• Services
    • Consulting
      • Strategy, Analytics and M&A
      • Future Industry Upgrade and Innovation Consulting
      • Leading-edge and Distinctive Innovative Solutions
      • Elevating Businesses with Unparalleled Depth and Expertise
    • Financial Advisory
      • Mergers & Acquisitions
      • Economic Advisory
      • Investment Advisory
  • Industries
    • Quantum
      • Quantum Computer
      • Quantum Communication
      • Quantum Precision Measurement
      • Post Quantum Cryptography
    • Intelligent Driving
      • Automotive
    • Future Industries
  • CTF
    • CTF Model
  • Services
    • Consulting
      • Strategy, Analytics and M&A
      • Future Industry Upgrade and Innovation Consulting
      • Leading-edge and Distinctive Innovative Solutions
      • Elevating Businesses with Unparalleled Depth and Expertise
    • Financial Advisory
      • Mergers & Acquisitions
      • Economic Advisory
      • Investment Advisory
  • Industries
    • Quantum
      • Quantum Computer
      • Quantum Communication
      • Quantum Precision Measurement
      • Post Quantum Cryptography
    • Intelligent Driving
      • Automotive
    • Future Industries
  • CTF
    • CTF Model

ICV: Quantum Computing Measurement & Control System Market Research Report

icv    Research    Quantum    normal report    ICV: Quantum Computing Measurement & Control System Market Research Report

For a preview of our comprehensive report, kindly follow the link provided at the end of this page.

Should you wish to purchase the full report or explore our consultation services, please direct your inquiries to infer@icvtank.com. We're ready to support your quest for insights in the Quantum Information Technology sector.

 

 

 

Introduction

 

The term quantum computing measurement and control system (QCMCS) refers to the hardware (and supporting software) system that connects a classical information system to a quantum bit (henceforth referred to as Qubit) system, it enables precise measurement and control of quantum states in quantum computer.

 

Different qubits possess distinct physical properties, necessitating specific methods for manipulation and measurement, superconducting qubits are measured using RF microwaves, ion trap qubits rely on lasers, photonic qubits use lasers and photodetectors, neutral atom qubits utilize precise optics or microwaves, and spin qubits rely on electron spin resonance techniques.

 

Given the advanced stage of superconducting quantum computing, its measurement and control system has emerged as a unique domain within the field of technology and equipment development. A typical Superconducting QCMCS generally includes

 

  1. Signal generation devices, such as microwave signal generators. These are used to create the signals that operate the quantum bits.

  2. Signal processing devices, including Digital to Analog Converters (DACs) and Analog to Digital Converters (ADCs). These are responsible for handling measurement signals and readout signals.

  3. Signal amplifiers like low-noise amplifiers, which are tasked with amplifying the subtle readout signals.

  4. Control software, designed to command the hardware devices mentioned above and to process the resulting measurement data.

 

Categories of QCMCS

 

For the sake of classification and understanding of key components in the measurement and control systems, we categorize them into two types based on shared characteristics: Superconducting and Semiconductor Quantum Computing Measurement & Control Systems (SQCMCS) and Optical Quantum Computing Measurement & Control Systems (OQCMCS).

 

The main reason for classifying superconducting and semiconductor (silicon spin) as one category is that they both belong to quantum computing constructed by solid-state physical systems. Both systems use microwave pulses for operations and rely on radio frequency and microwave technology. The hardware equipment shares many common components. The other category is due to the commonalities of optical quantum computing, ion trap computing, and neutral atom computing, all of which are associated with optical devices.

 

The role of QCMCS

 

In a quantum computer, the measurement and control system serves a role similar to that of the input/output system and control unit in a classical computer. QCMCS is responsible for reading, controlling, and manipulating the qubits' state. It orchestrates the timing and synchronization of quantum operations and manages the flow of information between the qubits and other components of the system.

 

QCMCS generates precise signals, such as microwave or laser pulses, to manipulate the qubits according to the desired quantum operations. It ensures the proper execution of quantum algorithms by controlling the interactions between the qubits.

 

Global Market Overview

The global quantum computing measurement and control system market is projected to reach USD 364.4 million by 2023, with an anticipated growth to USD 772.1 million by 2027.

 

 

The market share of measurement and control systems for superconducting and semiconductor quantum computing is projected to surpass 70% in 2025, with optical measurement and control systems accounting for the remainder.

 

 

The market of QC Measurement & Control System in Europe will worth $148.9 million in 2023, it is estimated to grow to $310.4 Million in 2025, resulting at a 4-year CAGR of 41.4%. The North America market will be the second largest segment, it will worth $64.7 million in 2023 and is estimated to increase to $97.2 Million in 2027, with a 4-year CAGR of 48.5%.

 

 

 

 

 

 

Table of Contents

1 Foreword
2 Methodology
3 Introduction of QC Measurement & Control Systems 
3.1 An Overview of QCMCS
3.2 QCMCS for Different Quantum Computing Routes
4 Global QCMCS Market Overview
4.1 QCMCS Market Size Prediction (2019–2027) 
4.2 QCMCS Market by Type
4.3 QCMCS Market by Region
5 Segment Market Forecast (North America, Asia Pacific, Europe)
5.1 QCMCS Market Size Forecast by Country
5.2 QCMCS Market Size Forecast by Type

6 QCMCS Market Forces
6.1 Key Market Players Analysis 
6.2 Market Divers
6.3 Market Opportunities
7 Selection of QCMCS for QC R&D Teams and related Recommendations
7.1 Choosing the Right Path for QCMCS
7.2 Advice for Quantum Computing R&D Teams
8 Summery
9 Disclaimer

 

List of Exhibit

Exhibit: Classification of QCMCS

Exhibit: Workflow of SQCMCS

Exhibit: Workflow of OQCMCS

Exhibit: Information of QCMCS Scientific Research Institutes

Exhibit: Introduction of Major Companies

Exhibit: Timeline for the Establishment of QCMCS

Exhibit: Major Companies’ Distribution of QCMCS

Exhibit: Comparison of the Key Performance Indictor of the Major QCMCS Product

Exhibit: 2019-2027 Global QCMCS Industry Market Scale and Growth Rate

Exhibit: 2019-2027 Global QCMCS Market by Type

Exhibit: 2019-2027 Global QCMCS Market by Regions

Exhibit: 2019-2027 China QCMCS Market Prediction and Growth Rate

Exhibit: 2019-2027 Europe QCMCS Market Prediction and Growth Rate

Exhibit: 2019-2027 North America QCMCS Market Prediction and Growth Rate

Exhibit: 2019-2027 Asia Pacific Excluding China QCMCS Market Prediction and Growth Rate

Exhibit: 2019-2027 Others QCMCS Market Prediction and Growth Rate

Exhibit: 2019-2027 China QCMCS Market Prediction by Type

Exhibit: 2019-2027 Europe QCMCS Market Prediction by Type

Exhibit: 2019-2027 North America QCMCS Market Prediction by Type

Exhibit: 2019-2027 Asia Pacific excluding China QCMCS Market Prediction by Type

Exhibit: 2019-2027 Others QCMCS Market Prediction by Type

Exhibit: 2019-2027 QCMCS Application Market Size by Type

 

Report Sample Link:Quantum Computing Measurement & Control System Market Research Report

 

Contact details

Phone: +1 929 530 5901

Email: infer@icvtank.com

Website: http://www.icvtank.com/

Address: 5250 Fairwind Dr. Mississauga, Ontario, L5R 3H4, Canada

 

Previous: null
Next: null