LiDAR 感测器市场 - 2024 年至 2029 年预测

LiDAR 感测器市场估计值将从 2024 年的 36.67 亿美元增至 2029 年的 76.35 亿美元，在预测期内年复合成长率(CAGR)为 15.80%。

为了因应全球人口成长，特别是开发中国家的人口成长，设计和土木建筑计画的规模和范围显着增加。建造的各个观点，从测绘到进行风险可行性研究，都需要增加技术援助。光达创新已发展成为一种有价值的设备，可以对广大区域提供准确的逐点研究。此外，工程师依靠全球定位系统 (GPS) 驱动的雷射扫描器和高灵敏度相机来创建满足扩展假设并促进准确的可行性评估的设计。为了因应这一趋势，各光达供应商正在扩大业务。

印度的目标是巩固基础，以实现 2025 年美国金融发展达到 5 兆美元的目标。作为国家基础设施管道（NIP）的一部分，各种大型计划目前正处于不同的实施阶段。 NIP计画在2020年至2025年间分配1.4兆美元的大规模风险预算用于基础设施发展，其中很大一部分分配给各个领域。其中可再生能源项目占24%，公路及高速公路项目占18%，都市开发案占17%，铁路开发案占12%。

此外，与石油天然气和采矿程序等行业的传统方法相比，科学家和测绘专家正在使用雷射雷达技术来提高准确性、精密度和多功能性，并提高人造和采矿作业的准确性、准确性和多功能性。在印度，运输部已强制要求在建造新高速公路之前使用光达系统进行测量。

NRSC（国家遥感探测中心）使用两台航空数位相机，Vexcel 的 ULTRACAM-D 和 ULTRACAM Eagle，可撷取空间解析度高达 5 公分的大尺寸数位相机影像（PAN、RGB、NIR）。此外，NRSC还采用了徕卡的两款雷射雷达系统：ALS50-II和ALS70-HP。这些系统具有内建数位相机，可与雷射测距并行执行光学成像。两款装置的工作波长均为1064nm。这些研究由 NRSC 进行，用于为城市、林业和水文应用创建高精度数位表面模型 (DSM) 和数位地形模型 (DTM)，以及为采矿作业和走廊规划创建精确的体积模型它有多种用途，包括分析、为电子化政府创建2D/3D资料库以及为规划目的提供 3D 视觉化。

政府增加对国防能力的投资支持市场扩张

LiDAR 感测器透过提供情境察觉、监视和目标捕获的先进功能，在国防工业中发挥至关重要的作用。这些感测器利用雷射脉衝在各种环境条件下（包括照度和恶劣天气场景）准确识别、追踪和识别物体。在国防应用中，LiDAR 感测器整合到无人机 (UAV)、地面车辆和监视框架中，以组装有关区域测绘、敌人位置和潜在危险的即时资讯。该技术使军队能够做出快速、明智的选择，从而提高作战相关性并提高作战情况下的整体任务获胜率。

拟议的国防部 (DoD) 2023 财年预算为 7,730 亿美元，比 2022 财年 7,423 亿美元的製裁基准水准增加 307 亿美元，即 4.1%，比 2022 财年要求的水准增加 8.1%。与 2021 财年的水准相比，2023 财年的请求在两年内增加了约 700 亿美元（9.8%）。

基于脉衝/线性模式的框架预计将在预期时间内占据重要的市场占有率。

线性模式或基于脉衝的 LIDAR（光检测和测距）系统使用短时雷射脉衝来测量物体与周围环境的距离。这些系统支援即时障碍物识别和安全导航，包括无人驾驶汽车等多种应用。

基于脉衝的雷射雷达是自动驾驶汽车 (AV) 查看环境并即时侦测阻碍力、行人和其他车辆的基础。扩大自动驾驶创新取决于这种确保安全路线和高效防撞程序的能力。例如，2023 年 10 月，英国政府保证额外供应 1 亿英镑，以支援自动驾驶汽车 (AV) 的逐步改进。其当前的安全目标是让自动驾驶汽车与熟练的人类协调员一样安全。

此外，交通运输洞察局预计汽车产量将从 2020 年的 8,818,000 辆增加到 2021 年的 9,157,000 辆。此外，国内销量将从2020年的11,571,000辆增加到2021年的11,831,000辆。这一成长对整体市场扩张产生了重大影响。

基于脉衝的雷射雷达还可用于环境监测、土木工程计划、考古调查、精密农业和农业作物监测。基于脉衝的雷射雷达的准确性和适应性使其成为提高快速决策和推进各个领域技术的重要工具。

根据 MGI（2011）的数据，到 2030 年，城市预计将占印度 GDP 的 70%。

印度建筑市场分为250子部门，每个产业之间都有连结。为了开创印度建筑技术产业的新时代，PMAY-U 提交的材料选出了 54 项全球创新建筑技术。在 SBM-U 框架下，1,191 个城市获得了 ODF++ 认证，超过 3,500 个城市获得了 ODF+ 认证。拟建的 35 个多式联运物流园区 (MMLP) 总资本支出达 61 亿美元，将处理 50% 的货运量。

在其他领域，在军事领域，基于脉衝或线性模式的 LIDAR 设备可提供精确的 3D 空间资料，从而实现先进的目标识别和侦察能力。这些设备透过帮助准确识别和追踪感兴趣的项目来提高情境察觉和任务规划。此外，基于脉衝的雷射雷达增强了地理亮点的测绘，提高了军事行动和关键决策的可行性。

此外，根据中央情报局的报告，2021 年阿根廷的军事支出占 GDP 的 0.8%，2019 年占 GDP 的 0.7% 左右。这笔支出主要用于设备中使用的感测器。

总体而言，由于国防、农业和汽车行业等各个行业的需求不断增长，脉衝或线性模式雷射雷达系统市场正在迅速扩大。此外，技术发展正在提高效率并降低价格，为公司提供提供创新产品和扩大产品范围的重大机会。

主要市场开拓：

• 2022 年 1 月，美国专利商标局授予 Woolpert 一项「机载 Topo-Bathy 雷射雷达系统及其方法」专利。有吸引力的研究和开发团队正在利用这些创新来开发雷射雷达，它可以覆盖更广泛的范围，并在比最近构建的感测器框架更明显的高度处收集高解析度地形和测深资讯。

目录

第一章简介

• 市场概况
• 市场定义
• 调查范围
• 市场区隔
• 货币
• 先决条件
• 基准年和预测年时间表
• 相关人员的主要利益

第二章调查方法

• 研究设计
• 调查过程

第三章执行摘要

• 主要发现
• 分析师观点

第四章市场动态

• 市场驱动因素
• 市场限制因素
• 波特五力分析
• 产业价值链分析

第五章 LiDAR 感测器市场：按感测器类型

• 介绍
• 空气
  • 地形
  • 水深
• 地上
  • 智慧型手机
  • 静止的

第六章 LiDAR 感测器市场：依系统类型

• 介绍
• 脉衝基/线性模式系统
• 基于相位的系统
• 盖格模式/光子计数系统

第七章 LiDAR 感测器市场：依产业分类

• 介绍
• 农业
• 基础设施/建筑
• 军事/国防
• 环境
• 矿业
• 运输
• 其他的

第八章 LiDAR 感测器市场：按地区

• 介绍
• 北美洲
  • 依感测器类型
  • 依系统类型
  • 按行业分类
  • 按国家/地区
• 南美洲
  • 依感测器类型
  • 依系统类型
  • 按行业分类
  • 按国家/地区
• 欧洲
  • 依感测器类型
  • 依系统类型
  • 按行业分类
  • 按国家/地区
• 中东/非洲
  • 依感测器类型
  • 依系统类型
  • 按行业分类
  • 按国家/地区
• 亚太地区
  • 依感测器类型
  • 依系统类型
  • 按行业分类
  • 按国家/地区

第九章竞争环境及分析

• 主要企业及策略分析
• 市场占有率分析
• 合併、收购、协议和合作
• 竞争对手仪表板

第十章 公司简介

• SICK AG
• Infineon Technologies AG
• Leica Geosystems AG
• Velodyne LiDAR, Inc.
• Quanergy Systems, Inc.
• Hitachi, Ltd.
• LeddarTech Inc.
• Neptec Technologies Corp
• Innoviz Technologies, Ltd.

The LiDAR Sensor market is anticipated to grow at a compound annual growth rate (CAGR) of 15.80% over the forecast period to reach US$7.635 billion by 2029, increasing from estimated value of US$3.667 billion in 2024.

There has been a noteworthy rise in the scale and degree of designing and civil construction ventures to oblige the growing population on the global scale, especially in developing nations. Each perspective of construction, extending from surveying and mapping to carrying out venture achievability studies, requires an expanding level of technological help. LiDAR innovations have developed as a profitable device, offering exact and point-by-point studies of tremendous regions. Besides, engineers depend on global positioning system (GPS)-aided laser scanners and profoundly delicate cameras to create designs that meet extended prerequisites and encourage precise possibility assessments. As a result of this drift, various LiDAR benefit providers have extended their operations.

India is aiming to boost its foundation to attain its financial development target of coming to US$5 trillion by 2025. As part of the National Infrastructure Pipeline (NIP), there are various large-scale projects right now in different stages of execution. The NIP designates a significant venture budget of $1.4 trillion towards foundation advancement, from 2020 to 2025, with a noteworthy portion designated to different segments. This incorporates 24% towards renewable energy ventures, 18% towards roads and highways, 17% towards urban development, and 12% towards railways development.

Further, LiDAR technology is utilized by scientists and mapping experts to analyze both artificial and natural landscapes with increased accuracy, precision, and versatility compared to previous methods in industries like oil and gas as well as in mining procedures. In India, the Ministry of Transportation has made it compulsory to utilize LiDAR systems for surveying areas prior to the construction of new highways.

The NRSC (National Remote Sensing Centre) utilizes two airborne digital cameras, namely the ULTRACAM-D and ULTRACAM Eagle manufactured by Vexcel, which are capable of capturing and delivering Large Format Digital Camera images (PAN, RGB, NIR) with spatial resolutions of up to 5 cm. Moreover, NRSC employed two LiDAR systems, namely the ALS50-II and ALS70-HP airborne laser scanners manufactured by Leica. These systems are equipped with integrated digital cameras to facilitate optical imaging alongside laser ranging. The operating wavelength for both instruments is 1064nm. These surveys conducted by NRSC serve various purposes, such as generating high-precision Digital Surface Models (DSM) and Digital Terrain Models (DTM) for urban, forestry, and hydrological applications, conducting accurate volumetric analysis for mining operations and corridor planning, generating 2D/3D Geodatabases for eGovernance, and providing 3D visualization for planning purposes.

Rising government investment in defense capabilities will bolster the market expansion

LiDAR sensors play a pivotal part within the defense industry by giving progressed capabilities for situational awareness, surveillance, and target procurement. These sensors utilize laser pulses to precisely identify, track, and recognize objects in different environmental conditions, including low-light and adverse climate scenarios. In defense applications, LiDAR sensors are coordinated into unmanned aerial vehicles (UAVs), ground vehicles, and surveillance frameworks to assemble real-time information on territory mapping, enemy positions, and potential dangers. This technology enables military faculty to make informed choices quickly, improve operational adequacy, and progress overall mission victory rates in combat circumstances.

The proposed budget for the Department of Defence (DoD) for FY 2023 is $773 billion, reflecting a $30.7 billion or 4.1 percent rise from the sanctioned base level of $742.3 billion in the FY 2022 and an 8.1 percent increment from the asked level in FY 2022. In comparison to the FY 2021 level, the FY2023 demand demonstrates an expansion of about $70 billion (9.8 percent) over a two-year span.

The pulse-based/linear-mode framework is anticipated to hold a substantial market share within the anticipated period.

A linear-mode or pulse-based LIDAR (light detection and ranging) system measures an object's distance from its surroundings by using brief laser pulses. Real-time obstacle identification and safe navigation are made possible by these systems which include diverse utilization such as driverless vehicles.

Pulse-based LIDAR is fundamental for autonomous vehicles (AVs) to see their environment and detect deterrents, pedestrians, and other vehicles in real-time. The expanding progression of self-driving innovation depends on this capacity, which ensures a secure route and productive collision avoidance procedures. For instance, in October 2023, the UK government guaranteed to supply an extra £100 million to back the progressing improvement of autonomous vehicles (AVs). The objective of its current security aim is for self-driving cars to be just as secure as a skilled human driver.

Besides, as per the estimates given by the Bureau of Transportation Insights, motor vehicle production expanded from 8,818 thousand in 2020 to 9,157 thousand in 2021. Moreover, domestic sales accounted increase from 11,571 thousand in 2020 to 11,831 thousand in 2021. This rise significantly impacts the overall market expansion.

Pulse-based LIDAR also helps with environmental monitoring, civil engineering projects, archaeological surveys, and precision farming and crop monitoring in agriculture. Pulse-based LIDAR's accuracy and adaptability make it a vital tool for a variety of sectors, s, improving quick decision making as well as advancing technology.

According to MGI (2011), cities are predicted to produce 70% of India's GDP by 2030.

India's construction market is divided into 250 subsectors and has connections between them. To usher in a new age in the Indian building technology industry, a sub-mission of PMAY-U has selected 54 globally innovative construction technologies. Under SBM-U, 1,191 localities have received ODF++ certification and over 3,500 cities have received ODF+ certification. 35 Multimodal Logistics Parks (MMLPs), which will be built at a total capital expenditure of $6.1 billion, will handle 50% of freight traffic.

Besides that, in the military, pulse-based or linear-mode LIDAR devices provide accurate 3D spatial data, enabling sophisticated target identification and reconnaissance capabilities. These devices improve situational awareness and mission planning by helping to accurately identify and track items of interest. Besides, pulse-based LIDAR bolsters the mapping of geographical highlights, which improves military operations' operational viability and vital decision-making.

Further, as per the Central Intelligence Agency report, Argentina's Military Spending was 0.8% of GDP in the year 2021 which was about 0.7% of GDP in 2019. The spending is majorly focused on the sensors being used in the equipment.

Overall, the pulse-based or linear-mode LIDAR systems market is expanding rapidly due to rising demand from a variety of industries, including the defense, agricultural, and automotive sectors. Furthermore, technological developments are increasing efficiency and lowering prices, giving businesses great chances to innovate and broaden their product offers.

Key Market Development:

• In January 2022, the United States Patent and Trademark Office awarded Woolpert a patent for his "Airborne Topo-Bathy Lidar System and Methods Thereof." An intriguing research and development group utilized these innovations to make a lidar sensor framework that can assemble high-resolution topographic and bathymetric information at a more prominent elevation, covering a more extensive range than lidar systems that have been built sometime recently.

Market Segmentation:

The Lidar Sensor Market is segmented and analyzed as below:

By Sensor Type

• Airborne
• Topographic
• Bathymetric
• Terrestrial
• Mobile
• Static

By System Type

• Pulse-based/Linear-mode System
• Phase-based System
• Geiger-mode/Photon-counting System

By Industry

• Agriculture
• Infrastructure and Construction
• Military and Defence
• Environment
• Mining
• Transport
• Others

By Geography

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

TABLE OF CONTENTS

1. INTRODUCTION

• 1.1. Market Overview
• 1.2. Market Definition
• 1.3. Scope of the Study
• 1.4. Market Segmentation
• 1.5. Currency
• 1.6. Assumptions
• 1.7. Base and Forecast Years Timeline
• 1.8. Key benefits for the stakeholders

2. RESEARCH METHODOLOGY

• 2.1. Research Design
• 2.2. Research Process

3. EXECUTIVE SUMMARY

• 3.1. Key Findings
• 3.2. Analyst View

4. MARKET DYNAMICS

• 4.1. Market Drivers
• 4.2. Market Restraints
• 4.3. Porter's Five Forces Analysis
  • 4.3.1. Bargaining Power of Suppliers
  • 4.3.2. Bargaining Power of Buyers
  • 4.3.3. Threat of New Entrants
  • 4.3.4. Threat of Substitutes
  • 4.3.5. Competitive Rivalry in the Industry
• 4.4. Industry Value Chain Analysis

5. LIDAR SENSOR MARKET BY SENSOR TYPE

• 5.1. Introduction
• 5.2. Airborne
  • 5.2.1. Topographic
  • 5.2.2. Bathymetric
• 5.3. Terrestrial
  • 5.3.1. Mobile
  • 5.3.2. Static

6. LIDAR SENSOR MARKET BY SYSTEM TYPE

• 6.1. Introduction
• 6.2. Pulse-based/Linear-mode System
• 6.3. Phase-based System
• 6.4. Geiger-mode/Photon-counting System

7. LIDAR SENSOR MARKET BY INDUSTRY

• 7.1. Introduction
• 7.2. Agriculture
• 7.3. Infrastructure and Construction
• 7.4. Military and Defence
• 7.5. Environment
• 7.6. Mining
• 7.7. Transport
• 7.8. Others

8. LIDAR SENSOR MARKET BY GEOGRAPHY

• 8.1. Introduction
• 8.2. North America
  • 8.2.1. By Sensor Type
  • 8.2.2. By System Type
  • 8.2.3. By Industry
  • 8.2.4. By Country
    • 8.2.4.1. United States
    • 8.2.4.2. Canada
    • 8.2.4.3. Mexico
• 8.3. South America
  • 8.3.1. By Sensor Type
  • 8.3.2. By System Type
  • 8.3.3. By Industry
  • 8.3.4. By Country
    • 8.3.4.1. Brazil
    • 8.3.4.2. Argentina
    • 8.3.4.3. Others
• 8.4. Europe
  • 8.4.1. By Sensor Type
  • 8.4.2. By System Type
  • 8.4.3. By Industry
  • 8.4.4. By Country
    • 8.4.4.1. United Kingdom
    • 8.4.4.2. Germany
    • 8.4.4.3. France
    • 8.4.4.4. Italy
    • 8.4.4.5. Others
• 8.5. Middle East and Africa
  • 8.5.1. By Sensor Type
  • 8.5.2. By System Type
  • 8.5.3. By Industry
  • 8.5.4. By Country
    • 8.5.4.1. Saudi Arabia
    • 8.5.4.2. UAE
    • 8.5.4.3. Israel
    • 8.5.4.4. Others
• 8.6. Asia Pacific
  • 8.6.1. By Sensor Type
  • 8.6.2. By System Type
  • 8.6.3. By Industry
  • 8.6.4. By Country
    • 8.6.4.1. Japan
    • 8.6.4.2. China
    • 8.6.4.3. India
    • 8.6.4.4. Australia
    • 8.6.4.5. Others

9. COMPETITIVE ENVIRONMENT AND ANALYSIS

• 9.1. Major Players and Strategy Analysis
• 9.2. Market Share Analysis
• 9.3. Mergers, Acquisitions, Agreements, and Collaborations
• 9.4. Competitive Dashboard

10. COMPANY PROFILES

• 10.1. SICK AG
• 10.2. Infineon Technologies AG
• 10.3. Leica Geosystems AG
• 10.4. Velodyne LiDAR, Inc.
• 10.5. Quanergy Systems, Inc.
• 10.6. Hitachi, Ltd.
• 10.7. LeddarTech Inc.
• 10.8. Neptec Technologies Corp
• 10.9. Innoviz Technologies, Ltd.