This course has been developed for the Chinese auto industry to provide engineers and software developers involved in V2X and related industries with important knowledge about vehicle cybersecurity, including basic cybersecurity practices, interpretation of SAE J3061 standards, connected vehicle attack & defense approaches and the Security Development Lifecycle (SDL).
In addition to presenting an overview of the standard, this course highlights the major changes introduced in the second edition, which extends the standard"s scope to include all vehicles (excluding special vehicles), the objective-oriented confirmation measures approach, and references to Cybersecurity at the Concept and System Level development.
This allows an organization to develop an internal cybersecurity process consistent with its other processes in order to build cybersecurity robustness into their cyber-physical systems. ...This web seminar will define key concepts in cybersecurity and discuss what a cybersecurity process consists of and why one is needed for the development of cyber-physical vehicle systems.
The automotive industry is the new "battleground" for cybersecurity. Following the path of desktops/laptops, tablets, and mobile phones, the automotive industry is now the "hot" area for both academic researchers and hackers. ...What does cybersecurity mean? Who is attacking and why? What must we change? What can stay the same? What is the larger organization's role in cyber?
Despite the advantages of electronic flight bags (EFB), passenger entertainment and email access during flights, and the ability to access aircraft repair manuals electronically, computer interconnectivity throughout aviation has opened the aviation sector to cyber-attacks that could impact flights, data, and safety. This two-day seminar is intended to introduce aviation professionals to the need to implement cyber security throughout commercial aviation including the supply chain.
Embedded hardware is everywhere you look today from your vehicle’s infotainment system to refrigerator to medical devices and everything else in-between. With so much exposure one would think that such devices are secure against attack; however, sadly for many devices this is not the case. For proof, just look no further than your local news reports. They are full of reports on devices being hacked. So, as engineers, how do we go about first identifying and mitigating (or capitalizing) the potential security vulnerabilities within these devices?
This session will showcase subject matter experts talking about successful applications of blockchain in automotive and discuss what to be cognoscente of when applying it to supply chain management, Cybersecurity and other applications.
This session focuses on cybersecurity for cyber-physical vehicle systems. Topics include: design, development and implementation of security-critical cyber-physical vehicle systems, cybersecurity design, development, and implementation strategies, analysis methodologies, process and life-cycle management, comparisons of system safety and cybersecurity, etc. ...Topics include: design, development and implementation of security-critical cyber-physical vehicle systems, cybersecurity design, development, and implementation strategies, analysis methodologies, process and life-cycle management, comparisons of system safety and cybersecurity, etc. ...Topics include: design, development and implementation of security-critical cyber-physical vehicle systems, cybersecurity design, development, and implementation strategies, analysis methodologies, process and life-cycle management, comparisons of system safety and cybersecurity, etc. Application areas include: security-critical automotive systems as well as other security-critical ground vehicle and aviation systems.
How will companies manage the supply chain (with new contributors and competitors), reduce time to market, manage cost, and ensure quality while addressing cybersecurity threats and the need for functional safety? Systems challenges abound. What changes in business strategies are addressing these challenges?
This panel addresses the necessity of vehicle cybersecurity safety assurance and procedures and metrics to indicate the achievement of a certain level of safety performance including the protection of vehicle electronic systems, communication networks, control algorithms, software, and transportation system users.
The verification and validation of the cybersecurity posture of modern vehicles is becoming more and more important as more software and threat surfaces are added to vehicles. ...This panel will discuss how the cybersecurity of modern vehicles can be verified and validated. Questions that will frame the discussion include: How is pen testing currently performed? ...Can OEMs be expected to aggressively uncover cybersecurity vulnerabilities? Are pen testing results appropriately rolled back into the development process?
SAE and Synopsys commissioned the first-ever independent study of the cybersecurity posture of the automotive industry. Those findings were published in a free study in February and broadly disseminated to industry.
The caveat to these additional capabilities is issues like cybersecurity, complexity, etc. This paper is an exploration into FuSa and CAVs and will present a systematic approach to understand challenges and propose potential framework, Intelligent Vehicle Monitoring for Safety and Security (IVMSS) to handle faults/malfunctions in CAVs, and specifically autonomous systems.
Autonomous driving systems and connected mobility are the next big developments for the car manufacturers and their suppliers during the next decade. To achieve the high computing power needs and fulfill new upcoming requirements due to functional safety and security, heterogeneous processor architectures with a mixture of different core architectures and hardware accelerators are necessary. To tackle this new type of hardware complexity and nevertheless stay within monetary constraints, high performance computers, inspired by state of the art data center hardware, could be adapted in order to fulfill automotive quality requirements. The European Processor Initiative (EPI) research project tries to come along with that challenge for next generation semiconductors. To be as close as possible to series development needs for the next upcoming car generations, we present a hybrid semiconductor system-on-chip architecture for automotive.