral statements made by its officers, directors or employees to third parties. Forward-looking statements involve inherent risks and uncertainties. Several factors could cause actual results to differ materially from those contained in any forward鈭抣ooking statement, including but not limited to the following: the Company's goals and strategies; the Company's future business development, financial condition, and results of operations; the expected growth of the AR holographic industry; and the Company's expectations regarding demand for and market acceptance of its products and services.
Further information regarding these and other risks is included in the Company's annual report on Form 20-F and the current report on Form 6-K and other documents filed with the SEC. All information provided in this press release is as of the date of this press release. The Company does not undertake any obligation to update any forward-looking statement except as required under applicable laws.
听
View original content:
SOURCE WiMi Hologram Cloud Inc.
FAQ
What is WiMi's HQLS technology and how does it improve quantum computing?
What are the main advantages of WIMI's HQLS over traditional quantum algorithms?
What are the current limitations of WIMI's HQLS technology?
What industries could benefit from WIMI's HQLS technology?
