The upcoming First CCF Quantum Computing Conference (CQCC 2022), to be held in Zhengzhou on August 20-21, invites renowned academicians and experts in the field to give invited presentations to the general public from the industrial system, research status, quantum programs, post-quantum codes, quantum superiority, ion quantum computing and quantum modulation.
CQCC 2022 Invited Guest Speaker
Lu Jun Member of the Chinese Academy of Engineering, Chief Scientist of China Electronics Technology Corporation
Director of Quantum Technology Yangtze River Delta Industrial Innovation Center, Executive Director. Academician Lu Jun is the academic leader in the field of early warning aircraft information system in China. He has been engaged in the research of integrated electronic information system and the development of major model projects for more than 30 years, and has profound attainments in the fields of electronic technology, information system and artificial intelligence. He has won the National Science and Technology Progress Grand Prize, the First Prize of National Defense Science and Technology Progress Award, the Golden Medal issued by the Central Committee of the Communist Party of China, the State Council and the Central Military Commission, the May Day Labor Medal, the Guanghua Engineering Science and Technology Award, and the CCTV Innovation Personality. He led the early warning aircraft team and was awarded the title of "Innovation Team" by the Ministry of Science and Technology of China.
Title: Thinking about the construction of quantum information technology industrial system
Abstract: With the further development of modern information technology, quantum information technology is widely believed to lead a new generation of information technology revolution, triggering a large number of technology industry revolutionary innovation development. The fourteenth five-year plan of China also lists "quantum information" as a national strategic science and technology frontier field.
To develop quantum information technology, we must analyze the development trend of quantum information technology, and deeply understand the formation process of quantum information technology industry system and the key core of building quantum information technology industry system.
This report explains the development trend of quantum information technology, and elaborates on the thinking of building quantum information technology industrial system from science and technology system, industry system and system system, and uses the "scientific system engineering" method to form the ABCPM model of developing science and technology industrial system, and proposes that at the early stage of quantum information technology industrial development In order to seize the high point of competition in the world quantum science and technology industry system, we should start to lay out and form a quantum information technology industry system with "industrial software + public benchmark + industrial mother machine" as the core capacity.
Dapeng Yu Academician of Chinese Academy of Sciences, APS Fellow, President of Shenzhen International Institute of Quantum Research
Dapeng Yu, an academician of Chinese Academy of Sciences and an APS Fellow, is currently the President of Shenzhen International Institute of Quantum Research, a Chair Professor of the Department of Physics of Southern University of Science and Technology, and the Chairman of the Quantum Information Branch of Chinese Institute of Electronics and the President of Shenzhen Institute of Electronics.
Professor Yu Dapeng has been engaged in the research of low-dimensional nanostructure physics for a long time, and was one of the first international pioneers to discover bottom-up methods for the preparation of 1D semiconductor nanowires and 2D Dirac quantum materials characterization, making important contributions to the research of low-dimensional quantum materials. In recent decades, his research has focused on the precise quantum tuning of physical properties of single nanowires and monolithic quantum structures such as photoelectricity, electricity, heat and magnetism, and has achieved a series of results. The research team led by him has reached new heights in the manipulation of physical properties such as photoelectricity-thermal-magnetic of single microstructures such as nanowires and graphene.
Title: Quantum Computing: A Long Way to Go - Quantum Action in Shenzhen
Abstract: Quantum computing and other related quantum technologies have become the focus of competition among international powers, and have also become a highly restricted area where the United States has imposed a comprehensive technology blockade, equipment embargo and personnel interdiction on China, and China has truly entered a "no man's land" in the field of quantum technologies. In this report, Prof. Yu Dapeng will give a comprehensive analysis of the development status, challenges and opportunities of quantum computing, explain the research foundation and advantages of China in the field of quantum computing, and put forward some policy recommendations for the current situation.
Mingsheng Ying (Ying Mingsheng) Researcher, Institute of Software, Chinese Academy of Sciences; Distinguished Professor, Changjiang Scholar, Tsinghua University
Mingsheng Ying is a Research Professor at the Institute of Software at the Chinese Academy of Sciences, and holds the Cheung Kong Chair Professorship at Tsinghua University. His research interests include quantum computation, theory of programming languages, and logics in AI. He has published books: Model Checking Quantum Systems: Principles and Algorithms (2021) (with Yuan Feng), Foundations of Quantum Programming (2016) and Topology in Process Calculus: Approximate Correct- ness and Infinite Evolution of Concurrent Programs (2001). He has served on the editorial board of several publications including Artificial Intelligence Journal. He is currently (Co)Editor-in-Chief of ACM Transactions on Quantum Computing。
Title:Quantum Hoare logic and its applications
Abstract:In this talk, Prof. Ying will mainly discuss the program logic approach to verification of quantum programs, including quantum Hoare logic and its related problems (invariant generation and termination analysis for quantum programs). He'll also briefly discuss its potential applications to other fields (e.g. verification of quantum cryptographic protocols, debugging of quantum programs). Some problems for future research will be proposed at the end of the talk.
Ding Jintai Distinguished Professor, Cheng-Tung Yau Center for Mathematics, Tsinghua University
D.in Mathematics from Yale University. He is currently a professor at the Yau Shing-Tung Center for Mathematics at Tsinghua University, where his main research interests are cryptography and computational algebra. He has served as co-chair of the International Conference on Post-Quantum Cryptography for three times, and is an international authority in the field of post-quantum cryptography. He has been involved in the design of the Kyber public key encryption algorithm algorithm, which has officially become the standard algorithm for post-quantum cryptographic security in the United States; in addition, he presided over the design of Rainbow digital signature algorithm.
Title: Post-Quantum Cryptography: A New Generation of Public Key Cryptosecurity Systems
Abstract: Public Key Cryptography (PKC), started in the 1970s with research on Diffie-Hellman protocol and RSA problems. In today's digital age, public key cryptography helps to solve trust issues and data security problems in the network, and is the cornerstone of Internet security. However, the emergence of the Shor algorithm in 1996 changed all that: we need a new generation of public-key cryptosecurity systems, i.e., post-quantum cryptography. After nearly 20 years of development, post-quantum cryptography has taken initial shape and can basically meet our needs for security and efficiency. Based on this, the U.S. has taken the lead in developing post-quantum cryptographic security standards and has recently published some of the selected standard algorithms to facilitate post-quantum migration work.
This report will describe the process of developing post-quantum cryptographic security standards in the United States and its impact. In addition, this report analyzes the great challenges in post-quantum migration efforts in the coming decades.
Shan Zheng Professor of Information Engineering University, Deputy Director of CCF Quantum Computing Group
Zheng Shan is a professor and doctoral supervisor at the University of Information Engineering. His main research interests are advanced computing and network security. He is a member of the Teaching Steering Committee of Computer Science of the Ministry of Education and the deputy director of the Quantum Computing Professional Group of the Chinese Computer Society. He has received two first-class and five second-class Provincial and Ministerial Science and Technology Progress Awards, one CCF CNCC Technology Innovation Award, and is the leader of the National First-class Course.
Title: The Quantum Superiority Paradox: Construction and Verification of the Problem
Abstract: Classical computing and quantum computing are "playing" each other on the "quantum superiority" problem. After Google's Hanging Suzuki achieved "quantum superiority" in the random line sampling problem, our Jiuzhang achieved "quantum superiority" in the Gaussian Bose-sampling problem and Zuchung's in the random line sampling problem. The quantum computing simulator (SWQSIM) of the Shineway supercomputer can obtain millions of correlation samples with higher fidelity in less than 304 seconds, and it can also simulate quantum circuits more than 1000 times more complex than the "hanging timber" in 60 hours. The report analyzes the rationale and justification of these "quantum superiority" problems from the viewpoint of computability, and gives exploratory ideas for the construction and verification of the so-called "superiority" problems.
Lu-Ming Duan Professor of Basic Sciences, Yao Qizhi Chair Professor, Tsinghua University, Fellow of the American Physical Society
Luming Duan received his B.S. (Ph.D.) degrees from the University of Science and Technology of China in 1994 (1998), respectively, and has served as Assistant Professor, Associate Professor, Professor, and Fermi Chair Professor at the University of Michigan, U.S.A. He returned to China full time in 2018 as the Chair Professor of Basic Science and Yao Chi-Chi Chair Professor at Tsinghua University. He was awarded the Yutai Rao Prize in Fundamental Optics, the Ying-Tung Huo Award for Young Research, the Sloan Research Award in the United States, and the Outstanding Research Award of the Overseas Chinese Physical Society.
He has done some pioneering work in the field of quantum information and proposed the "DLCZ (Duan-Lukin-Cirac-Zoller) quantum relay scheme and network quantum computing scheme, which laid the foundation for long-range quantum communication and scalable quantum computing. Lu-Ming Duan has published more than 200 papers in major international journals including Modern Physical Review (2), Nature (8), Science (3), Physical Review Letters (50+), etc. His papers have been cited by Google Scholar more than 33,000 times so far.
Title: Advances in ion quantum computing
Abstract:In this talk, Prof. Duan will review the recent progress on trapped ion quantum computing and networking, including the realization of large-scale quantum simulation of dynamics in Hubbard-type models beyond the classical simulation capability and the implementation of the dual-type qubits with crosstalk errors significantly below the error threshold, a key component for quantum error correction and fault-tolerant quantum computing.
Yu Yang Professor, School of Physics, Nanjing University
Yang Yu is a professor at the School of Physics, Nanjing University. His main research area is superconducting quantum computing and superconducting devices, and he is one of the earliest members of the international experimental research on superconducting quantum computing. 2002 First experimental observation of quantum coherent oscillations in superconducting phase quantum bits, paper (first author) published in Science, Nobel Prize winner in physics Leggett commented that his work broke the barrier of decoherence of superconducting quantum bits. 2010 Pioneered the demonstration of coherent tuning of three solid-state quantum bits. His work also includes the observation of macroscopic quantum phenomena such as MACH-ZEHNDER interference in superconducting quantum bits, LANDAU-ZENER interference in quantum geometric phases, and the simulation of topological energy band structures using superconducting quantum bits. He has published more than 100 SCI papers, including 3 in Science, 1 in Nature Communications, and 11 in Phys. Rev. Lett. He has led many major projects including the Key R&D Program of the Ministry of Science and Technology.
Title: Fast Adiabatic Regulation of Superconducting Quantum Bits
Abstract: Quantum adiabatic evolution has good stability and provides an important tool for regulation in quantum computing and quantum simulation. However, the adiabatic evolution is generally long due to the adiabatic condition, which can reduce the regulatory fidelity for some systems with short decoherence time. We use two different schemes, optimized excited Raman process and elimination of kinetic phase, to achieve accelerated adiabatic tuning, which accelerates the tuning speed and thus improves the fidelity while maintaining the stability of adiabatic evolution. Our scheme can be used for integrated tuning of superconducting quantum chips.
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Please refer to the conference website for the detailed schedule of the above invited presentations. In addition to the heavy invited presentations, the first CCF Quantum Computing Conference also features 10 special forums covering hardware and software, industry, education and other fields, as well as excellent paper/representative work sharing sessions.
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The conference will also launch a call for papers, and outstanding papers will be reviewed and recommended to the following journals.
Frontiers in Physics (SCI) Nanotechnology (SCI)
SPIN (SCI)
Quantum Engineering (regular journal)
Journal of the University of Electronic Science and Technology (EI)
Advances in Lasers and Optoelectronics (ESCI)
Computer Applications
Journal of Beijing University of Technology (Nature Edition)
Journal of Quantum Electronics
Journal of Information Engineering University
Journal of Zhengzhou University
Computer Education
Software Journal
Deadline for submission: August 7, 2022
Acceptance notification date: August 15, 2022
Conference date: August 20-21, 2022
Please visit the following conference submission system link to submit your paper (non-CCF members must register).
https://conf.ccf.org.cn/cqcc2022/paper (Chinese)
https://conf.ccf.org.cn/en/cqcc2022/paper (English)
We welcome all scholars in computing and physics who are interested in quantum computing to attend the first CCF Quantum Computing Conference in Zhengzhou, the "Green City", to exchange academic ideas and discuss cooperation, and to witness and promote the development of quantum computing in China.
