全球光學測量市場規模：按技術類型、按應用、按產品類型、按地區、範圍和預測

光學測量市場規模及預測

2023年光學測量市場規模為56.6億美元，預計2024年至2030年複合年增長率為6.26%，到2030年將達到97.6億美元。

光學測量的全球市場推動因素

光學測量市場的市場推動因素可能受到多種因素的影響。

技術開發：技術開發：

3D 掃瞄、雷射干涉測量和攝影測量等光學測量技術的發展帶來了測量速度、精度和可靠性的提高，推動了光學測量解決方案在整個行業中的採用。

精密測量的需求：

為了確保品質、性能和合規性，航空航太、汽車、電子和醫療保健等行業必須準確測量組件、零件和表面。高精度和高解析度的光學測量儀器對於此類應用至關重要。

非接觸式測量：

透過使用光學測量技術，可以實現非破壞性、非接觸式測量。這對於精緻和精緻的材料以及在無菌條件下防止污染特別有用。此功能有助於在接觸式技術不適用或不可行的領域使用光學測量解決方案。

自動化與工業 4.0：

自動化和工業 4.0 趨勢需要先進的製造測量技術來進行品質控制、流程最佳化和數位整合。光學測量系統有助於在自動化生產環境中進行準確、有效率的測量。它也經常與機器人和其他自動化技術結合。

提高品質要求與標準：

不斷提高的行業標準和監管要求（例如 FDA 法規和 ISO 標準）推動了對先進測量系統的需求，以確保合規性和產品品質。光學測量技術提供了滿足這些要求所需的精度和可靠性。

擴大在研究與開發中的使用：

材料科學、生物醫學工程和地球科學等各領域的研究和開發工作在很大程度上依賴光學測量技術。光學測量系統廣泛應用於研究和開發環境，因為它們的適應性使其適合各種應用。

成本與效能優勢：

與接觸式測頭和座標測量機 (CMM) 等傳統測量技術相比，光學測量系統可降低設定、操作和維護成本。它還可以實現高速測量，從而提高工業環境中的生產力和效率。

全球光學測量市場的阻礙因素

有幾個因素可能會成為光學測量市場的限制和挑戰。其中包括：

初始投資高：

初始投資高：光學測量系統對於預算有限的小型企業和組織來說很難使用，因為它們通常需要在技術、設備和訓練有素的人員方面進行大量初始投資。

技術複雜性：

光學測量系統可能難以使用和維護，並且需要一些培訓和經驗。這種複雜性可能使消費者難以學習新技術並阻礙其採用。

某些條件下的準確性有限：

光學測量技術可能不適用於某些產業和環境，因為它們在某些環境條件（例如極端溫度、振動和照明變化）下實現高精度的能力受到限制。

監理合規性：

光學計量組織可能難以遵守行業規範和標準，例如測量精度的 ISO 標準，特別是在需要嚴格品質控管程序的行業中。

與替代技術的衝突：

接觸式測量系統、座標測量機 (CMM)、雷射掃瞄和其他替代測量技術是光學測量領域的競爭對手。在某些情況下，這些替代技術由於其獨特的優勢而被用來取代光學測量。

資料處理與解釋上的困難：

處理和分析光學測量系統產生的大量數據非常困難，需要複雜的數據處理和分析方法。公司在有效分析資料所需的運算能力和知識方面可能受到限制。

維護和校準要求：

為了確保準確性和可靠性，光學測量系統必須定期進行維護和校準。對於一些公司來說，由於相關成本和停機時間，可能很難為維護和校準活動提供資金。

安全性和隱私問題：

這些問題可能成為光學測量涉及收集和處理敏感資料（例如生物儀器或工業製程資料）並確保資料完整性和機密性的應用的障礙，因此有必要引入強有力的保護措施。

與目前系統整合：

與當前系統整合：將光學測量系統與當前工作流程、程序和軟體系統整合可能很困難，特別是在擁有專有或遺留基礎設施的部門中。採用可能會因相容性問題或需要進行更改而受到阻礙。

目錄

第一章簡介

• 市場定義
• 市場區隔
• 調查方法

第 2 章執行摘要

• 主要發現
• 市場概覽
• 市場亮點

第三章市場概述

• 市場規模與成長潛力
• 市場趨勢
• 市場推動因素
• 市場阻礙因素
• 市場機會
• 波特五力分析

第 4 章光學測量市場：依技術類型

• 以雷射為基礎的測量
• 光譜學
• 干涉儀
• 影像系統
• 非接觸式測量

第 5 章光學測量市場，依應用劃分

• 工業生產
• 汽車
• 航空航太與國防
• 醫療保健與生命科學
• 電子和半導體
• 能源和公用事業

第 6 章光學測量市場：依產品類型

• 座標測量機 (CMM)
• 光學數位化儀掃瞄器 (ODS)
• 視覺系統
• 光學比較器
• 光學測微計
• 雷射追蹤器

第七章區域分析

• 北美
• 美國
• 加拿大
• 墨西哥
• 歐洲
• 英國
• 德國
• 法國
• 義大利
• 亞太地區
• 中國
• 日本
• 印度
• 澳大利亞
• 拉丁美洲
• 巴西
• 阿根廷
• 智利
• 中東/非洲
• 南非
• 沙烏地阿拉伯
• 阿拉伯聯合大公國

第 8 章市場動態

• 市場推動因素
• 市場阻礙因素
• 市場機會
• 新冠肺炎 (COVID-19) 對市場的影響

第九章競爭態勢

• 主要公司
• 市佔率分析

第十章公司簡介

• Hexagon Metrology（Sweden）
• Nikon Instruments（Japan）
• Mitutoyo Corporation（Japan）
• GOM mbH（Germany）
• FARO Technologies（US）
• Keyence Corporation（Japan）
• Carl Zeiss（Germany）
• Jenoptik（Germany）
• Zygo Corporation（US）
• Vision Engineering（UK）
• KLA-Tencor Corporation（US）
• Perceptron Inc.（US）
• Breuckmann GmbH（Germany）
• Steinbichler Optotechnik GmbH（Germany）
• Nova Measuring Instruments Ltd.（UK）
• Quality Vision International Pvt. Ltd.（India）
• Creaform（Canada）
• Third Dimension（US）
• Micro-Vu Corp（US）
• ST Industries Inc.（US）
• Nanometrics Incorporated（US）
• Carl Zeiss Meditec AG

第 11 章市場前景與機會

• 新興技術
• 未來市場趨勢
• 投資機會

第12章附錄

• 縮寫列表
• 來源與參考文獻

Optical Measurement Market Size And Forecast

Optical Measurement Market size was valued at USD 5.66 Billion in 2023 and is projected to reach USD 9.76 Billion by 2030 , growing at a CAGR of 6.26% during the forecast period 2024-2030. Global Optical Measurement Market Drivers The market drivers for the Optical Measurement Market can be influenced by various factors. These may include: Technological developments: The adoption of optical measuring solutions across industries has been fueled by improvements in measurement speed, precision, and dependability brought about by developments in optical measurement technologies, such as 3D scanning, laser interferometry, and photogrammetry.

Demand for Precision Measurement:

To guarantee quality, performance, and standard compliance, industries including aerospace, automotive, electronics, and healthcare need to measure components, parts, and surfaces precisely. For these applications, optical measurement instruments are indispensable because of their great accuracy and resolution.

Non-contact Measurement:

The use of optical measurement techniques allows for non-destructive and non-contact measurement, which is especially useful for materials that are sensitive or delicate and for preventing contamination in sterile conditions. This feature encourages the use of optical measurement solutions in sectors where contact-based techniques might not be beneficial or feasible.

Automation and Industry 4.0:

Advanced measuring technologies are required for quality control, process optimization, and digital integration in the manufacturing sector due to the trend towards automation and Industry 4.0 efforts. Optical measurement systems facilitate accurate and efficient measurement in automated production environments. They are frequently coupled with robotics and other automation technologies.

Increasing Quality Requirements and Standards:

The need for increasingly advanced measuring systems to guarantee compliance and product quality is driven by rising industry standards and regulatory requirements, such as FDA regulations and ISO standards. The accuracy and dependability needed to fulfill these requirements are provided by optical measurement technology.

Extending Utilization in R&D:

Research and development endeavors in diverse domains, such as materials science, biomedical engineering, and geosciences, heavily rely on optical measurement methodologies. Optical measurement systems are widely used in R&D environments due to their adaptability, which makes them suitable for a variety of applications.

Cost and Performance Advantages:

Optical measurement systems can save money on setup, operation, and maintenance when compared to more conventional measurement techniques like tactile probes or coordinate measuring machines (CMMs). They also offer high-speed measurement capabilities, which boost productivity and efficiency in industrial settings.

Global Optical Measurement Market Restraints

Several factors can act as restraints or challenges for the Optical Measurement Market. These may include:

High Initial Investment:

Smaller businesses or organizations with tighter budgets may find it difficult to use optical measurement systems since they frequently demand a large initial investment in technology, equipment, and trained personnel.

Technology Complexity:

Optical measurement systems can be difficult to use and maintain, needing certain training and experience. This intricacy may make it harder for consumers to master new skills and may prevent widespread adoption.

Limited Accuracy in Certain Conditions:

Optical measurement techniques may not be as applicable in some industries or settings due to their limited ability to achieve high accuracy in certain environmental conditions, such as extreme temperatures, vibrations, or variations in lighting.

Regulatory Compliance:

Optical measuring organizations may find it difficult to comply with industry norms and standards, such as ISO standards for measurement accuracy, especially in industries where stringent quality control procedures are required.

Competition from Alternative Technologies:

Contact-based measurement systems, coordinate measuring machines (CMMs), laser scanning, and other alternative measurement technologies are competitors in the optical measurement sector. In some cases, these alternative technologies over optical measuring may be used due to their distinct advantages.

Difficulties with Data Processing and Interpretation:

Handling and analyzing massive amounts of data produced by optical measurement systems can be difficult and need for advanced methods for data processing and analysis. Businesses may encounter limitations with regard to the computational power and knowledge required for efficient data analysis.

Requirements for Maintenance and Calibration:

To guarantee accuracy and dependability, optical measurement systems need to undergo routine maintenance and calibration. Some businesses may find it difficult to fund maintenance and calibration activities due to the accompanying costs and downtime.

Security and Privacy Concerns:

These issues may serve as barriers in applications where optical measurement entails the collection and processing of sensitive data, such as biometric measurements or data from industrial processes, necessitating the implementation of strong safeguards to ensure data integrity and confidentiality.I

ntegration with Current Systems:

It can be difficult to integrate optical measurement systems with current workflows, procedures, and software systems, especially in sectors with proprietary or legacy infrastructure. Adoption may be hampered by compatibility problems and modification needs.

Global Optical Measurement Market Segmentation Analysis

The Global Optical Measurement Market is Segmented on the basis of Technology Type, Application, Product Type and Geography.

Optical Measurement Market, By Technology Type

• Laser-based Measurement:
• Utilizes laser beams for precise measurement of distances, dimensions, and angles.
• Spectroscopy: Analyzes the interaction between matter and electromagnetic radiation to identify materials or quantify their properties.
• Interferometry:
• Measures small displacements, refractive index changes, or surface irregularities by analyzing interference patterns.
• Imaging Systems:
• Capture visual data to analyze and measure objects or environments.
• Non-contact Measurement:
• Techniques that do not require physical contact with the object being measured, often employing light or electromagnetic waves.

Optical Measurement Market, By Application

• Industrial Manufacturing:
• Measurement solutions applied in various manufacturing processes for quality control, inspection, and precision.
• Automotive:
• Measurement technologies used in automotive manufacturing for quality assurance, dimensional accuracy, and assembly.
• Aerospace and Defense:
• Measurement systems employed in the aerospace and defense industries for precision engineering, inspection, and testing.
• Healthcare and Life Sciences:
• Optical measurement tools used in medical imaging, diagnostics, and research applications.
• Electronics and Semiconductor:
• Measurement solutions for ensuring quality, reliability, and precision in electronics and semiconductor manufacturing.
• Energy and Utilities:
• Applications of optical measurement in energy production, distribution, and infrastructure maintenance.

Optical Measurement Market, By Product Type

• Coordinate Measuring Machines (CMM):
• Automated measurement systems for dimensional inspection of objects.
• Optical Digitizers and Scanners (ODS):
• Devices for capturing and digitizing physical objects into 3D models or data.
• Vision Systems:
• Automated systems for visual inspection, measurement, and analysis.
• Optical Comparators:
• Devices for comparing the dimensions of a part to its original design using optical principles.
• Optical Micrometers:
• Instruments for precise measurement of small distances or dimensions using optical techniques.
• Laser Trackers:
• High-precision measurement systems using laser technology to track and measure positions in 3D space.

Optical Measurement Market, By Geography

• North America:
• Market conditions and demand in the United States, Canada, and Mexico.
• Europe:
• Analysis of the OPTICAL MEASUREMENT MARKET in European countries.
• Asia-Pacific:
• Focusing on countries like China, India, Japan, South Korea, and others.
• Middle East and Africa:
• Examining market dynamics in the Middle East and African regions.
• Latin America
• : Covering market trends and developments in countries across Latin America.

Key Players

• The major players in the Optical Measurement Market are:
• Hexagon Metrology (Sweden)
• Nikon Instruments (Japan)
• Mitutoyo Corporation (Japan)
• GOM mbH (Germany)
• FARO Technologies (US)
• Keyence Corporation (Japan)
• Carl Zeiss (Germany)
• Jenoptik (Germany)
• Zygo Corporation (US)
• Vision Engineering (UK)
• KLA-Tencor Corporation (US)
• Perceptron Inc. (US)
• Breuckmann GmbH (Germany)
• Steinbichler Optotechnik GmbH (Germany)
• Nova Measuring Instruments Ltd. (UK)
• Quality Vision International Pvt. Ltd. (India)
• Creaform (Canada)
• Third Dimension (US)
• Micro-Vu Corp (US)
• ST Industries Inc. (US)
• Nanometrics Incorporated (US)
• Carl Zeiss Meditec AG

TABLE OF CONTENTS

1. Introduction

• Market Definition
• Market Segmentation
• Research Methodology

2. Executive Summary

• Key Findings
• Market Overview
• Market Highlights

3. Market Overview

• Market Size and Growth Potential
• Market Trends
• Market Drivers
• Market Restraints
• Market Opportunities
• Porter's Five Forces Analysis

4. Optical Measurement Market, By Technology Type

• Laser-based Measurement
• Spectroscopy
• Interferometry
• Imaging Systems
• Non-contact Measurement

5. Optical Measurement Market, By Application

• Industrial Manufacturing
• Automotive
• Aerospace and Defense
• Healthcare and Life Sciences
• Electronics and Semiconductor
• Energy and Utilities

6. Optical Measurement Market, By Product Type

• Coordinate Measuring Machines (CMM)
• Optical Digitizers and Scanners (ODS)
• Vision Systems
• Optical Comparators
• Optical Micrometers
• Laser Trackers

7. Regional Analysis

• North America
• United States
• Canada
• Mexico
• Europe
• United Kingdom
• Germany
• France
• Italy
• Asia-Pacific
• China
• Japan
• India
• Australia
• Latin America
• Brazil
• Argentina
• Chile
• Middle East and Africa
• South Africa
• Saudi Arabia
• UAE

8. Market Dynamics

• Market Drivers
• Market Restraints
• Market Opportunities
• Impact of COVID-19 on the Market

9. Competitive Landscape

• Key Players
• Market Share Analysis

10. Company Profiles

• Hexagon Metrology (Sweden)
• Nikon Instruments (Japan)
• Mitutoyo Corporation (Japan)
• GOM mbH (Germany)
• FARO Technologies (US)
• Keyence Corporation (Japan)
• Carl Zeiss (Germany)
• Jenoptik (Germany)
• Zygo Corporation (US)
• Vision Engineering (UK)
• KLA-Tencor Corporation (US)
• Perceptron Inc. (US)
• Breuckmann GmbH (Germany)
• Steinbichler Optotechnik GmbH (Germany)
• Nova Measuring Instruments Ltd. (UK)
• Quality Vision International Pvt. Ltd. (India)
• Creaform (Canada)
• Third Dimension (US)
• Micro-Vu Corp (US)
• ST Industries Inc. (US)
• Nanometrics Incorporated (US)
• Carl Zeiss Meditec AG

11. Market Outlook and Opportunities

• Emerging Technologies
• Future Market Trends
• Investment Opportunities

12. Appendix

• List of Abbreviations
• Sources and References