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影響應用的新興技術的CBRNE(化學/生物/放射性物質/核/炸藥)增長機會

Growth Opportunities of Emerging Technologies Impacting CBRNE Applications

出版商 Frost & Sullivan 商品編碼 979063
出版日期 內容資訊 英文 76 Pages
商品交期: 最快1-2個工作天內
價格
影響應用的新興技術的CBRNE(化學/生物/放射性物質/核/炸藥)增長機會 Growth Opportunities of Emerging Technologies Impacting CBRNE Applications
出版日期: 2020年11月30日內容資訊: 英文 76 Pages
簡介

化學,生物,放射性,核爆炸性(CBRNE)威脅物質檢測系統的機會主要是由恐怖襲擊的威脅日益增加所驅動的。

本報告調查化學,生物,放射性,核能和爆炸性(CBRNE)技術及其機遇,並宣傳該技術的重要性和影響以及CBRNE技術在私人市場中的機遇。它分析了當前的趨勢和發展,支持CBRNE威脅檢測的各種新技術的功能等。

目錄

戰略勢在必行

  • Strategic Imperative 8
  • 關於Growth Pipeline Engine
  • 成長機會助推Growth Pipeline Engine

第1章執行摘要

  • 技術/創新研究的範圍
  • 調查方法
  • 調查過程/調查方法
  • 主要發現摘要
  • 啟用技術對CBRNE市場的影響

第2章技術狀況:CBRNE技術的現狀

  • CBRNE技術狀況:概述
  • 提高安全性和系統小型化的奈米技術是CBRNE應用的趨勢
  • 智慧城市的實現和彈性電子在CBRNE中的作用
  • 增強CBRNE應用的技術
  • 無人機技術對CBRNE應用的影響
  • 機器人技術,傳感器和可穿戴技術對CBRNE應用的影響
  • CBRNE檢測系統在全球市場中的機會

第3章評估應用程序對CBRNE的影響

  • 急救人員在CBRNE檢測中的作用和重要性
  • 軍事和平民在CBRNE應用中的作用
  • 第一響應者在CBRNE應用程序中共享一個公共空間
  • IFAFRI的第一響應者能力差距
  • IFAFRI第一響應者能力差距的潛在解決方案
  • CBRN培訓網絡和歐盟CBRN卓越中心
  • 無人機對CBRNE應用的影響分析
  • CBRNE應用程序中的傳感器影響分析
  • CBRNE應用程序的主要應用程序
  • 分析納米傳感器對CBRNE應用的影響
  • 太赫茲成像在CBRNE應用中的影響分析
  • 分析生物傳感器對CBRNE應用的影響
  • CBRNE應用程序中的伽馬相機影響分析
  • SiPR伽馬探測器的重要性和重大發展
  • 機器人工程在CBRNE應用中的影響分析
  • 緊急操作機器人解決方案的案例研究
  • 對CBRNE應用程序的可穿戴影響分析
  • 分析軟件/模擬器對CBRNE應用程序的影響
  • CBRNE檢測應用程序的主要標準
  • CBRNE應用的第一響應者的主要標準
  • CBRNE應用的主要歐盟標準
  • 促進CBRNE應用的主要政府計劃和舉措
  • 歐洲的重大發展和倡議
  • 針對CBRNE應用的主要歐盟項目

第4章主要工業計劃/利益相關者生態系統

  • 用於CBRNE應用的無人機的重大發展
  • CBRNE應用探測器的重大發展
  • 用於CBRNE檢測的軟件/模擬器的重大發展
  • 機器人工程技術的重大發展以支持應急人員
  • 支持平民和急救人員的傳感器的重大發展
  • 用於監測放射性物質的伽馬探測器的重大發展
  • CBRNE用於威脅檢測的可穿戴設備的重大發展
  • 歐盟,中東和亞太地區的主要發展
  • 輻射探測的一項重要創新,以支持平民

第5章專利趨勢和資金分析

  • 專利搜索的優先領域適合於傳感器設備的開發。
  • 推動CBRNE市場發展的融資趨勢和分析
  • 關鍵供資重點和舉措
  • 歐盟地區的主要資金優先事項和計劃

第6章增長機會和戰略見識

  • 增強的CBRNE威脅感知增長機會
  • COVID-19對CBRNE應用程序的影響
  • 戰略見解:關鍵成功因素

第7章主要聯繫信息

下一步

目錄
Product Code: D9C8

Sensors, Drones, Robotics, and Wearables Drive Opportunities in the CBRNE Industry

Opportunities for chemical, biological, radiological, nuclear, and explosive (CBRNE) threat agent detection systems are being largely driven by increasing threats of terrorist attacks.

Chemical threats involve use of harmful and toxic industrial chemicals or materials and release of poisonous gases. Biological threats include premeditated attacks by deliberately releasing hazardous bioagents, such as, biological toxins. Nuclear and radiological attacks pose an enormous menace and will result in catastrophic losses.

There are also needs and opportunities for improved ability to determine the chemical attribution signature (CAS) of chemical threat agents, trace the origins of toxic chemicals and related materials to their source, and to enhance sample collection and preservation of CAS at the scene.

CBRNE agents cause intense damage that could lead to mass civilian casualties, economic degradation, demolition of critical infrastructure, and contamination of large areas.

Key Questions Answered in the Technology and Innovation Study:

  • What is the significance of CBRNE technology and its impact?
  • What are the current trends and developments that are driving the opportunities for CBRNE technologies in the civilian market?
  • What are the technology capabilities of various emerging technologies boosting the CBRNE threat detection?

Key innovations and their application impact:

  • IP and Funding scenario
  • Growth opportunities and critical success factors
  • What sort of strategies do OEMs need to embrace to gain entry and sustain in the competitive marketplace?

Table of Contents

Strategic Imperatives

  • The Strategic Imperative 8™
  • The Strategic Imperative 8™
  • About the Growth Pipeline Engine™
  • Growth Opportunities Fuel the Growth Pipeline Engine™

Chapter 1.0 - Executive Summary

  • 1.1 Scope of the Technology and Innovation Research
  • 1.2 Research Methodology
  • 1.3 Research Process and Methodology
  • 1.4 Summary of the Key Findings
  • 1.5 Impact of Enabling Technologies in CBRNE Market

Chapter 2.0 - Technology Landscape - Current State of CBRNE Technology

  • 2.1 CBRNE Technology Landscape - An Overview
  • 2.2 Push for Enhanced Safety Nanotechnology and System Miniaturization are Trending CBRNE Applications
  • 2.3 Enabling Smart Cities and Role of Stretchable Electronics in CBRNE
  • 2.4 Enabling Technologies Empowering CBRNE Applications
  • 2.5 Impact of Drone Technology in CBRNE Applications
  • 2.6 Impact of Robotics, Sensor, and Wearable Technologies in CBRNE Applications
  • 2.7 Global Market opportunities of CBRNE Detection Systems

Chapter 3.0 - Application Impact Assessment on CBRNE

  • 3.1 Role and Significance of First Responders for CBRNE Detection
  • 3.2 Role of Military Personnel and Civilian in CBRNE Applications
  • 3.3 First Responders Sharing a Common Space in CBRNE Applications
  • 3.4 IFAFRI's First Responders Capability Gaps
  • 3.5 Potential Solutions for IFAFRI's First Responders Capability Gaps
  • 3.6 CBRN training networks and EU CBRN Centres of Excellence
  • 3.7 Impact Analysis of Drones in CBRNE Applications
  • 3.8 Impact Analysis of Sensors in CBRNE Applications
  • 3.9 Key Applications of CBRNE Applications
  • 3.10 Impact Analysis of Nanosensors in CBRNE Applications
  • 3.11 Impact Analysis of Terahertz Imaging in CBRNE Applications
  • 3.12 Impact Analysis of Biosensors in CBRNE Applications
  • 3.14 Impact Analysis of Gamma camera in CBRNE Applications
  • 3.15 Significance and Key Developments in SiPR Gamma Detectors
  • 3.16 Impact Analysis of Robotics in CBRNE Applications
  • 3.17 Case Studies of Robotic Solutions for Emergency Operations
  • 3.18 Impact Analysis of Wearable in CBRNE Applications
  • 3.19 Impact Analysis of Software/Simulator in CBRNE Applications
  • 3.20 Key Standards for CBRNE Detection Applications
  • 3.21 Key Standards for First Responder in CBRNE Applications
  • 3.22 Key EU Standards for CBRNE Applications
  • 3.22 Key EU Standards for CBRNE Applications (continued)
  • 3.23 Key Government Programs and Initiatives Driving CBRNE Applications
  • 3.24 Key Developments and Initiatives from Europe Region
  • 3.25 Key EU Projects in CBRNE Application
  • 3.25 Key EU Projects in CBRNE Application (Continued)

Chapter 4.0 - Key Industry Initiative & Stakeholder Ecosystem

  • 4.1 Key Developments in Drones for CBRNE Applications
  • 4.2 Key Developments in Detectors for CBRNE Applications
  • 4.3 Key Developments in Software/Simulators for CBRNE Detection
  • 4.4 Key Developments in Robotics Assisting Emergency Responders
  • 4.5 Key Developments in Sensors Aiding Civilians and First Responders
  • 4.6 Key Developments in Gamma Detectors for Monitoring Radioactive Materials
  • 4.7 Key Developments in Wearable for CBRNE Threat Detections
  • 4.8 Key Developments in EU, Middle East, and APAC Regions
  • 4.9 Key Innovations in Radiation Detection Aiding Civilians

Chapter 5.0 - Patent Trends and Funding Analysis

  • 5.1 Patent Research Focus Areas are More Toward Development of Sensor Devices
  • 5.2 Funding Trends and Analysis Empowering CBRNE Market
  • 5.3 Key Funding Focus Areas and Initiatives
  • 5.4 Key Funding Focus Areas and Initiatives in EU REGION

Chapter 6.0 - Growth Opportunities and Strategic Insights

  • 6.1 Growth Opportunities for Enhanced CBRNE Threat Sensing
  • 6.2 Impact of COVID-19 in CBRNE Applications
  • 6.3 Strategic Insights - Critical Success Factors

Chapter 7.0 - Key Contacts

  • 7.1 Key Contacts

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