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Sophisticated acquisition drivers for all current interfaces like USB3 Vision, GigE Vision, Camera Link, CoaXPress etc. What is new in Common Vision Blox 2020? The new release CVB 2020 offers innovative functions for extremely flexible and unsurpassed possibilities for image acquisition.

  • GigE Vision is an interface standard introduced in 2006 for high-performance industrial cameras. It provides a framework for transmitting high-speed video and related control data over Ethernet networks.
  • ResearchAndMarkets.com Laura Wood, Senior Press Manager press@researchandmarkets.com For E.S.T Office Hours Call 1-917-300-0470 For U.S./CAN Toll Free Call 1-800-526-8630 For GMT Office.
  • Press release - Market Insights Reports - 3D Tsv Devices Market:Study Navigating the Future Trends Outlook Prominent Players: Teledyne DALSA, STATS ChipPAC, Micron Technology, Samsung.

DUBLIN--(BUSINESS WIRE)--The 'X-Ray Detector Market by Type and Application: Global Opportunity Analysis and Industry Forecast, 2020-2027' report has been added to ResearchAndMarkets.com's offering.

The global X-ray detector market was valued at $5. 12 billion in 2019, and is projected to reach $8. 87 billion by 2027, registering a CAGR of 6. 4% from 2020 to 2027.

X-ray detectors are the devices which are used to measure the flux, spatial distribution, spectrum, and other properties of X-rays. When X-rays travelling through the body, it also passes through an X-ray detector on the other side of the patient and formed an image. There are different types of X-ray detectors such as flat panel detectors (FPDs), charge-coupled device detectors (CCDs), line scan detector, and computed radiography plates/cassettes. These are used for the various application including medical, veterinary, security, dental, and industrial.

Major factors that affects the growth of the global X-ray detector market are The rise in demand for digital imaging technologies, advantages of digital X-ray detectors, and favorable reimbursement policies for X-rays drive growth of the global X-ray detector market. However, high cost associated with digital x-ray detectors and lack of skilled professionals restrain the market growth. On the contrary, The rise in demand for wireless X-ray detectors and growth in medical tourism in developing countries are expected to offer significant growth opportunities for the players in the near future.

The global X-ray detector market is segmented into type, application, and region. By type, the market is segmented into flat panel detectors (FPDs), charge-coupled device detectors (CCDs), line scan detector, and computed radiography plates/cassettes. Further, the flat panel detectors segment is sub-divided into indirect capture FPDs and direct capture FPDs. In addition, the flat panel detectors segment is also categorized, on the basis of panel size, into small area FPDs and large area FPDs. By application, the market is segmented into medical, veterinary, security, dental, and industrial. Moreover, the medical segment is divided into static imaging and dynamic imaging. Furthermore, static imaging is categorized on the basis of indication into oncology and others. Region wise, the market analyzed across North America, Europe, Asia-Pacific, and LAMEA.

Key Benefits

  • This report provides a detailed quantitative analysis of the current X-ray detector market trends and future estimations from 2020 to 2027, which assists to identify the prevailing market opportunities.
  • An in-depth analysis of various regions is anticipated to provide a detailed understanding of the current trends to enable stakeholders to formulate region-specific plans.
  • A comprehensive analysis of the factors that drive and restrain the growth of the global X-ray detector market is provided.
  • An extensive analysis of various regions provides insights that allow companies to strategically plan their business moves.

Market Dynamics

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Drivers

  • Growth in Demand for Digital Imaging Technologies
  • Advantages of Digital X-Ray Detectors
  • Favorable Reimbursement Policy for X-Rays

Restraint

  • High Cost Associated With Digital X-Ray Detectors

Opportunity

  • The Rise in Demand for Wireless X-Ray Detectors
  • Growth in Medical Tourism in Developing Countries

Key Market Players

  • Agfa-Gevaert N. V.
  • Analogic Corporation (Altaris Capital Partners, LLC)
  • Canon, Inc.
  • Carestream Health, Inc.
  • Comet Holding (YXLON International GmbH)
  • Detection Technology Plc.
  • Fujifilm Holdings Corporation (Fujifilm Medical Systems)
  • General Electric
  • Konica Minolta Holdings Inc.
  • Koninklijke Philips N. V.
  • Siemens AG
  • Teledyne Technologies Incorporated (Teledyne DALSA, Inc. )
  • Thales Group (Trixell)
  • Varex Imaging Corporation

Other Players

  • Agilent Technologies
  • Hamamatsu Photonics K. K.
  • Vieworks Co., Ltd.
  • Rayence Inc.

For more information about this report visit https://www.researchandmarkets.com/r/mb0xf7

(Redirected from GigE vision)
GigE vision logo

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GigE Vision
TypeIncentive
IndustryVision
Founded2006
United States
HeadquartersUnited States

GigE Vision[1] is an interface standard introduced in 2006 for high-performance industrial cameras. It provides a framework for transmitting high-speed video and related control data over Ethernet networks. The distribution of software or development, manufacture or sale of hardware that implement the standard, require the payment of annual licensing fees.[2] The standard was initiated by a group of 12 companies, and the committee has since grown to include more than 50 members.[3] The 12 founding members were: Adimec, Atmel, Basler AG, CyberOptics, Teledyne DALSA, JAI A/S, JAI PULNiX, Matrox, National Instruments, Photonfocus, Pleora Technologies and Stemmer Imaging. The Automated Imaging Association (AIA)[4] oversees the ongoing development and administration of the standard.

GigE Vision is based on the Internet Protocol standard. One goal is to unify current protocols for industrial cameras. The other is to make it easier for 3rd party organizations to develop compatible software and hardware.

GigE Vision is not an open protocol, and as such a special license is required to develop GigE camera drivers.

Technology[edit]

GigE Vision has four main elements:

  • GigE Vision Control Protocol (GVCP)—Runs on the UDP protocol. The standard defines how to control and configure devices. Specifies stream channels and the mechanisms of sending image and configuration data between cameras and computers.
  • GigE Vision Stream Protocol (GVSP)—Runs on the UDP protocol. Covers the definition of data types and the ways images can be transferred via GigE.
  • GigE Device Discovery Mechanism—Provides mechanisms to obtain IP addresses.
  • XML description file based on a schema defined by the European Machine Vision Association's GenICam standard that allows access to camera controls and image streams.[5]

See also[edit]

References[edit]

  1. ^GigE Vision Standard
  2. ^http://www.visiononline.org/vision-standards-details.cfm?id=141&type=5
  3. ^GigE Vision Standard Development Committee
  4. ^About AIA
  5. ^GenICam™ standard home pageArchived 2012-10-11 at the Wayback Machine

External links[edit]

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