Automotive Cybersecurity Market
By Application (Telematics, Infotainment, ADAS and Safety, Power Train and Body Control Systems, Communications and Navigation System),
By Offering (Hardware, Software),
By Type (In-Vehicle, Cloud Services),
By Security (Application Security, Network Security, Endpoint Security),
By Region (North America, Europe, Asia-Pacific, Latin America, Middle East & Africa):
Automotive Cybersecurity Market - Global Analysis And Forecast 2023-2033.
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The global automotive cybersecurity market showcased a revenue of USD 2.76 billion in 2022 and is projected to witness a compounded annual growth rate (CAGR) of more than 19.35% over the forecast period of 2023-2033.
Russia-Ukraine War Impact
Market Scope
About the Market
Impact of COVID-19
Global Economic Slowdown
Market Dynamics
Driver
Restrain
Opportunity
Recent Developments
Synopsis
How is this report helpful
FAQ's
Report Coverage
Related Reports
When associated with automobiles, cybersecurity is the fortification of automotive electronic systems, communication networks, control algorithms, software, users, and underlying data from malevolent attacks, damage, unsanctioned access, or manipulation. Innovative technologies will connect, automate, and ultimately drive modern-day vehicles and, with the increasing demand, will turn out to be a part of an interrelated vehicle ecosystem, susceptible to the same cyber security risks as other information ecosystems. In more accustomed information ecosystems, security, vigilance, and resilience are the hallmarks of cyber risk management and information security. With the safety of human passengers at stake, these three principles will direct cybersecurity in the developing mobility ecosystem.
To improve customer experience, safety, and security, technology demands a greater place in automated cars while expecting these components, systems, and services to not jeopardize their privacy. An archetypal automobile today contains about 70 computational systems running up to 100 million lines of programming code, which is twice as many lines of code as the windows vista operating system, which means security must complement design from the kickoff. The attack surface of an automobile expands as automobiles continue to develop in complexity. A solitary, vulnerable device can expose an entire automotive ecosystem to attack, and the probable exposure ranges from inconvenience to massive safety breakdowns. With security, resilience, and vigilance at the automaker's helm, they are taking various steps to safeguard the data they are creating, such as escalating the regulatory, risk, and cybersecurity negotiation to augment overall vehicle safety, security, and privacy, taming the industry's cybersecurity talent, methodologies, proficiency, and responsiveness, edifying secure product expansion and software coding routines coupled with substantial immersion from security professionals, fashioning robust technology and nursing proficiencies and sharing statistics across the industry on budding threats and responses and creating competences within the vehicle, its ecosystem, and supply chain for avoiding attacks, mending exposures, and retorting to attacks.
The increasing demand for connected cars is triggering more growth in the automotive cybersecurity market in the North American region. With the presence of major automobile manufacturers such as Ford, Chevrolet, Jeep, Ram, and GMC in the U.S., the country will lead the cybersecurity market in the region due to the high demand for connected cars. The region has witnessed many cybersecurity crimes when it comes to automobiles. For instance, in July 2015, it was reported that hackers had taken control of a Jeep Cherokee via its internet-connected entertainment system. After security researchers showed that one of its cars could be hacked, Fiat Chrysler issued a safety recall disturbing 1.4m vehicles in the U.S. In the Asia-Pacific region, China, the largest market for automotive sales, is implementing cybersecurity policies to keep cyberattacks at bay, followed by India. China accounts for one-third of new vehicle sales globally, which is only anticipated to intensify in the years to come. China is expected to have over 97 regulations designed to mitigate the risks associated with over-the-air (OTA) software and update systems utilized in intelligent connected vehicles (ICV) and electric vehicles (EV) by 2025. Such legislature will be domineering to warrant driver, vehicle, and community safety and safeguard personal and national data.
Impact of Russia-Ukraine War on Automotive Cybersecurity Market
There is a direct impact of the Russia-Ukraine war on the global automotive cybersecurity market. However, the European region will witness the highest impact. Increased trade sanctions across the European region, followed by disruption in global trade routes, are one of the major factors imposed due to war and limiting business opportunities. Factors such as lack of raw materials, limited manufacturing capabilities in the European region, and withdrawal of major automotive manufacturers from Russia and Ukraine will directly affect the cybersecurity market. For instance, in October 2022, Mercedes Benz and Ford ceased manufacturing in Russia, followed by exports to the country. With the exit of major players, post-recovery, the European region will be open for grabs in terms of market share. The crisis had a short-term effect on the automotive cybersecurity market. However, the market will gain impetus in the long term in the region.
Automotive Cybersecurity: Market Scope
The automotive cybersecurity market is divided into four segments: application, offering, type, and security. Furthermore, these segments are subdivided into respective categories and cross-referenced to North America, Europe, Asia-Pacific, Latin America, and Middle East & Africa for regional analysis. The application segment is further categorized into telematics, infotainment, ADAS and safety, power train and body control systems, and communications and navigation systems. The offering segment is segregated into hardware and software. The type segment of the automotive cybersecurity market is bifurcated into in-vehicle and cloud services. With respect to security, the industry is analyzed by application security, network security, and endpoint security. Each of these segments is further classified into regions: North America, Europe, Asia-Pacific, Latin America, and Middle East & Africa. The historical dataset of 2018-2022 is provided in the report, whereas the forecast period of 2023-2033 is offered.
ADAS and safety will witness the highest growth rate within the application segment
ADAS and safety show a fulfilling revenue generation in the application segment during the forecast period. Advanced Driver Assistance Systems (ADAS) expose a large attack surface, and cybersecurity weaknesses could have overwhelming consequences. Automotive Cybersecurity is a significant necessity and a crucial prerequisite for safe ADAS and future self-driving cars since there will be no safety without cybersecurity. Guaranteeing the cybersecurity of ADAS and safety is challenging, as any wireless interface can be a probable attack vector. ADAS is grounded on multifaceted hardware and software, often integrating Vehicle-to-Everything (V2X) communication and back-end connectivity. Pilot Systems steered a study on ADAS cybersecurity focusing on susceptibilities in sensors and the sensor fusion algorithms, as several white hack attacks have been recognized and published on the perception layer. In ADAS, camera sensors are used to offer a 360-degree view of the vehicle's surroundings and are based on neural network/deep learning systems, which are susceptible to manipulation and cyber-attacks. The concerned manufacturers claim that the problem is answered in the current generation of cameras, but the hack divulges a much-propounded structural problem of ADAS and perception algorithms. There always will be circumstances that necessitate a judgment call and context switch between different levels of perception and interpretation where humans are connoisseurs in dealing with such situations while automated systems face difficulties or fail.
The software segment will capture the highest market share between 2023-2033
It is observed that the software segment still be capturing a higher market share in the offering sector during the forecast period. As with computers and smartphones, the software has become progressively prominent in handling vehicle functionality and has substituted many formerly hard-wired functions in classic electronic control units (ECUs). The mounting ascendency of software has helped recent vehicles become known as "computers on wheels." Inopportunely, the software also makes vehicles susceptible to probable cyber-attacks. According to the United Nations Economic Commission for Europe (UNECE), new vehicles include approximately 100 million software code lines expected to triple by 2030. Software is presently advanced through an amalgamation of internal development organizations and tier-1 suppliers. To integrate cybersecurity processes that empower WP.29 compliance (performance and audit necessities for cybersecurity and software update management for novel passenger vehicles sold in the European Union and dozens of other countries), OEMs will need to develop new procedures that not only alter how software is advanced but also progress relationships with those tier-1 suppliers.
The cloud services segment will capture the highest market share in the coming years
Cloud services are capturing a larger market in the type segment during the forecast period. Cloud server attacks have become the leading category in cyberattacks, with more than 41% of the total from 2010 to 2021. The Log4Shell vulnerability has the probability of surging server attacks even further in 2022 and beyond and has emerged as a new issue. Revealed in December 2021, this susceptibility is based on the Apache Log4j Java-based logging library and can endanger the security of any automotive-related server using this common library. Over-the-air updates, which allow manufacturers to fix bugs and update the software remotely, are susceptible to outside attacks due to remote control. Data broadcast between multiple vendors, the automaker, dealership, third-party data centers, GPS and onboard diagnostics systems, smart home devices, and others creates multiple vulnerable points that should be monitored. Acclimatizing the current systems and components with tougher security procedures will be key to conserving the connected automobile.
Application security segment within security to witness the highest CAGR during the forecast timeframe
The forecast timeframe has predicted proliferation in demands of application security during the forecast timeframe. Applications tools, logic factories, and works of art all rolled into one, which makes data accomplish useful work. Applications are connected to and work in concert with systems such as the infotainment system and processes running at the Electronic Control Unit (ECU) level. Apps network these elements into an organized whole while acting as a dynamic interface with the consumers they serve. Applications connect to and interconnect with every element in a digital system carrying both a high potential for expediency and, concurrently, a high potential for susceptibility through unofficial access and modification, which makes them a high-value target for attackers and to further complex matters, applications are exposed at every step in the software development lifecycle. Application security must be pragmatic during all application creation phases, including design, development, and deployment.
North America is to witness the highest growth rate during the forecast period
North American region is promising a dynamic rise in disposable income, which is expected to trigger growing market consumption of automotive cybersecurity. The increasing demand for connected cars in the region is triggering the market growth of cybersecurity. With the presence of major automobile manufacturers such as Ford, Chevrolet, Jeep, Ram, and GMC in the U.S., the country will lead the cybersecurity market in the region. The government has taken necessary steps to deal with automotive cybersecurity over the years. In 2016, the U.S government launched Automotive Information Sharing and Analysis Center (ISAC), which is an industry-driven community to share and analyze intelligence about emerging cybersecurity risks to the vehicle and to collectively enhance vehicle cybersecurity capabilities across the global automotive industry, including light- and heavy-duty vehicle OEMs, suppliers, and the commercial vehicle sector. In 2022, the U.S. Department of Transportation released cybersecurity best practices for the safety of modern vehicles, including the information sharing program and self-auditing of automobiles as a procedure to deal with cybersecurity.
Impact of COVID-19 on Automotive Cybersecurity Market
COVID-19 significantly impacted the automotive cybersecurity market in terms of losses and dropped sales of connected cars in the market. This is largely credited to the restricted travel and imposed lockdowns during the pandemic. Work from home model used during the pandemic reduced commutes, and the demand for automobiles dropped. The collected data show a 16% decline in 2020 production to less than 78 million vehicles, reducing the demand for cybersecurity. The pandemic also accelerated the modernization of all sectors, which was the need of the hour to cope with the pandemic. Cybercrime is, in fact, up nearly 600% since the pandemic, which will affect the automotive industry to recovery. Major companies operating in the market suffered losses owing to blocked sales channels, lack of manpower, and social distancing norms as a part of lockdowns in place during the pandemic. The automobile sector is still recovering, but the pandemic is unlikely to have a long-term impact on the growth of the automotive cybersecurity market.
Automotive Cybersecurity: Market Dynamics
The market dynamics section of the report covers a depth analysis of drivers, restraints, and opportunities impacting the automotive cybersecurity market. The report also encompasses major market strategies practiced by the industry, followed by patent analysis, product analysis, competitive benchmarking of companies, PORTER and PESTLE analysis of the automotive cybersecurity industry, pricing analysis, and geographic competitiveness to provide a detailed understanding. The major players operating the market are Aptive PLC, Broadcom Inc., Continental AG, Denso Corporation, Guard Knox Cyber-Technologies Ltd., Honeywell International, Inc., Harman International, Karamba Security, Robert Bosch GmbH and Vector Informatik GmbH. These companies cumulatively hold the majority of the automotive cybersecurity market share and actively undergoes strategic development, such as new product launch, merger, collaboration, business expansion, acquisition, and long-term contracts to ensure market penetration. These companies also largely focus on research and development to gain competitiveness in the market. A detailed analysis of these companies is offered in the report.
Driver: Government increasing the adoption of connected cars and mandatory cybersecurity standards are fueling the market growth
The increasing market demand for automotive cybersecurity is a collective outcome of governments trying to increase the adoption rate of connected cars to develop green infrastructure. For instance, in January 2022, the U.K. government extended and augmented the electric vehicle (EV) grant accessible to consumers. This grant allows consumers to avail of discounts when acquiring eligible EVs. The grant has been increased to £3,500 ($4,650) from £2,500 ($3,320) for eligible electric cars and has been set up to £8,000 ($10,600) for eligible vans. Vehicles must meet explicit requirements in order to be eligible for the subsidy, such as emanating less than 50g/km of CO2 and having a range of at least 70 miles for automobiles and 60 miles for vans on a single charge. Moreover, the support is only available for brand-new automobiles, not used ones. Subsidies such as these are making EVs accessible to many consumers, propelling the growth of the electric vehicle battery market in return. With the increasing demand for connected cars, cyber crimes are also increasing in the automotive industry, which has led to the implementation of rigid cybersecurity standards globally. For instance, in June 2020, the World Forum for Harmonization of Vehicle Regulations (WP29) implemented a new international automotive cybersecurity regulation to pave the way for connected vehicles and alleviate the cybersecurity risks posed to passenger vehicles. The regulation establishes performance and audit requirements for cybersecurity and software update management for new-fangled passenger vehicles sold in the European Union and dozens of other countries. The cybersecurity regulation precisely calls out three lifecycle phases: development, production, and post-production, which include monitoring, detecting, and responding to cyberattacks. With the increasing demand for connected cars, which is increasing cyber-attacks on automobiles, cybersecurity standards are being implemented, boosting the market growth of automotive cybersecurity.
Restrain proliferation in the development of common platforms, posing a threat to the market
The use of common platforms reduces the cost of implementing security features by standardizing them across all models, making them vulnerable to cyber-attacks. A hacker can attack all the models using the common platform, making the entire ecosystem susceptible. Over the years, many automakers have adopted a Real-Time Operating System (RTOS), which is an operating system (OS) that brings about hardware resources and activities, including scheduling application programs, writing files to disk, sending data across networks, and others synchronously and within foreseeable time limits. With time, many smartphones and servers are getting designed or repurposed to be compatible with automobiles, increasing the number of consumers who have the skills to operate these platforms. These platforms are more susceptible to danger since many hackers are already familiar with them. Though RTOS enables critical features in a car to run with minimal latency, more attention needs to be paid to security.
Opportunity: Enhanced vehicle security using machine learning, cybersecurity platforms, and adaptive security to create market demand
The automotive cybersecurity market shows promising opportunities in the North American region and developing countries of other regions. This is largely observed due to the increasing use of machine learning, cybersecurity platforms, and adaptive security in automobiles to augment vehicle security against cyber-attacks. Implementing different kinds of deep learning algorithms could bring abnormal advantages for attack detection methods. Overseen learning-based methods frequently result in high precision due to the extent of statistics provided by the platform. Adaptive security technology examines actions and occurrences to anticipate the threat beforehand and then deal with it. Two adaptive security mechanisms can be used, one at the receiver and the other at the transmitter side of a vehicular network. Vehicular networks can thus gain maximum benefit by combining these two techniques to maintain security using basic safety messages (BSMs). With the increase in cybersecurity attacks, these measures taken by companies can create market demand for automotive cybersecurity during the forecast period.
Automotive Cybersecurity Market: Recent Developments
- In January 2022, Aptiv PLC (NYSE: APTV), a global technology company, acquired Wind River, a global leader in delivering software for the intelligent edge, for $4.3 billion in cash. With Aptiv and Wind River's synergistic technologies and decades of experience delivering safety-critical systems, the company will hasten this journey to a software-defined future of the automotive industry.
- In November 2021, GuardKnox, an automotive technology company, and Carota, a global one-stop Over-The-Air (OTA) upgrade and remote diagnostic full solution provider, collaborated to deliver seamless OTA update capabilities for car manufacturers using secure end-to-end communication.
- In November 2022, BlackBerry Limited prolonged its use of Amazon Web Services (AWS), which will make BlackBerry QNX technology accessible to mission-critical entrenched systems developers for the first time in the cloud, meaningfully reducing time to market for their products. BlackBerry QNX will validate the company's industry-leading Real-Time Operating System (RTOS) along with its artificial intelligence (AI) data platform, BlackBerry IVY, running natively on Amazon Elastic Compute Cloud (Amazon EC2) instances, powered by AWS Graviton2 processors.
Automotive Cybersecurity Market: Synopsis
The study of the automotive cybersecurity market offers revenue and growth data sets of segments provided at the global, regional, and country levels. The report offers the historical data set for 2018-2022 and the forecast period of 2023-2033. For analysis, Quadrant Market Insights (QMI) has segregated the automotive cybersecurity market into four major segments as follows:
By Application
- Telematics
- Infotainment
- ADAS and Safety
- Power Train and Body Control Systems
- Communications and Navigation System
By Offering
- Hardware
- Software
By Type
- In-Vehicle
- Cloud Services
By Security
- Application Security
- Network Security
- Endpoint Security
The regional analysis of the automotive cybersecurity market is as follows:
North America
- U.S.
- Canada
- Mexico
Europe
- UK
- Germany
- France
- Russia
- Italy
- Spain
- Rest of Europe
Asia-Pacific
- China
- India
- Japan
- Australia
- Rest of Asia-Pacific
Latin America
- Brazil
- Argentina
- Chile
Middle East & Africa
- South Africa
- UAE
- Saudi Arabia
- Israel
Key players operating in the automotive cybersecurity industry are:
- Aptive PLC
- Broadcom Inc.
- Continental AG
- Denso Corporation
- Guard Knox Cyber-Technologies Ltd.
- Honeywell International, Inc.
- Harman International
- Karamba Security
- Robert Bosch GmbH
- Vector Informatik GmbH
Automotive Cybersecurity Market: Who Should Purchase, and How It Will Help Readers
- The report is best suited for top-level decision-makers, individuals who are supposed to take a leadership role or require market research to start a business, independent researchers, research institutes, and anyone who wishes to gain detailed strategic insights into the automotive cybersecurity market.
- This report provides a qualitative and quantitative analysis of the market segments, current trends, estimations, and dynamics of the automotive cybersecurity market analysis from 2018 to 2033 to identify the prevailing market opportunities.
- Market research and information related to key drivers, restraints, and opportunities are offered.
- Porter's five forces and PESTLE analysis highlight the potency of buyers and suppliers to enable stakeholders' market profit-oriented business decisions and strengthen their supplier-buyer network.
- An in-depth analysis of the automotive cybersecurity segmentation assists in determining 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 an analysis of the regional and global automotive cybersecurity industry trends, key players, market segments, application areas, and market growth strategies.
- The report offers insights from primary interviews and CXOs of major industry players. It also offers a comprehensive contact and event repository to ensure future collaborations among industry stakeholders.
Automotive Cybersecurity Market: Frequently Asked Questions (FAQ)
Q: How big is the automotive cybersecurity market?
A: The global automotive cybersecurity market showcased a revenue of USD 2.76 billion in 2022 and is projected to witness a compounded annual growth rate (CAGR) of more than 19.35% over the forecast period of 2023-2033.
Q: Does the report have several automotive cybersecurity numbers bifurcated by segments and regions?
A: The report offers a total number of automotive cybersecurity market, further bifurcated into segments and regions. Please refer to the TOC page for more information.
Q: What are the major trends in the automotive cybersecurity market?
A:Proliferation in demand for connected cars, increase in disposable income in developing regions, and implementation of cybersecurity standards to affect market growth of automotive cybersecurity.
Q: How can I get the sample Report on the automotive cybersecurity market?
A: The automotive cybersecurity market report sample can be obtained on demand from the website. Also, 24*7 chat support and direct call services are provided to procure the sample report
Q: Is it possible to purchase a specific or customized report as per my needs
A: Yes, it is possible to purchase a specific part of the report or edit the scope of the report at your convenience. Feel free to drop us the mail/talk to our customer support or schedule a conversation to procure a customized report.
Report Coverage
- Application
- Offering
- Type
- Security
- North America
- Europe
- Asia-Pacific
- Latin America
- Middle East & Africa
- Government increasing the adoption of connected cars and mandatory cybersecurity standards are fuelling the market growth
- Enhanced vehicle security using machine learning, cybersecurity platforms and adaptive security to create market demand
- Proliferation in development of common platforms posing threat to the market
Aptive PLC, Broadcom Inc., Continental AG, Denso Corporation, Guard Knox Cyber-Technologies Ltd., Honeywell International, Inc., Harman International, Karamba Security, Robert Bosch GmbH and Vector Informatik GmbH.
1. Introduction
1.1 Report Description
1.1.1 Definition
1.1.2 Abbreviations
1.2 Key Market Segments
1.3 Benefits to Stakeholders
1.4 Research Methodology
1.4.1 Market Scoping
1.4.1.1 Problem Identification
1.4.1.2 Defining the Market
1.4.2 Market Estimation
1.4.2.1 Data Mining
1.4.2.2 Product Analysis
1.4.2.3 Application Analysis
1.4.2.4 Market Engineering and Forecasting
1.4.2.4.1 Bottom-up Demand Side
1.4.2.4.2 Bottom-up Supply side
1.4.3 Market Authentication
1.4.3.1 Data Triangulation
1.4.3.1.1 Top-down Supply Side
1.4.3.1.2 Top-down Demand Side
1.4.3.1.3 Data Triangulation
1.4.3.2 Primary Insights and Industry feedback
1.4.4 Report Writing
2. Executive Summary
2.1 Market Snapshot
2.2 Macro Trends, Global Economic Factors and Import/Export Insights
2.3 Primary Insights
2.4 Application Insights
2.5 Equipment Insights
2.6 Mode of Operation Insights
2.7 Regional Insights
3. Market Overview
3.1 Market Segment and Scope
3.2 Top Investment Pockets
3.3 Key Strategic Initiatives
3.4 Automotive Cybersecurity Market Industry Ecosystem
3.5 Market Evolution
3.6 Patent Analysis
3.7 Technology Landscape
3.8 Regulatory Infrastructure
3.9 Porter’s Analysis
3.9.1 Bargaining Power of Buyer
3.9.2 Bargaining Power of Supplier
3.9.3 Threat of New Entrants
3.9.4 Threat of Substitutes
3.9.5 Industry Rivalry
3.10 PESTLE Analysis
3.11 Market Dynamics
3.11.1 Drivers
3.11.2 Restrains
3.11.3 Opportunities
3.12 Impact of COVID-19 on Automotive Cybersecurity Market
3.13 Russia-Ukraine War Impact on Automotive Cybersecurity Market
3.14 Growth Share Matrix
4. Automotive Cybersecurity Market, By Application
4.1 Major Impacting Factors, By Application
4.1.1 Key Market Trends and Growth Factors
4.1.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.1.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
4.2 Telematics
4.2.1 Key Market Trends and Growth Factors
4.2.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.2.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
4.3 Infotainment
4.3.1 Key Market Trends and Growth Factors
4.3.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.3.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
4.4 ADAS and Safety
4.4.1 Key Market Trends and Growth Factors
4.4.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.4.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
4.5 Power Train and Body Control Systems
4.5.1 Key Market Trends and Growth Factors
4.5.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.5.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
4.6 Communications and Navigation System
4.6.1 Key Market Trends and Growth Factors
4.6.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.6.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
5. Automotive Cybersecurity Market, By Offering
5.1 Major Impacting Factors, By Offering
5.1.1 Key Market Trends and Growth Factors
5.1.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
5.1.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
5.2 Hardware
5.2.1 Key Market Trends and Growth Factors
5.2.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
5.2.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
5.3 Software
5.3.1 Key Market Trends and Growth Factors
5.3.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
5.3.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
6. Automotive Cybersecurity Market, Type
6.1 Major Impacting Factors, By Type
6.1.1 Key Market Trends and Growth Factors
6.1.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
6.1.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
6.2 In-Vehicle
6.2.1 Key Market Trends and Growth Factors
6.2.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
6.2.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
6.3 Cloud Services
6.3.1 Key Market Trends and Growth Factors
6.3.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
6.3.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7. Automotive Cybersecurity Market, By Security
7.1 Major Impacting Factors, By Security
7.1.1 Key Market Trends and Growth Factors
7.1.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.1.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.2 Application Security
7.2.1 Key Market Trends and Growth Factors
7.2.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.2.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.3 Network Security
7.3.1 Key Market Trends and Growth Factors
7.3.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.3.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.4 Endpoint Security
7.4.1 Key Market Trends and Growth Factors
7.4.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.4.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8. Automotive Cybersecurity Market, By Region
8.1 Global Market Trends and Growth Factors
8.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.6 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
8.7 North America
8.7.1 Key Market Trends and Growth Factors
8.7.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.7.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.7.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.7.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.7.6 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8.7.7 U.S.
8.7.7.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.7.7.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.7.7.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.7.7.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.7.7.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.7.8 Canada
8.7.8.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.7.8.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.7.8.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.7.8.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.7.8.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.7.9 Mexico
8.7.9.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.7.9.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.7.9.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.7.9.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.7.9.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.8 Europe
8.8.1 Key Market Trends and Growth Factors
8.8.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.8.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.8.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.8.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.8.6 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8.8.7 UK
8.8.7.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.8.7.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.8.7.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.8.7.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.8.7.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.8.8 Germany
8.8.8.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.8.8.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.8.8.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.8.8.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.8.8.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.8.9 France
8.8.9.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.8.9.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.8.9.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.8.9.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.8.9.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.8.10 Russia
8.8.10.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.8.10.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.8.10.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.8.10.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.8.10.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.8.11 Italy
8.8.11.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.8.11.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.8.11.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.8.11.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.8.11.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.8.12 Rest of Europe
8.8.12.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.8.12.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.8.12.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.8.12.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.8.12.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.9 Asia-Pacific
8.9.1 Key Market Trends and Growth Factors
8.9.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.9.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.9.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.9.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.9.6 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8.9.7 China
8.9.7.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.9.7.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.9.7.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.9.7.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.9.7.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.9.8 India
8.9.8.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.9.8.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.9.8.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.9.8.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.9.8.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.9.9 Japan
8.9.9.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.9.9.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.9.9.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.9.9.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.9.9.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.9.10 Australia
8.9.10.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.9.10.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.9.10.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.9.10.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.9.10.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.9.11 Rest of Asia-Pacific
8.9.11.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.9.11.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.9.11.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.9.11.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.9.11.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.10 Latin America
8.10.1 Key Market Trends and Growth Factors
8.10.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.10.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.10.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.10.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.10.6 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8.10.7 Brazil
8.10.7.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.10.7.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.10.7.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.10.7.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.10.7.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.10.8 Argentina
8.10.8.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.10.8.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.10.8.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.10.8.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.10.8.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.10.9 Chile
8.10.9.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.10.9.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.10.9.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.10.9.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.10.9.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.11 Middle East and Africa
8.11.1 Key Market Trends and Growth Factors
8.11.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.11.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.11.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.11.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.11.6 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8.11.7 South Africa
8.11.7.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.11.7.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.11.7.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.11.7.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.11.7.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.11.8 UAE
8.11.8.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.11.8.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.11.8.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.11.8.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.11.8.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.11.9 Saudi Arabia
8.11.9.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.11.9.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.11.9.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.11.9.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.11.9.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
8.11.10 Israel
8.11.10.1 Trade Factor and Economic Indicator within Automotive Cybersecurity Market
8.11.10.2 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
8.11.10.3 Market Size and Forecast, by Offering, 2018-2033, (USD Billion)
8.11.10.4 Market Size and Forecast, by Type, 2018-2033, (USD Billion)
8.11.10.5 Market Size and Forecast, by Security, 2018-2033, (USD Billion)
9. Markets-Competitive Benchmarking & Company Profiles
9.1 Competitive Benchmarking
9.1.1 Company Market Share
9.1.2 Product Mapping
9.1.3 Competitive Heat map
9.2 AT&T
9.2.1 Company Overview
9.2.2 Financial Analysis
9.2.3 Product Offering
9.2.4 Strategic Initiatives
9.2.5 SWOT
9.2.6 Ansoff Matrix
9.3 Avast Software
9.3.1 Company Overview
9.3.2 Financial Analysis
9.3.3 Product Offering
9.3.4 Strategic Initiatives
9.3.5 SWOT
9.3.6 Ansoff Matrix
9.4 Cisco
9.4.1 Company Overview
9.4.2 Financial Analysis
9.4.3 Product Offering
9.4.4 Strategic Initiatives
9.4.5 SWOT
9.4.6 Ansoff Matrix
9.5 FireEye
9.5.1 Company Overview
9.5.2 Financial Analysis
9.5.3 Product Offering
9.5.4 Strategic Initiatives
9.5.5 SWOT
9.5.6 Ansoff Matrix
9.6 IBM
9.6.1 Company Overview
9.6.2 Financial Analysis
9.6.3 Product Offering
9.6.4 Strategic Initiatives
9.6.5 SWOT
9.6.6 Ansoff Matrix
9.7 Kaspersky Lab.
9.7.1 Company Overview
9.7.2 Financial Analysis
9.7.3 Product Offering
9.7.4 Strategic Initiatives
9.7.5 SWOT
9.7.6 Ansoff Matrix
9.8 Microsoft
9.8.1 Company Overview
9.8.2 Financial Analysis
9.8.3 Product Offering
9.8.4 Strategic Initiatives
9.8.5 SWOT
9.8.6 Ansoff Matrix
9.9 McAfee, LLC
9.9.1 Company Overview
9.9.2 Financial Analysis
9.9.3 Product Offering
9.9.4 Strategic Initiatives
9.9.5 SWOT
9.9.6 Ansoff Matrix
9.10 Palo Alto Networks, Inc
9.10.1 Company Overview
9.10.2 Financial Analysis
9.10.3 Product Offering
9.10.4 Strategic Initiatives
9.10.5 SWOT
9.10.6 Ansoff Matrix
9.11 WatchGuard Technologies, Inc.
9.11.1 Company Overview
9.11.2 Financial Analysis
9.11.3 Product Offering
9.11.4 Strategic Initiatives
9.11.5 SWOT
9.11.6 Ansoff Matrix
10. Industry Connects and Upcoming Seminars
