Product Code: A07114
The global automotive Ethernet market is envisioned to garner $8,765.8 million by 2031, growing from $ 2,135.1 million in 2021 at a CAGR of 14.4% from 2022 to 2031.
Automotive ethernet is a physical network that connects different auto parts via a wired network. It is designed in a manner that it meets the electrical and bandwidth requirements. By achieving synchronization and lowering the complexity of the network within the vehicle, this arrangement lowers the cost of cabling and labor. The in-vehicle infrastructure becomes more sophisticated because of the next-generation automotive applications. The proliferation of sensors, actuators, connectivity modules, network modules, and Electronic Control Units (ECUs) in modern cars has increased the complexity of the vehicle. The original equipment manufacturers (OEMs) for the automotive industry are implementing next-generation technologies to maintain infrastructure stability and reduce network strain.
The automotive sector is being dramatically led toward innovation by the integration of cutting-edge technologies, such as communication, linked devices, and artificial intelligence (AI) technology, in connected vehicles, which is raising customer happiness and improving the driving experience. Automobiles also employ a number of unique communication standards, with each component often using a separate connection or wire. By adopting a single standard, all of the communications between the various components can cohabit on a single switched ethernet network, with a single pair of cables running from a central switch to each point inside the car. Additionally, as technology develops, car electronic systems become more complicated with more controllers, sensors, and interfaces, necessitating a larger bandwidth. There is a huge need for automotive ethernet since these electronic components in the connected vehicle must constantly speak with one another.
However, the market's expansion is anticipated to be constrained by the difficulty of switching from conventional in-vehicle connectivity to ethernet.
A significant opportunity in the automotive ethernet market is technological improvement in automobiles. To create the sophisticated, high-bandwidth communications systems needed by next-generation automobiles, businesses are focusing on intelligent automotive ethernet solutions. For instance, the first automotive ethernet switch firmware for EVs, sophisticated ADAS, and self-driving cars was introduced in 2021 by the German business Elektrobit which develops automotive software. The firmware gives automotive ethernet switches an extra layer of intelligence, enabling them to manage the massive network functions necessary to improve the scalability, safety, and security of automobiles. Routing, gateways, firewalls, and network intrusion detection and prevention systems are just a few of the sophisticated network management and security features it offers.
Businesses now have to rewire their business strategies in response to COVID-19. The pandemic has had a negative effect on the automotive industry globally. In the first half of 2020, automobile ecosystem vendors will cease operations due to the widespread lockdown and social distance standards. A growing trend in the automotive industry has been set off by improvements in the COVID-19 vaccine, government stimulus programs, and a recovery in the global economy. The market is expanding primarily because businesses are starting up again and adjusting to the new normal as they recover from the COVID-19 effect, which had previously resulted in restrictive containment measures like social isolation, remote work, and the closure of commercial activities that created operational difficulties.
The key players profiled in this report include: Vector Informatik GmbH, NXP Semiconductors N. V., Marvell Semiconductor, Inc., Molex, Broadcom Inc., Microchip Technology Inc., Aukua Systems, Keysight Technologies, Cadence Design Systems, Inc, and Texas Instruments Incorporated.
Key Benefits For Stakeholders
- This report provides a quantitative analysis of the market segments, current trends, estimations, and dynamics of the automotive ethernet market analysis from 2021 to 2031 to identify the prevailing automotive ethernet market opportunities.
- Market research is offered along with information related to key drivers, restraints, and opportunities.
- Porter's five forces analysis highlights the potency of buyers and suppliers to enable stakeholders to make profit-oriented business decisions and strengthen their supplier-buyer network.
- An in-depth analysis of the automotive ethernet market segmentation assists to determine the prevailing market opportunities.
- Major countries in each region are mapped according to their revenue contribution to the global market.
- Market player positioning facilitates benchmarking and provides a clear understanding of the present position of the market players.
- The report includes the analysis of the regional as well as global automotive ethernet market trends, key players, market segments, application areas, and market growth strategies.
Key Market Segments
By Component
- Hardware
- Software
- Services
By Application
- Others
- Chassis
- Infotainment
- Powertrain
- Driver Assistance
- Body and Comfort
By Vehicle Type
- Passenger Cars
- Commercial Vehicles
By Region
- North America
- Europe
- Germany
- United Kingdom
- France
- Spain
- Italy
- Rest of Europe
- Asia-Pacific
- China
- Japan
- India
- South Korea
- Australia
- Rest Of Asia Pacific
- LAMEA
- Brazil
- Saudi Arabia
- UAE
- South Africa
- Rest of LAMEA
- Key Market Players
- Broadcom
- NXP
- Marvell
- Microchip
- Vector Informatik
- Dryv.io
- Molex
- Texas Instruments
- Cadence
- DASAN Networks.
- AUKUA SYSTEMS
- Keysight Technologies
TABLE OF CONTENTS
CHAPTER 1:INTRODUCTION
- 1.1.Report description
- 1.2.Key market segments
- 1.3.Key benefits to the stakeholders
- 1.4.Research Methodology
- 1.4.1.Secondary research
- 1.4.2.Primary research
- 1.4.3.Analyst tools and models
CHAPTER 2:EXECUTIVE SUMMARY
- 2.1.Key findings of the study
- 2.2.CXO Perspective
CHAPTER 3:MARKET OVERVIEW
- 3.1.Market definition and scope
- 3.2.Key findings
- 3.2.1.Top investment pockets
- 3.3.Porter's five forces analysis
- 3.4.Top player positioning
- 3.5.Market dynamics
- 3.5.1.Drivers
- 3.5.2.Restraints
- 3.5.3.Opportunities
- 3.6.COVID-19 Impact Analysis on the market
- 3.7.Value Chain Analysis
- 3.8.Key Regulation Analysis
- 3.9.Patent Landscape
- 3.10.Market Share Analysis
- 3.11.Regulatory Guidelines
CHAPTER 4: AUTOMOTIVE ETHERNET MARKET, BY COMPONENT
- 4.1 Overview
- 4.1.1 Market size and forecast
- 4.2 Hardware
- 4.2.1 Key market trends, growth factors and opportunities
- 4.2.2 Market size and forecast, by region
- 4.2.3 Market analysis by country
- 4.3 Software
- 4.3.1 Key market trends, growth factors and opportunities
- 4.3.2 Market size and forecast, by region
- 4.3.3 Market analysis by country
- 4.4 Services
- 4.4.1 Key market trends, growth factors and opportunities
- 4.4.2 Market size and forecast, by region
- 4.4.3 Market analysis by country
CHAPTER 5: AUTOMOTIVE ETHERNET MARKET, BY APPLICATION
- 5.1 Overview
- 5.1.1 Market size and forecast
- 5.2 Chassis
- 5.2.1 Key market trends, growth factors and opportunities
- 5.2.2 Market size and forecast, by region
- 5.2.3 Market analysis by country
- 5.3 Infotainment
- 5.3.1 Key market trends, growth factors and opportunities
- 5.3.2 Market size and forecast, by region
- 5.3.3 Market analysis by country
- 5.4 Powertrain
- 5.4.1 Key market trends, growth factors and opportunities
- 5.4.2 Market size and forecast, by region
- 5.4.3 Market analysis by country
- 5.5 Driver Assistance
- 5.5.1 Key market trends, growth factors and opportunities
- 5.5.2 Market size and forecast, by region
- 5.5.3 Market analysis by country
- 5.6 Body and Comfort
- 5.6.1 Key market trends, growth factors and opportunities
- 5.6.2 Market size and forecast, by region
- 5.6.3 Market analysis by country
- 5.7 Others
- 5.7.1 Key market trends, growth factors and opportunities
- 5.7.2 Market size and forecast, by region
- 5.7.3 Market analysis by country
CHAPTER 6: AUTOMOTIVE ETHERNET MARKET, BY VEHICLE TYPE
- 6.1 Overview
- 6.1.1 Market size and forecast
- 6.2 Passenger Cars
- 6.2.1 Key market trends, growth factors and opportunities
- 6.2.2 Market size and forecast, by region
- 6.2.3 Market analysis by country
- 6.3 Commercial Vehicles
- 6.3.1 Key market trends, growth factors and opportunities
- 6.3.2 Market size and forecast, by region
- 6.3.3 Market analysis by country
CHAPTER 7: AUTOMOTIVE ETHERNET MARKET, BY REGION
- 7.1 Overview
- 7.1.1 Market size and forecast
- 7.2 North America
- 7.2.1 Key trends and opportunities
- 7.2.2 North America Market size and forecast, by Component
- 7.2.3 North America Market size and forecast, by Application
- 7.2.4 North America Market size and forecast, by Vehicle Type
- 7.2.5 North America Market size and forecast, by country
- 7.2.5.1 U.S.
- 7.2.5.1.1 Market size and forecast, by Component
- 7.2.5.1.2 Market size and forecast, by Application
- 7.2.5.1.3 Market size and forecast, by Vehicle Type
- 7.2.5.2 Canada
- 7.2.5.2.1 Market size and forecast, by Component
- 7.2.5.2.2 Market size and forecast, by Application
- 7.2.5.2.3 Market size and forecast, by Vehicle Type
- 7.2.5.3 Mexico
- 7.2.5.3.1 Market size and forecast, by Component
- 7.2.5.3.2 Market size and forecast, by Application
- 7.2.5.3.3 Market size and forecast, by Vehicle Type
- 7.3 Europe
- 7.3.1 Key trends and opportunities
- 7.3.2 Europe Market size and forecast, by Component
- 7.3.3 Europe Market size and forecast, by Application
- 7.3.4 Europe Market size and forecast, by Vehicle Type
- 7.3.5 Europe Market size and forecast, by country
- 7.3.5.1 Germany
- 7.3.5.1.1 Market size and forecast, by Component
- 7.3.5.1.2 Market size and forecast, by Application
- 7.3.5.1.3 Market size and forecast, by Vehicle Type
- 7.3.5.2 United Kingdom
- 7.3.5.2.1 Market size and forecast, by Component
- 7.3.5.2.2 Market size and forecast, by Application
- 7.3.5.2.3 Market size and forecast, by Vehicle Type
- 7.3.5.3 France
- 7.3.5.3.1 Market size and forecast, by Component
- 7.3.5.3.2 Market size and forecast, by Application
- 7.3.5.3.3 Market size and forecast, by Vehicle Type
- 7.3.5.4 Spain
- 7.3.5.4.1 Market size and forecast, by Component
- 7.3.5.4.2 Market size and forecast, by Application
- 7.3.5.4.3 Market size and forecast, by Vehicle Type
- 7.3.5.5 Italy
- 7.3.5.5.1 Market size and forecast, by Component
- 7.3.5.5.2 Market size and forecast, by Application
- 7.3.5.5.3 Market size and forecast, by Vehicle Type
- 7.3.5.6 Rest of Europe
- 7.3.5.6.1 Market size and forecast, by Component
- 7.3.5.6.2 Market size and forecast, by Application
- 7.3.5.6.3 Market size and forecast, by Vehicle Type
- 7.4 Asia-Pacific
- 7.4.1 Key trends and opportunities
- 7.4.2 Asia-Pacific Market size and forecast, by Component
- 7.4.3 Asia-Pacific Market size and forecast, by Application
- 7.4.4 Asia-Pacific Market size and forecast, by Vehicle Type
- 7.4.5 Asia-Pacific Market size and forecast, by country
- 7.4.5.1 China
- 7.4.5.1.1 Market size and forecast, by Component
- 7.4.5.1.2 Market size and forecast, by Application
- 7.4.5.1.3 Market size and forecast, by Vehicle Type
- 7.4.5.2 Japan
- 7.4.5.2.1 Market size and forecast, by Component
- 7.4.5.2.2 Market size and forecast, by Application
- 7.4.5.2.3 Market size and forecast, by Vehicle Type
- 7.4.5.3 India
- 7.4.5.3.1 Market size and forecast, by Component
- 7.4.5.3.2 Market size and forecast, by Application
- 7.4.5.3.3 Market size and forecast, by Vehicle Type
- 7.4.5.4 South Korea
- 7.4.5.4.1 Market size and forecast, by Component
- 7.4.5.4.2 Market size and forecast, by Application
- 7.4.5.4.3 Market size and forecast, by Vehicle Type
- 7.4.5.5 Australia
- 7.4.5.5.1 Market size and forecast, by Component
- 7.4.5.5.2 Market size and forecast, by Application
- 7.4.5.5.3 Market size and forecast, by Vehicle Type
- 7.4.5.6 Rest Of Asia Pacific
- 7.4.5.6.1 Market size and forecast, by Component
- 7.4.5.6.2 Market size and forecast, by Application
- 7.4.5.6.3 Market size and forecast, by Vehicle Type
- 7.5 LAMEA
- 7.5.1 Key trends and opportunities
- 7.5.2 LAMEA Market size and forecast, by Component
- 7.5.3 LAMEA Market size and forecast, by Application
- 7.5.4 LAMEA Market size and forecast, by Vehicle Type
- 7.5.5 LAMEA Market size and forecast, by country
- 7.5.5.1 Brazil
- 7.5.5.1.1 Market size and forecast, by Component
- 7.5.5.1.2 Market size and forecast, by Application
- 7.5.5.1.3 Market size and forecast, by Vehicle Type
- 7.5.5.2 Saudi Arabia
- 7.5.5.2.1 Market size and forecast, by Component
- 7.5.5.2.2 Market size and forecast, by Application
- 7.5.5.2.3 Market size and forecast, by Vehicle Type
- 7.5.5.3 UAE
- 7.5.5.3.1 Market size and forecast, by Component
- 7.5.5.3.2 Market size and forecast, by Application
- 7.5.5.3.3 Market size and forecast, by Vehicle Type
- 7.5.5.4 South Africa
- 7.5.5.4.1 Market size and forecast, by Component
- 7.5.5.4.2 Market size and forecast, by Application
- 7.5.5.4.3 Market size and forecast, by Vehicle Type
- 7.5.5.5 Rest of LAMEA
- 7.5.5.5.1 Market size and forecast, by Component
- 7.5.5.5.2 Market size and forecast, by Application
- 7.5.5.5.3 Market size and forecast, by Vehicle Type
CHAPTER 8: COMPANY LANDSCAPE
- 8.1. Introduction
- 8.2. Top winning strategies
- 8.3. Product Mapping of Top 10 Player
- 8.4. Competitive Dashboard
- 8.5. Competitive Heatmap
- 8.6. Key developments
CHAPTER 9: COMPANY PROFILES
- 9.1 Broadcom
- 9.1.1 Company overview
- 9.1.2 Company snapshot
- 9.1.3 Operating business segments
- 9.1.4 Product portfolio
- 9.1.5 Business performance
- 9.1.6 Key strategic moves and developments
- 9.2 NXP
- 9.2.1 Company overview
- 9.2.2 Company snapshot
- 9.2.3 Operating business segments
- 9.2.4 Product portfolio
- 9.2.5 Business performance
- 9.2.6 Key strategic moves and developments
- 9.3 Marvell
- 9.3.1 Company overview
- 9.3.2 Company snapshot
- 9.3.3 Operating business segments
- 9.3.4 Product portfolio
- 9.3.5 Business performance
- 9.3.6 Key strategic moves and developments
- 9.4 Microchip
- 9.4.1 Company overview
- 9.4.2 Company snapshot
- 9.4.3 Operating business segments
- 9.4.4 Product portfolio
- 9.4.5 Business performance
- 9.4.6 Key strategic moves and developments
- 9.5 Vector Informatik
- 9.5.1 Company overview
- 9.5.2 Company snapshot
- 9.5.3 Operating business segments
- 9.5.4 Product portfolio
- 9.5.5 Business performance
- 9.5.6 Key strategic moves and developments
- 9.6 Dryv.io
- 9.6.1 Company overview
- 9.6.2 Company snapshot
- 9.6.3 Operating business segments
- 9.6.4 Product portfolio
- 9.6.5 Business performance
- 9.6.6 Key strategic moves and developments
- 9.7 Molex
- 9.7.1 Company overview
- 9.7.2 Company snapshot
- 9.7.3 Operating business segments
- 9.7.4 Product portfolio
- 9.7.5 Business performance
- 9.7.6 Key strategic moves and developments
- 9.8 Texas Instruments
- 9.8.1 Company overview
- 9.8.2 Company snapshot
- 9.8.3 Operating business segments
- 9.8.4 Product portfolio
- 9.8.5 Business performance
- 9.8.6 Key strategic moves and developments
- 9.9 Cadence
- 9.9.1 Company overview
- 9.9.2 Company snapshot
- 9.9.3 Operating business segments
- 9.9.4 Product portfolio
- 9.9.5 Business performance
- 9.9.6 Key strategic moves and developments
- 9.10 DASAN Networks.
- 9.10.1 Company overview
- 9.10.2 Company snapshot
- 9.10.3 Operating business segments
- 9.10.4 Product portfolio
- 9.10.5 Business performance
- 9.10.6 Key strategic moves and developments
- 9.11 AUKUA SYSTEMS
- 9.11.1 Company overview
- 9.11.2 Company snapshot
- 9.11.3 Operating business segments
- 9.11.4 Product portfolio
- 9.11.5 Business performance
- 9.11.6 Key strategic moves and developments
- 9.12 Keysight Technologies
- 9.12.1 Company overview
- 9.12.2 Company snapshot
- 9.12.3 Operating business segments
- 9.12.4 Product portfolio
- 9.12.5 Business performance
- 9.12.6 Key strategic moves and developments