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futuristicpaintercat · 11 months ago

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Ethernet Switches and Routers Market to Prosper at a CAGR of 12% owing to Increasing Demand for High-Speed Network Infrastructure

Ethernet switches and routers form the core infrastructure of modern local area networks (LAN) and wide area networks (WAN). Ethernet switches allow devices to connect, transmit and receive data on a network by establishing connections between ports and forwarding data. Routers connect one or more networks together and determine the best path for network traffic to flow. They performs the vital function of packet forwarding which allows for seamless network connectivity. The growing demand for high-speed network connectivity in enterprises, data centers and telecommunication networks is fueling the growth of ethernet switches and routers market. Their ability to provide higher bandwidth, lower latency, greater reliability and flexibility are increasing their adoption. The Global Ethernet Switches and Routers Market is estimated to be valued at US$ 21.04 Bn in 2024 and is expected to exhibit a CAGR of 12% over the forecast period 2024 To 2031. Key Takeaways Key players in the Ethernet Switches and Routers market (100 words): Key players operating in the Ethernet Switches and Routers are Huawei Technologies Co. Ltd., ZTE Corp., Cisco Systems Inc., ADVA Optical Networking SE, Nokia Corporation, Ciena Corporation, Infinera Corporation, Fujitsu Ltd., ECI Telecom Ltd., Telefonaktiebolaget LM Ericsson, NEC Corporation, Juniper Networks Inc., Coriant GmbH, Huawei Marine Networks Co. Limited, NTT Electronics Corporation, Lumentum Operations LLC, Plaintree Systems Inc., Marben Products, Smartoptics AS, Shenzhen HiSilicon Technologies Co. Ltd. Key opportunities The rising demand for high bandwidth and seamless connectivity along with growing deployment of 4G/5G networks present significant growth opportunities. Advancements in Ethernet switch port densities, switching capacity, and new product introductions are anticipated to drive revenues. Increasing investments in data center interconnects, intelligent buildings, transportation infrastructure also open promising avenues. Global expansion Leading vendors are expanding their global footprint to tap growth opportunities across major world economies such as North America, Europe, APAC and Latin America. The market is witnessing a significant rise in cross border trade, international collaborations and M&A activities. This is positively impacting the worldwide expansion of Ethernet switches and routers industry. Market Drivers The primary driver propelling the Ethernet Switches And Routers Market Growth is the increasing demand for high-speed network connectivity from enterprises, data centers and telecom operators. This is encouraging large investments in high bandwidth networks worldwide. Furthermore, the rising adoption of advanced technologies like cloud computing, IoT, big data analytics and Industry 4.0 is generating a massive surge in network traffic. This is significantly boosting the requirement for ethernet switches and routers with higher port densities and performance. The ongoing transition toward virtualization and SDN/NFV is another key factor driving the adoption of new generation switches and routers with programmable functionality. Government initiatives to develop smart infrastructure and implement digital transformation agendas are also catalyzing market expansion.

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Ravina Pandya, Content Writer, has a strong foothold in the market research industry. She specializes in writing well-researched articles from different industries, including food and beverages, information and technology, healthcare, chemical and materials, etc. (https://www.linkedin.com/in/ravina-pandya-1a3984191)

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y2fear · 1 year ago

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Novos Fiber Partners With Smartoptics for Fiber Rollout in Texas

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smartoption · 3 years ago

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smartopt-blog · 6 years ago

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#smartopt #smart #opt # #android #tech #like #nikolaev #mykolayiv #iphone #airpods #apple #iphonexs (at Mykolayiv) https://www.instagram.com/p/B0A_ufNI-9l/?igshid=1si58f71hx0h5

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akankshastraitsresearch · 3 years ago

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#smartoptics #adaptive optics market research adaptive optics market report adaptive optics market research report #market research #market research reports

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altcoinmarketcap93-blog · 6 years ago

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10 Altcoins That Will Make You Money In 2019

Comments and very young talks bitcoin. Initiating a trade without a clear exit strategy is a recipe for disaster. Determine beforehand the price at which you'll cut your losses if the market moves contrary to expectations. This level is known as a stop-loss and it's critical to market survival. Limit your losses below 25% of your position size. A stop-loss is wisely placed on the other side of a level at which price has reversed previously, the more times the better. ICOs - Initial Coin Offerings are magnets to people that are new to the crypto trading market. This is because of the obvious reason: profit. ICOs promise people that their token will gain popularity if given enough time. Before investing money into newly released tokens make sure that you do a LOT of research before getting yourself fully engaged with what they have. However, even if these coins are riskier, they also have higher potential for growth. For example, OmiseGO (OMG), which started ranked 46th last July 23, 2017, was trading for $0.92 only. By Sept. 7, only 1.5 months after, it reached as high as $13.28. Most of these coins have been around for a few years, save for Bitcoin Cash and Bitcoin Gold, which are hard forks of Bitcoin. As such, large-caps are less risky to invest in, since most of them have been developed for a long time already, and a lot of investors already invest in these. The 5-10 crypto trading signals per week don't look much, but it is the overall package you get here. It is critical that traders usually tend to overtrade and CryptoMedics want to avoid this mistake for their users. The calls are very selected to only valuable ones with high reliability. The given altcoin signals (which are mostly based on a mix of technical analysis and fundamentals). Head Trader for the Altcoin department is Jakov, a seasoned crypto trader who knows his stuff very well (he published the Weekly Open Strategy on SmartOptions a while ago) - 100% accuracy months are not rare with his trades, but also his companion Alexander comes with nice altcoin trades. Two traders at your fingertips here, but there are even more for BitMEX signals.

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smitamaxi · 3 years ago

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Global Optical Transceiver Market Share, Size, Segmentation with Competitive Analysis, Top Manufacturers and Forecast 2021-2027

Global Optical Transceiver Market is expected to reach US$ 11.46 Bn by 2027, at a CAGR of 8.9% during the forecast period.

Global Optical Transceiver Market Overview:

Global Optical Transceiver Market: Report Scope the latest industry report on the Global Optical Transceiver Market assesses the opportunities and current market landscape, offering insights and updates on the corresponding segments for the forecasted period of 2021-2027. The report contains a complete analysis of major market dynamics as well as detailed information on the Global Optical Transceiver Market's structure. This market research report provides unique insights into how the Global Optical Transceiver market is expected to grow from 2021 to 2027.

The primary goal of the Global Optical Transceiver Market research is to provide detailed information on market opportunities that are assisting in the transformation of Global Optical Transceiver enterprise. Report provide projected growth rates along with the compound annual growth rate (CAGR) for forecasted period to enable readers to better understand the monitoring and assessment of the Global Optical Transceiver Market, as well as to discover lucrative opportunities in the market.

Request for free sample: https://www.maximizemarketresearch.com/request-sample/65410

Market Scope:

Maximize Market Research, report provide overall market insights for manufacturers, suppliers, distributors, and investors in the Global Optical Transceiver Market. The information and data offered in the report may be used by all stakeholders in the Global Optical Transceiver market, as well as industry professionals, researchers, journalists, and business researchers.

Maximize Market Research, report provides a unique research approach to conduct detailed research on the global Global Optical Transceiver Market and make conclusions on the market's future growth factors. Primary and secondary research methodologies are combined in the research approach to assure the authenticity and validity of the conclusions in this report.

The report discusses the Global Optical Transceiver Market's drivers, restraints, opportunities, and challenges. The research helps to identify the market growth drivers and determining how to utilize these factors as strengths. Restraints can assist readers in identifying traits that are restricting the Global Optical Transceiver market, as well as reducing them before they become an issue. This will assist readers in comprehending the aspects that will influence your ability to capitalise on possibilities.

Get more Report Details : https://www.maximizemarketresearch.com/market-report/global-optical-transceiver-market/65410/

Key Players:

• II-VI Incorporated • FIT Hong Teng Limited • Lumentum • Sumitomo Electric Industries Ltd • Accelink • Applied Optoelectronics • Fujitsu Optical Components • Innolight • Mellanox • NeoPhotonics • Ciena • Cisco • Hisense Broadband • Intel • NEC • Perle Systems • Reflex Photonics • Smartoptics • Solid Optics • Source Photonics

The competitive landscape shows the market share of major key competitors, as well as their key development plans and current financial performance over the previous five years. This information is anticipated to help businesses understand their competitors on a global level. Furthermore, the reports feature company profiles, product offers, critical financial data, country-level research, and a synthesis of demand and supply variables that influence market growth.

Regional Analysis:

Geographically, Global Optical Transceiver market report is segmented into several key regions are as follows,

Asia-Pacific (Vietnam, China, Malaysia, Japan, Philippines, Korea, Thailand, India, Indonesia, and Australia)

Europe (Turkey, Germany, Russia UK, Italy, France, etc.)

North America (the United States, Mexico, and Canada.)

South America (Brazil etc.)

The Middle East and Africa (GCC Countries and Egypt.)

Furthermore, the study covers market size, growth rate, import and export, as well as country-level analysis, integrating the demand and supply forces of the Global Optical Transceiver market in these countries, which are impacting market growth.

COVID-19 Impact Analysis on Global Optical Transceiver Market:

COVID-19's global influence on the Global Optical Transceiver market was examined in this research. During this crisis, the report examines the Global Optical Transceiver market's alternatives, demanding conditions, and difficult possibilities in detail. In terms of funding and market expansion, the paper briefly examines the COVID-19's merits and limitations. The study also contains a set of concepts that should aid readers in developing and planning company strategies.

The report considers consultations to overcome past disruptions and foresees potential ones in order to improve preparation. Businesses can use the frameworks to design their strategic alignments in order to recover from such disruptive trends. Maximize Market Research analysts can also assist readers in breaking down a complex circumstance and bringing resiliency to a situation that is uncertain.

About Us:

Maximize Market Research provides B2B and B2C research on 12000 high growth emerging opportunities & technologies as well as threats to the companies across the Healthcare, Pharmaceuticals, Electronics & Communications, Internet of Things, Food and Beverages, Aerospace and Defence and other manufacturing sectors.

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shashiemrf · 4 years ago

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Global Market of Optical Transceiver is Projected to Reflect a Moderate CAGR throughout 2025

Market Synopsis

In its research report, Market Research Future (MRFR), emphasizes that the global market 2020 is slated to grow exponentially over the assessment period, securing a significant market valuation and a healthy CAGR over the review period.

Drivers and Restraints

The optical transceiver market is slated to expand at a significant pace because of growth in fiber optical network adoption. The major factors driving the growth of the optical transceiver market include rising internet data traffic, increasing demand for smartphones and other smart devices, and increasing cloud-based services adoption. The business is, however, limited by the lack of network availability. At the other hand, the industry is witnessing several opportunities in developing cheaper and more effective transceivers, and development in the Internet of Things marketing. The optical transceiver market is expected to show significant growth rate and is expected to reach maturity by 2025.

Segmental Analysis

Based on the the fiber type, the market is bifurcated into Single-mode SFP, and multimode SFP

On the basis of data rate, the optical transceiver market is segmented into 40 to 100 Gbps, 10 to 40 Gbps, less than 10Gbps, more than 100 Gbps

On the basis of end-user, the optical transceiver market is divided into enterprises, telecommunication, and data centers

On the basis of form factor, the optical transceiver market is segmented into SFP28, SFP, SFP+, QSFP, CXP, QSFP+, CFP, QSFP28, and others

On the basis of configuration, the optical transceiver market is bifurcated into half-duplex and full-duplex mode.

Regional Analysis

The global business regional analysis was conducted in four major regions including Asia Pacific , North America, Europe and the rest of the world.

The market is currently highly dominated by North America amongst the regions listed above. North America is a technologically advanced area, and the growing advance in the field of optical networks marks the development of the demand for optical transceivers. Another explanation for North America's high market share is the growing proliferation of data centers and the consequent amount of unstructured data. In addition, the key vendors invest heavily in research & development are also helping the market to develop at an accelerated pace.

Asia Pacific has a large concentration of manufacturing companies that produce electronic components. Economic conditions have changed in countries such as India and China, where the government is taking initiatives to improve network infrastructure through the introduction of optical fiber networks and the development of data centers throughout the world. It is predicted that Asia Pacific will have the highest growth rate over the forecast period.

On the other hand, in terms of market share in the optical transceiver market Europe has successfully captured the second position. Europe is, along with North America, a technologically advanced country with developed economies such as Germany, the UK and France. However, Asia Pacific is slated to show the major growth rate during the forecast period.

Get Free Sample Report @ https://www.marketresearchfuture.com/sample_request/6066

Competitive Overview

The key market players operating in the global optical transceiver market as identified by MRFR are Lumentum Holdings Inc. (U.S.), Source Photonics, Inc (U.S.),Finisar Corporation (U.S.), Accelink Technologies Co., Ltd (China), Sumitomo Electric Industries, Ltd. (U.S.), Oclaro Inc. (U.S.), Foxconn Electronics Inc. (Taiwan), Fujitsu Optical Components Ltd. (Japan), NeoPhotonics Corporation (U.S.), Reflex Photonics Inc (Canada), among others.

Other vendors include Perle Systems (Canada), Smartoptics (Norway), FS.COM (U.S.), Broadcom Corporation (U.S.), Precision Optical Transceivers, Inc (U.S.), Curvature (U.S.), Ruckus Networks (U.S.), GBC Photonics (Poland), integra optics (U.S.), AimValley B.V. (The Netherlands), Moog Protokraft (U.S.), PennWell Corporation (U.S.) Laird Technologies, Inc (U.S.), PeakOptical (Denmark), Into Networks B.V. (the Netherlands), Sandstone Technologies Inc. (U.S.), Murata Manufacturing Co., Ltd (Japan), among others.

Table of Content:

4 Market Landscape

4.1 Porter’s Five Forces Analysis

4.1.1 Threat Of New Entrants

4.1.2 Bargaining Power Of Buyers

4.1.3 Threat Of Substitutes

4.1.4 Bargaining Power Of Suppliers

4.1.5 Segment Rivalry

4.2 Value Chain/Supply Chain Of Global Optical Transceiver Market

5 Overview Of Global Optical Transceiver Market

5.1 Introduction

5.2 Growth Drivers

5.3 Impact Analysis

5.4 Market Challenges

6 Market Trends

6.1 Introduction

6.2 Growth Trends

6.3 Impact Analysis

7. Global Optical Transceiver Market By Fiber Type

7.1 Introduction

7.2 Single-Mode SFP

7.2.1 Market Estimates & Forecast, 2020-2027

7.2.2 Market Estimates & Forecast By Region, 2020-2027

7.3 Multimode SFP

7.3.1 Market Estimates & Forecast, 2020-2027

7.3.2 Market Estimates & Forecast By Region, 2020-2027

8. Global Optical Transceiver Market By Data Rate

8.1 Introduction

8.2 Less Than 10Gbps

8.2.1 Market Estimates & Forecast, 2020-2027

8.2.2 Market Estimates & Forecast By Region, 2020-2027

8.3 10 To 40 Gbps

8.3.1 Market Estimates & Forecast, 2020-2027

8.3.2 Market Estimates & Forecast By Region, 2020-2027

8.4 40 To 100 Gbps

8.4.1 Market Estimates & Forecast, 2020-2027

8.4.2 Market Estimates & Forecast By Region, 2020-2027

8.5 More Than 100 Gbps

8.5.1 Market Estimates & Forecast, 2020-2027

8.5.2 Market Estimates & Forecast By Region, 2020-2027

9. Global Optical Transceiver Market By End-User

9.1 Introduction

9.2 Telecommunication

9.2.1 Market Estimates & Forecast, 2020-2027

9.2.2 Market Estimates & Forecast By Region, 2020-2027

9.3 Enterprises

9.3.1 Market Estimates & Forecast, 2020-2027

9.3.2 Market Estimates & Forecast By Region, 2020-2027

9.4 Data Centers

9.4.1 Market Estimates & Forecast, 2020-2027

9.4.2 Market Estimates & Forecast By Region, 2020-2027

10. Global Optical Transceiver Market By Form Factor

10.1 Introduction

10.2 SFP

10.2.1 Market Estimates & Forecast, 2020-2027

10.2.2 Market Estimates & Forecast By Region, 2020-2027

10.3 SFP+

10.3.1 Market Estimates & Forecast, 2020-2027

10.3.2 Market Estimates & Forecast By Region, 2020-2027

10.4 SFP28

10.4.1 Market Estimates & Forecast, 2020-2027

10.4.2 Market Estimates & Forecast By Region, 2020-2027

10.5 QSFP

10.5.1 Market Estimates & Forecast, 2020-2027

10.5.2 Market Estimates & Forecast By Region, 2020-2027

10.6 QSFP+

10.6.1 Market Estimates & Forecast, 2020-2027

10.6.2 Market Estimates & Forecast By Region, 2020-2027

10.7 QSFP28

10.7.1 Market Estimates & Forecast, 2020-2027

10.7.2 Market Estimates & Forecast By Region, 2020-2027

10.8 CFP

10.8.1 Market Estimates & Forecast, 2020-2027

10.8.2 Market Estimates & Forecast By Region, 2020-2027

10.9 CXP

10.9.1 Market Estimates & Forecast, 2020-2027

10.9.2 Market Estimates & Forecast By Region, 2020-2027

11. Global Optical Transceiver Market By Configuration

11.1 Introduction

11.2 Half-Duplex

11.2.1 Market Estimates & Forecast, 2020-2027

11.2.2 Market Estimates & Forecast By Region, 2020-2027

11.3 Full-Duplex

11.3.1 Market Estimates & Forecast, 2020-2027

11.3.2 Market Estimates & Forecast By Region, 2020-2027

12. Global Optical Transceiver Market By Region

12.1 Introduction

12.2 North America

12.2.1 Market Estimates & Forecast, 2020-2027

12.2.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.2.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.2.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.2.5 Market Estimates & Forecast By End-User, 2020-2027

12.2.6 Market Estimates & Forecast By Configuration, 2020-2027

12.2.7 U.S.

12.2.7.1 Market Estimates & Forecast, 2020-2027

12.2.7.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.2.7.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.2.7.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.2.7.5 Market Estimates & Forecast By End-User, 2020-2027

12.2.7.6 Market Estimates & Forecast By Configuration, 2020-2027

12.2.8 Mexico

12.2.8.1 Market Estimates & Forecast, 2020-2027

12.2.8.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.2.8.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.2.8.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.2.8.5 Market Estimates & Forecast By End-User, 2020-2027

12.2.8.6 Market Estimates & Forecast By Configuration, 2020-2027

12.2.9 Canada

12.2.9.1 Market Estimates & Forecast, 2020-2027

12.2.9.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.2.9.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.2.9.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.2.9.5 Market Estimates & Forecast By End-User, 2020-2027

12.2.9.6 Market Estimates & Forecast By Configuration, 2020-2027

12.3 Europe

12.3.1 Market Estimates & Forecast, 2020-2027

12.3.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.3.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.3.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.3.5 Market Estimates & Forecast By End-User, 2020-2027

12.3.6 Market Estimates & Forecast By Configuration, 2020-2027

12.3.7 Germany

12.3.7.1 Market Estimates & Forecast, 2020-2027

12.3.7.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.3.7.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.3.7.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.3.7.5 Market Estimates & Forecast By End-User, 2020-2027

12.3.7.6 Market Estimates & Forecast By Configuration, 2020-2027

12.3.8. France

12.3.8.1 Market Estimates & Forecast, 2020-2027

12.3.8.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.3.8.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.3.8.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.3.8.5 Market Estimates & Forecast By End-User, 2020-2027

12.3.8.6 Market Estimates & Forecast By Configuration, 2020-2027

12.3.9 U.K

12.3.9.1 Market Estimates & Forecast, 2020-2027

12.3.9.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.3.9.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.3.9.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.3.9.5 Market Estimates & Forecast By End-User, 2020-2027

12.3.9.6 Market Estimates & Forecast By Configuration, 2020-2027

12.4 Asia Pacific

12.4.1 Market Estimates & Forecast, 2020-2027

12.4.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.4.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.4.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.4.5 Market Estimates & Forecast By End-User, 2020-2027

12.4.6 Market Estimates & Forecast By Configuration, 2020-2027

12.4.7 China

12.4.7.1 Market Estimates & Forecast, 2020-2027

12.4.7.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.4.7.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.4.7.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.4.7.5 Market Estimates & Forecast By End-User, 2020-2027

12.4.7.6 Market Estimates & Forecast By Configuration, 2020-2027

12.4.8 India

12.4.8.1 Market Estimates & Forecast, 2020-2027

12.4.8.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.4.8.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.4.8.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.4.8.5 Market Estimates & Forecast By End-User, 2020-2027

12.4.8.6 Market Estimates & Forecast By Configuration, 2020-2027

12.4.9 Japan

12.4.9.1 Market Estimates & Forecast, 2020-2027

12.4.9.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.4.9.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.4.9.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.4.9.5 Market Estimates & Forecast By End-User, 2020-2027

12.4.9.6 Market Estimates & Forecast By Configuration, 2020-2027

12.4.10 Rest Of Asia Pacific

12.4.10.1 Market Estimates & Forecast, 2020-2027

12.4.10.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.4.10.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.4.10.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.4.10.5 Market Estimates & Forecast By End-User, 2020-2027

12.4.10.6 Market Estimates & Forecast By Configuration, 2020-2027

12.5 Rest Of The World

12.5.1 Market Estimates & Forecast, 2020-2027

12.5.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.5.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.5.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.5.5 Market Estimates & Forecast By End-User, 2020-2027

12.5.6 Market Estimates & Forecast By Configuration, 2020-2027

12.5.7 The Middle East & Africa

12.5.7.1 Market Estimates & Forecast, 2020-2027

12.5.7.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.5.7.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.5.7.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.5.7.5 Market Estimates & Forecast By End-User, 2020-2027

12.5.7.6 Market Estimates & Forecast By Configuration, 2020-2027

12.5.8 Latin Countries

12.5.8.1 Market Estimates & Forecast, 2020-2027

12.5.8.2 Market Estimates & Forecast By Fiber Type, 2020-2027

12.5.8.3 Market Estimates & Forecast By Data Rate, 2020-2027

12.5.8.4 Market Estimates & Forecast By Form Factor, 2020-2027

12.5.8.5 Market Estimates & Forecast By End-User, 2020-2027

12.5.8.6 Market Estimates & Forecast By Configuration, 2020-2027

13. Company Profiles

13.1 Finisar Corporation (U.S.)

13.1.1 Company Overview

13.1.2 Product/Business Segment Overview

13.1.3 Financial Updates

13.1.4 Key Developments

13.2 Lumentum Holdings Inc. (U.S.)

13.2.1 Company Overview

13.2.2 Product/Business Segment Overview

13.2.3 Financial Updates

13.2.4 Key Developments

13.3 Accelink Technologies Co., Ltd (China)

13.3.1 Company Overview

13.3.2 Product/Business Segment Overview

13.3.3 Financial Updates

13.3.4 Key Developments

13.4 Oclaro Inc. (U.S.)

13.4.1 Company Overview

13.4.2 Product/Business Segment Overview

13.4.3 Financial Updates

13.4.4 Key Developments

13.5 Sumitomo Electric Industries, Ltd. (U.S.)

13.5.1 Company Overview

13.5.2 Product/Business Segment Overview

13.5.3 Financial Updates

13.5.4 Key Developments

13.6 Foxconn Electronics Inc. (Taiwan)

13.6.1 Company Overview

13.6.2 Product/Business Segment Overview

13.6.3 Financial Updates

13.6.4 Key Developments

13.7 NeoPhotonics Corporation (U.S.)

13.7.1 Company Overview

13.7.2 Product/Business Segment Overview

13.7.3 Financial Updates

13.7.4 Key Developments

13.8 Fujitsu Optical Components Ltd. (Japan)

13.8.1 Company Overview

13.8.2 Product/Business Segment Overview

13.8.3 Financial Updates

13.8.4 Key Developments

13.9 Reflex Photonics Inc (Canada)

13.9.1 Company Overview

13.9.2 Product/Business Segment Overview

13.9.3 Financial Updates

13.9.4 Key Developments

13.10 Source Photonics, Inc (U.S.)

13.10.1 Company Overview

13.10.2 Product/Business Segment Overview

13.10.3 Financial Updates

13.10.4 Key Developments

14 Conclusion

LIST OF TABLES

Table1 World Population By Major Regions (2020 To 2030)

Table2 Global Optical Transceiver Market: By Region, 2020-2027

Table3 North America Optical Transceiver Market: By Country, 2020-2027

Table4 Europe Optical Transceiver Market: By Country, 2020-2027

Table5 Asia Pacific Optical Transceiver Market: By Country, 2020-2027

Table6 The Middle East & Africa Optical Transceiver Market: By Country, 2020-2027

Table7 Latin America Optical Transceiver Market: By Country, 2020-2027

Table8 Global Optical Transceiver By Fiber Type Market: By Regions, 2020-2027

Table9 North America Optical Transceiver By Fiber Type Market: By Country, 2020-2027

Table10 Europe Optical Transceiver By Fiber Type Market: By Country, 2020-2027

Table11 Asia Pacific Optical Transceiver By Fiber Type Market: By Country, 2020-2027

Table12 The Middle East & Africa Optical Transceiver By Fiber Type Market: By Country, 2020-2027

Table13 Latin America Optical Transceiver By Fiber Type Market: By Country, 2020-2027

Table14 Global Fiber Type Market: By Region, 2020-2027

Table15 North America Optical Transceiver Market, By Country

Table16 North America Optical Transceiver Market, By Fiber Type

Table17 North America Optical Transceiver Market, By Data Rate

Table18 Europe: Optical Transceiver Market, By Data Rate

Table19 Europe: Optical Transceiver Market, By Fiber Type

Table20 Asia Pacific: Optical Transceiver Market, By Country

Table21 Asia Pacific: Optical Transceiver Market, By Fiber Type

Table22 Asia Pacific: Optical Transceiver Market, By Data Rate

Table23 The Middle East & Africa: Optical Transceiver Market, By Country

Table24 The Middle East & Africa Optical Transceiver Market, By Fiber Type

Table25 The Middle East & Africa Optical Transceiver Market, By Data Rate

Table26 Latin America: Optical Transceiver Market, By Country

Table27 Latin America Optical Transceiver Market, By Fiber Type

Table28 Latin America Optical Transceiver Market, By Data Rate

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jacobhinkley · 7 years ago

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Archaeologists Argue Micronesian Stone Money Comprises Bitcoin Predecessor

Archaeologists are arguing that a pre-modern stone money used by Micronesian islanders resembles a precursor to bitcoin and distributed ledger technology.

Also Read: Largest Cannabis Community Market in Israel to Accept Bitcoin Payments

Archaeologists Highlight Similarities Between Micronesian Stone Money and Bitcoin

Scott Fitzpatrick, an archaeologist at the University of Oregon in Eugene, has argued that a stone form of money used by inhabitants of the Micronesian island of Yap, at least several hundred years ago, comprises a predecessor to bitcoin and blockchain technology. “Stone money transactions on Yap were the precursor to Bitcoin and blockchain technologies,” Mr. Fitzpatrick stated.

During April’s annual meeting of the Society for American Archaeology in Washington, D.C., Mr. Fitzpatrick elaborated on his theory, stating: “Centuries ago in western Micronesia, Yapese islanders began traveling to the Palauan archipelago to carve their famous stone money from limestone, which they then transported back to use in a variety of social transactions. While commonly referred to as ‘money’, these disks were not currency in the strict sense, though their value is not dissimilar to other traditional and modern objects where worth is arbitrary based on both real and perceived attributes (e.g., size, shape, quality, pedigree, or other factors). These characteristics have corollaries in today’s society for material culture and electronic cryptocurrencies that use blockchain technology—essentially, digital ledgers that track financial transactions in real time across a computer network to ensure that they are seamless and incorruptible.”

According to Science News, each limestone disk, or “rai,” was “assigned a value based on size, evenness of shape, stone quality and risks taken on the journey. After being inspected and verified by a local chief, rai were displayed at communal spots, such as ritual dancing grounds. Ownership of a disk could be transferred, for instance, as a wedding gift, to secure political allies or in exchange for food from residents of nearby islands after a severe storm. These deals also occurred in front of the whole community. No matter who acquired a rai, it stayed in its original location.”

“Traditional Forms of ‘Money’ or Exchange Valuables are the Precursor to Bitcoin”

Among the similarities highlighted between rai and bitcoin, is the public storage of rai, the peer-to-peer maintenance of the infrastructure and circulation of rai, the open auditability of rai, the use of rai as a means of exchange, and the fact that rai were produced through a process of mining.

Mr. Fitzpatrick concludes that “transactions involving traditional forms of ‘money’ or exchange valuables are the precursor to Bitcoin and other technologies that demand a unified and continuous chain of information to ensure that the value is known and ownership indisputable. This research suggests that Yapese stone money is just one of many cases in the ancient past of humans, through social networks, attempting to create accurate and unbroken lines of communication so that economic relationships can be established, maintained, and rectified.”

Kathryn Sampeck, an anthropological archaeologist at Illinois State University in Normal, has also supported the theory that the stone money of Yap resembles a predecessor to bitcoin technology, describing such as “legitimate.”

What is your response to Mr. Fitzpatrick’s theory? Join the discussion in the comments section below!

Images courtesy of Shutterstock

Want a comprehensive list of the top 500 cryptocurrencies and see their prices and overall market valuation? Check out Satoshi Pulse for all that hot market action!

The post Archaeologists Argue Micronesian Stone Money Comprises Bitcoin Predecessor appeared first on Bitcoin News.

Archaeologists Argue Micronesian Stone Money Comprises Bitcoin Predecessor published first on https://medium.com/@smartoptions

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vivekbajaj-grs · 4 years ago

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Global Optical Transceiver Market by Player, Region, Type, Application and Sales Channel 2021-2030

The global Optical Transceiver market was valued at $XX million in 2020, and we Researcher analysts predict the global market size will reach $XX million by the end of 2030, growing at a CAGR of XX% between 2021 and 2030.

Since the COVID-19 virus outbreak in December 2019, the disease has spread to all countries and territories around the world and 2 international conveyances. The global impacts of COVID-19 are already starting to be felt, and will significantly affect this industry in 2020 and 2021.

Download FREE Sample of this Report @ https://www.grandresearchstore.com/report-sample/global-optical-transceiver-2021-2030-185

This report analyses the impact of COVID-19 on this industry. COVID-19 can affect the global market in 3 ways: by directly affecting production and demand, by creating supply chain and market disruption, and by its financial impact on enterprises and financial markets.

This report provides detailed historical analysis of global market for Optical Transceiver from 2015-2020, and provides extensive market forecasts from 2021-2030 by region/country and subsectors. It covers the sales volume, price, revenue, gross margin, historical growth and future perspectives in the Optical Transceiver market.

Leading players of Optical Transceiver including:

II-VI Incorporated

FIT Hong Teng

Lumentum

Sumitomo Electric Industries

Accelink

Applied Optoelectronics

Fujitsu Optical Components

Innolight

Mellanox

NeoPhotonics

Ciena

Cisco

Hisense Broadband

Intel

NEC

Perle Systems

Reflex Photonics

Smartoptics

Solid Optics

Source Photonics

Finisar Corporation

Hummingbird Networks

Champion ONE

ETU-Link Technology

Curvature

Edge Technologies

Optcore

TXO Optics

UNOPTIX

DataLight Optics

Market split by Type, can be divided into:

SFF/SFP

XFP

QSFP

CFP

CXP

Market split by Application, can be divided into:

Telecommunication

Data Center

Enterprises

Market split by Sales Channel, can be divided into:

Direct Channel

Distribution Channel

Market segment by Region/Country including:

North America (United States, Canada and Mexico)

Europe (Germany, UK, France, Italy, Russia and Spain etc.)

Asia-Pacific (China, Japan, Korea, India, Australia and Southeast Asia etc.)

South America (Brazil, Argentina and Colombia etc.)

Middle East & Africa (South Africa, UAE and Saudi Arabia etc.)

If you have any special requirements, please let us know and we can provide you the customized report as you want.

Get the Complete Report & TOC @ https://www.grandresearchstore.com/chemicals-and-materials/global-optical-transceiver-2021-2030-185

Table of content

Table of Contents Chapter 1 Optical Transceiver Market Overview 1.1 Optical Transceiver Definition 1.2 Global Optical Transceiver Market Size Status and Outlook (2015-2030) 1.3 Global Optical Transceiver Market Size Comparison by Region (2015-2030) 1.4 Global Optical Transceiver Market Size Comparison by Type (2015-2030) 1.5 Global Optical Transceiver Market Size Comparison by Application (2015-2030) 1.6 Global Optical Transceiver Market Size Comparison by Sales Channel (2015-2030) 1.7 Optical Transceiver Market Dynamics (COVID-19 Impacts) 1.7.1 Market Drivers/Opportunities 1.7.2 Market Challenges/Risks 1.7.3 Market News (Mergers/Acquisitions/Expansion) 1.7.4 COVID-19 Impacts on Current Market 1.7.5 Post-Strategies of COVID-19 Outbreak Chapter 2 Optical Transceiver Market Segment Analysis by Player 2.1 Global Optical Transceiver Sales and Market Share by Player (2018-2020) 2.2 Global Optical Transceiver Revenue and Market Share by Player (2018-2020) 2.3 Global Optical Transceiver Average Price by Player (2018-2020) 2.4 Players Competition Situation & Trends 2.5 Conclusion of Segment by Player Chapter 3 Optical Transceiver Market Segment Analysis by Type 3.1 Global Optical Transceiver Market by Type 3.1.1 SFF/SFP 3.1.2 XFP 3.1.3 QSFP 3.1.4 CFP 3.1.5 CXP 3.2 Global Optical Transceiver Sales and Market Share by Type

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#OpticalTransceiverMarket

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thoughtfulsaladgarden · 4 years ago

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HOW TO USE QSFP28 TRANSCEIVERS FOR 100G DATA CENTER CONNECTIVITY

One of the most uncomplicated method to link 100G traffic is using common transceivers and there's a wide variety of wires and transceivers ideal for this.

https://www.fibermall.com/blog/100g-qsfp28-lr4-psm4-and-cwdm4-modules.htm

To provide cost-optimized remedies for attaching buttons with each other in a shelf or information facility, Ethernet button suppliers intend to optimize the thickness of optical transceiver ports on their devices. This is so they can surely provide optimal network matter and least expensive set you back each little bit traffic.

The majority of these button suppliers pick the tiniest create variable transceiver: the QSFP28 transceiver. It is the tiniest component offered, and has actually the most affordable power usage amongst those that can dealing with 100G traffic. It is additionally significant that the QSFP28 has actually the exact same physical dimension as the QSFP+ typically utilized for 40G traffic. This suggests that button suppliers can surely enhance the traffic throughput by an aspect 2.5 without the should upgrade the front panel of their buttons.

QSFP28 cable television settings up Practical, low-priced technique of attaching 100G devices, with a solitary setting up rather than 3 distinct parts. Less components are called for, however a lot of significantly, utilizing cable television settings up eliminates a lot of the issues related to unclean ports. DAC (Straight Connected Wires) exist for 0-15m and AOC (Energetic Optical Wires) as much as 70m. AOC cable television settings up give comparable efficiency to distinct transceivers and fiber wires.

QSFP 100G AOC QSFP28 AOC (Energetic Optical Cable)

QSFP28 Twinax DAC QSFP28 DAC (Straight Connected Cable)

QSFP28 transceivers Short-range QSFP28-SR4 transceivers assistance links of as much as 100 meters over multimode fiber. This method resembles utilizing AOC wires, however right below it's feasible to utilize organized cabling. They utilize more pricey non-standard MPO (multi push-on/pull-off cable television) ports which terminate out several of the set you back cost financial savings of the transceiver.

Long-range QSFP28-LR4 variations assistance links as much as 10km over singlemode fiber. They utilize common LC ports and utilize current organized LC cabling.

QSFP-SR4 QSFP28-SR4 MPO port kind, least expensive set you back trx, non-standard cabling

QSFP-LR4 QSFP28-LR4 LC port kind, common SM cabling

QSFP28 application assist QSFP28 application assist This is all excellent information for button suppliers that should take care of information that remains within the shelf and the information facility. For these circumstances, the QSFP28 supplies the best healthy. It just comes to be a trouble when 100G traffic should be moved over fars away, as when it comes to offering 100G information facility connection in between various geographical places.

For long-distance connection, there are a variety of create aspects offered. The CFP and CFP2, for instance, provide DWDM Coherent innovation and allow multi-channel cross country connection of greater than 1000km. However the CFP is large; it is as well large to be utilized in an Ethernet button in quantity.

Also if a supplier picks the smaller sized CFP2 or CFP4, the dimension and power are still needlessly - and frequently unrealistically - high. One service is to provide CFP DWDM assistance for those couple of web links where it is called for, however also there, the enhance in power usage and the lower in offered ports have actually an effect on the total cost-effectiveness of the button.

The difficulty of cross country connection The QSFP28 is still the tiniest 100G transceiver. It is a portion of the dimension of the CFP, and is best for brief ranges. For much longer ranges, there have actually additionally been some current developments in transceivers with DWDM abilities, a lot of dramatically the PAM4 . To work, nonetheless, the PAM4 needs boosting for also extremely brief ranges, and for any kind of range over 5 or 6km, demands dispersion settlement. With this, it can surely take care of information traffic as much as 80km.

While the variety of selections for attaching 100G traffic is expanding, no solitary little transceiver can surely refix the issue of attaching buttons in between information facilities or various other far-off websites.

That is why it is not unusual for companies to think about full-blown, telecom-grade DWDM systems to take care of their 100G information facility connection. These systems take the outcome of the QSFP28 transceiver and run it with a complicated internet of transponders, amplifiers, signify conditioning, multiplexers and network monitoring. It functions, however these systems are created for the telecommunications, not the datacom world, which suggests they're exceptionally intricate, and typically much overspecified of what are reasonably straightforward traffic needs. However more significantly, they're pricey, pressing the capex and opex for these systems much outdoors the variety of what a business information facility need to should invest, specifically when DWDM is just called for for a tiny percent of common Ethernet button links.

Just how company information facilities can surely obtain the greatest of both globes The perfect service would certainly enable best-in-breed 100G buttons and routers to be utilized within the information facility, with reduced power usage and an optimum port matter - with an inexpensive each little bit. And after that, for those celebrations where traffic from these buttons and routers should be linked over much longer ranges, or over a DWDM network, there need to be a remedy that's straightforward, very easy to mount and run, and affordable to very own and run. For a business information facility, none of these are terms that might be put on a remedy created for telecommunications systems.

The service that supplies the greatest of both globes permits the individual to obtain the complete advantages of QSFP28 transceivers in the datacom devices, however additionally obtains the benefits of telco-quality traffic transport in between websites.

The Smartoptics DCP family members is developed precisely for this objective. These modular, plug-and-play, low-powered transponders and muxponders can surely be positioned near the buttons whose traffic they should carry. They're created on an open up networking approach that makes it possible for transponders and installed DWDM to be utilized along with installed DWDM transceivers, depending upon the details demands of each network.

Instead of utilize pricey workarounds of items created for massive telecoms providers, company information facilities can surely currently utilize a lot easier, plug-and-play remedies that are versatile, scalable, and created to fulfill their demands.

For more on utilizing QSFP28 transceivers for information facility connection without compromising long-distance traffic demands, download and install the Smartoptics overview of streamlining 100G DWDM connection.

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