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封面
市場調查報告書
商品編碼
1914726

光子量子電腦市場

Markets for Photonic Quantum Computers
出版日期: | 出版商: Communications Industry Researchers (CIR) | 英文 | 訂單完成後即時交付

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簡介目錄

本報告的主要目標是分析和量化以光子學為關鍵基礎的量子電腦的商業潛力。目前,市面上大約有15款這類量子計算機,其中PsiQuantum獲得了迄今為止最大的融資,Xanadu也備受關注。然而,正如將在本報告中討論的那樣,還有一些公司不如PsiQuantum和Xanadu那麼知名。

在領先的量子計算技術中,光子量子電腦被認為是 "最先進" 的。這是因為它們與基於測量的量子電腦(MBQC)最為密切相關,有望顯著提高糾錯能力,並為建立先進的量子網路提供 "自然路徑" 。

目錄

第1章 光子量子電腦:產品與產業背景

  • 報告背景
  • 光子量子計算機的優勢
  • 光子量子計算機的挑戰
  • 其他類型的光子量子計算機
  • 光子量子計算機的晶片和晶片組
    • 研究機構和大學
    • 商業供應商
  • 元件和子系統
    • 雷射和光源
    • 頻率梳
    • 光子偵測器
    • 控制晶片
    • SDK
  • 光子量子計算機的新架構
    • CV架構
    • T-Center架構
  • 價值量子電腦品牌社群:對光子量子電腦的適用性
    • Quandela Cloud
    • Xanadu
  • 光子量子電腦產業結構
    • 俄羅斯和中國
  • 下一章

第2章 光子量子電腦及相關產品

  • Bose Quantum Technology/QBoson(中國)
    • 現有產品
    • 客戶群和市場
  • Electronics and Telecommunications Research Institute(ETRI)(韓國)
  • InfamousPlatypus(美國)
    • 客戶群和競爭對手
  • MITRE Corporation/CVE(美國)
    • Quantum Moonshot
    • 客戶基礎
  • NTT(日本)
    • 當前研究
  • ORCA Computing(英國)
    • PT系列產品
    • 商用現成產品(COTS)應用
    • ORCA 客戶:高效能運算(HPC)應用
  • Photonic(加拿大)
    • 產品與技術演進
    • 客戶群和競爭
  • PsiQuantum(美國)
    • 技術演進
    • 客戶群和競爭
  • Q.Ant(德國)
  • QC82(美國)
    • 公司目標
    • 目標客戶
  • Quandela
    • 技術與製造
    • Quandela 雲
    • 客戶群和競爭對手
  • Quanfluence(印度)
  • Quantum Computing Inc.(美國)
    • 現有產品與服務
    • 客戶群和競爭對手
  • Quantum Source Labs(以色列)
    • 電腦策略
    • 客戶群
  • QuiX Quantum(荷蘭)
    • 現有產品
    • 客戶
  • Rotonium(義大利)
    • 研發方向
    • 製造
    • 潛在客戶群
  • Spooky Manufacturing(美國)
  • TundraSystems Global LTD(英國)
  • TuringQ(中國)
    • Quantum Computer Supply and Manufacturing
    • 客戶基礎
  • Xanadu Quantum Technologies(加拿大)
    • 產品與技術
    • 製造
    • 客戶與合作夥伴
    • Xanadu Cloud 的興衰
  • 組件公司
    • ID Quantique(瑞士)
    • M-Labs(中國)
    • Menlo Systems(德國)
    • Nanofiber Quantum Technologies(日本)
    • Nexus Photonics(美國)
    • Nicslab(美國)
    • Sparrow Quantum(丹麥)
    • Toptica Photonics(德國)
    • Toshiba(日本)
    • Vescent(美國)
  • 服務公司
    • Iceberg Quantum(澳洲)
  • 軟體
    • QC Design(德國)
    • QMware(瑞士)
  • 平台
    • qBraid(美國)
  • 研究機構/大學
    • Griffith University
    • Harvard University
    • Institute for Photonic Quantum Systems(德國)
    • Israeli Quantum Computing Center
    • Nanjing University
    • National Quantum Computing Center(英國)
    • National Quantum Laboratory(俄羅斯)
    • Niels Bohr Institute(丹麥)
    • Poznan Supercomputing and Networking Center
    • Queensland University of Technology
    • RIKEN(日本)
    • Russian Quantum Center
    • Sandia National Laboratory(美國)
    • Simon Fraser University(加拿大)
    • University of Arizona
    • University of Bristol
    • University of New Mexico
    • University of Queensland
    • University of Science & Technology of China(USTC)
    • University of Southern Queensland
    • University of the Sunshine Coast
    • University of Virginia
    • University of Washington
    • University of Waterloo

第3章 光子量子電腦的目標應用

  • 研究儀器與實驗室
  • 量子化學與材料科學
  • 金融與銀行業
  • 軍事、情報和航太
  • 汽車和交通運輸
  • 能源產業
  • 光子計算機:專為特定地點設計
    • 光子計算機與高效能運算:量子超級計算機
    • 資料中心級光子量子計算機
    • 機架式光子計算機
    • 光子量子邊緣運算
  • 量子+人工智慧

第4章 光子量子電腦十年預測

  • 研究方法
  • 出貨量預測
    • 初始出貨量
    • 今後五年成長
  • 依產品類型劃分的出貨量
  • 替代方案
  • 關於分析師
簡介目錄

Our primary goal in this report is to analyze and quantify the commercial potential for quantum computers that use photonics for their main fabric. There are perhaps 15 models of such machines being commercialized at the present time with PsiQuantum having attracted the largest funding to date and Xanadu attracting considerable attention, too. But there are others as we report in this document, inevitably not as well known as PsiQuantum and Xanadu.

Of the serious contender technologies for quantum computers, photonic quantum computers seem the most "edgy" in that they (1) are the most strongly associated with measurement-based quantum computers (MBQCs) with their apparent path to significantly improved error correction and (2) offer a "natural path" to advanced quantum networks.

Table of Contents

Chapter 1: Photonic Quantum Computers: Products and Industry Background

  • 1.1 Background to Report
  • 1.2 Advantages of Photonic Quantum Computers
  • 1.3 Challenges of Photonic Quantum Computers
  • 1.4 Types of Photonic Quantum Computers
  • 1.5 Chips and Chipsets for Photonic Quantum Computers
    • 1.5.1 Research Institutes and Universities
    • 1.5.2 Commercial Suppliers
  • 1.6 Components and Subsystems
    • 1.6.1 Lasers and Light Sources
    • 1.6.2 Frequency Combs
    • 1.6.3 Photon Detectors
    • 1.6.4 Control Chips
    • 1.6.5 SDKs
  • 1.7 Novel Architectures for Photonic QCs
    • 1.7.1 CV Architectures
    • 1.7.2 T Centre architecture
  • 1.8 The Value QC Brand Communities: Applicability to Photonic QCs
    • 1.8.1 Quandela Cloud
    • 1.8.2 Xanadu
  • 1.9 Photonic Quantum Computer Industry Structure
    • 1.9.1 Russia and China
  • 1.10 The Next Chapter

Chapter 2: Photonic Quantum Computers and Related Products

  • 2.1 Bose Quantum Technology/QBoson (China)
    • 2.1.1 Current Products
    • 2.1.2 Customer Base and Markets
  • 2.2 Electronics and Telecommunications Research Institute (ETRI) (Korea)
  • 2.3 InfamousPlatypus (United States)
    • 2.3.1 Customer Base and Competition
  • 2.4 MITRE Corporation/CVE (United States)
    • 2.4.1 Quantum Moonshot
    • 2.4.2 Customer Base
  • 2.5 NTT (Japan)
    • 2.5.1 Current Research
  • 2.6 ORCA Computing (United Kingdom)
    • 2.6.1 PT Series Products
    • 2.6.2 Use of COTS
    • 2.6.3 ORCA Customers: Use with HPC
  • 2.7 Photonic (Canada)
    • 2.7.1 Product and Technology Evolution
    • 2.7.2 Customer Base and Competition
  • 2.8 PsiQuantum (United States)
    • 2.8.1 Technical Evolution
    • 2.8.2 Customer Base and Competition
  • 2.9 Q.Ant (Germany)
  • 2.10 QC82 (United States)
    • 2.10.1 Goals of Company
    • 2.10.2 Expected Customer Base
  • 2.11 Quandela
    • 2.11.1 Technology and Manufacturing
    • 2.11.2 Quandela Cloud
    • 2.11.3 Customer Base and Competition
  • 2.12 Quanfluence (India)
  • 2.13 Quantum Computing, Inc. United States
    • 2.13.1 Current Products and Services
    • 2.13.2 Customer Base and Competition
  • 2.14 Quantum Source Labs (Israel)
    • 2.14.1 Computer Strategy
    • 2.14.2 Customer Base
  • 2.15 QuiX Quantum (The Netherlands)
    • 2.15.1 Current Products
    • 2.15.2 Customers
  • 2.16 Rotonium (Italy)
    • 2.16.1 Direction of Research and Product Development
    • 2.16.2 Manufacturing
    • 2.16.3 Possible Customer Base
  • 2.17 Spooky Manufacturing (United States)
  • 2.18 TundraSystems Global LTD (United Kingdom)
  • 2.19 TuringQ (China)
    • 2.19.1 Quantum Computer Offerings and Manufacturing
    • 2.19.2 Customer Base
  • 2.20 Xanadu Quantum Technologies (Canada)
    • 2.20.1 Products and Technology
    • 2.20.2 Manufacturing
    • 2.20.3 Customers and Partners
    • 2.20.4 The Rise and Fall of Xanadu Cloud
  • 2.21 Components
    • 2.21.1 ID Quantique (Switzerland)
    • 2.21.2 M-Labs (China)
    • 2.21.3 Menlo Systems (Germany)
    • 2.21.4 Nanofiber Quantum Technologies (Japan)
    • 2.21.5 Nexus Photonics (United States)
    • 2.21.6 Nicslab (United States)
    • 2.21.7 Sparrow Quantum (Denmark)
    • 2.21.8 Toptica Photonics (Germany)
    • 2.21.9 Toshiba (Japan)
    • 2.21.10 Vescent (United States)
  • 2.22 Services
    • 2.22.1 Iceberg Quantum (Australia)
  • 2.23 Software
    • 2.23.1 QC Design (Germany)
    • 2.23.2 QMware (Switzerland)
  • 2.24 Platforms
    • 2.24.1 qBraid (United States)
  • 2.25 Research and Universities
    • 2.25.1 Centre for Quantum Computation and Communication Technology (CQC2T) (Australia)
    • 2.25.2 Griffith University (Australia)
    • 2.25.3 Harvard University ( United States)
    • 2.25.4 Institute for Photonic Quantum Systems (PhoQC) (Germany)
    • 2.25.5 Israeli Quantum Computing Center (IQCC) (Israel)
    • 2.25.6 Nanjing University (China)
    • 2.25.7 National Quantum Computing Center (NQCC) (United Kingdom)
    • 2.25.8 National Quantum Laboratory (NQL) (Russia)
    • 2.25.9 Niels Bohr Institute (NBI) (Denmark)
    • 2.25.10 Poznan Supercomputing and Networking Center (PSNC)
    • 2.25.11 Queensland University of Technology (QUT) (Australia)
    • 2.25.12 RIKEN (Japan)
    • 2.25.13 Russian Quantum Center (Russia)
    • 2.25.14 Sandia National Laboratory (United States)
    • 2.25.15 Simon Fraser University (Canada)
    • 2.25.16 University of Arizona (United States)
    • 2.25.17 University of Bristol (United Kingdom)
    • 2.25.18 University of New Mexico (United States)
    • 2.25.19 University of Queensland (Australia)
    • 2.25.20 University of Science & Technology of China (USTC)
    • 2.25.21 University of Southern Queensland (UniSQ) (Australia)
    • 2.25.22 University of the Sunshine Coast (Australia)
    • 2.25.23 University of Virginia (UVA) (United States)
    • 2.25.24 University of Washington (UW) (United States)
    • 2.25.25 University of Waterloo (Canada)

Chapter 3: Target Applications for Photonic Quantum Computers

  • 3.1 Research Machines and Laboratories
  • 3.2 Quantum Chemistry and Materials Science
  • 3.3 Finance and Banking
  • 3.4 Military, Intelligence and Aerospace
  • 3.5 Automotive and Transportation
  • 3.6 The Energy Industry
  • 3.7 Photonic Computers: Design for Specific Locations
    • 3.7.1 Photonic Computers and HPC: The Quantum Supercomputer
    • 3.7.2 Data Center Scale Photonic Quantum Computers
    • 3.7.3 Rack-Mounted Photonic Computers
    • 3.7.4 Photonic Quantum Edge Computing
  • 3.8 Quantum + AI

Chapter 4: Ten-year Forecasts of Photonic Quantum Computers

  • 4.1 Methodology
  • 4.2 Shipment Forecast
    • 4.2.1 Initial Shipments
    • 4.2.2 Growth Over the Next Five Years
  • 4.3 Shipments by Product Type
  • 4.4 Alternative Scenarios
  • About the Analyst

List of Exhibits

  • Exhibit 4-1: Shipments of QCs vs. Photonic QCs
  • Exhibit 4-2: Worldwide Shipments of Photonic QCs by Type