Trains, planes, automobiles… they all move fast — their network should, too. Transportation systems depend on a strong, secure network – drivers, passengers, employees, and even autonomous operations all rely on it.
5G connectivity is key to unlocking next-gen transportation networks and applications. Given the critical importance of safety in the transportation ecosystem, in addition to ensuring a seamless user experience, having ubiquitous and extremely reliable connectivity is mission critical. Managing multi-access technologies such as public 5G, private 5G, and Wi-Fi will play a pivotal role in ensuring reliable and secure connectivity across transportation use cases.
Traditional networks forced data back to centralized nodes, which increased latency by being further way from where the data originated. With 5G, these nodes can now be decentralized and distributed in cloud deployments, bringing applications and the internet closer to the vehicle, and allowing unprecedented low latency connectivity. Additionally, 5G provides improved security to aid car manufacturers and fleet managers to meet connected vehicle application security requirements.,
Next-gen experiences in the connected car
The connected car has evolved since the early days of sending a signal once the vehicle was in an accident. Today’s connected vehicle has become a bidirectional communicational channel. It needs to be able to communicate with the internet, other vehicles, roadways, intersections, and more for traffic, safety and even entertainment use cases. Automotive OEMs must navigate how to seamlessly move a vehicle between environments, using multiple access technologies, and maintain network visibility, control, and reporting.
Connected cars are the most sophisticated Internet of Things (IoT) devices today with use-cases (onboard applications or services) ranging from notifying drivers of upcoming road hazards, emergency vehicles, or pedestrians in intersections, to telematics services that enable predictive maintenance of vehicle components, infotainment services to enable audio and video streaming apps (Netflix, Spotify), on-board Wi-Fi, high-definition maps, and a marketplace for retail use-cases.
In addition to these use-cases, OEMs are looking at 5G as a critical enabler for autonomous driving with V2X services – where the car communicates with neighboring vehicles, roadway infrastructure, and an edge cloud – which requires periodic mapping updates and predictive intelligence with automated assurance to detect service anomalies and drive corrective actions. Additionally, software defined vehicles require frequent software updates (FOTA/SOTA) which require reliable, high-bandwidth connectivity.
Webex integration is another application that OEMs are choosing to enable as a new service for their customers by making their vehicle a mobile connected office. Ford and Mercedes Benz AG’s recent partnerships with Cisco to enable WebEx conferencing in their vehicles pave the way for mainstream adoption by other OEMs.
Commercial Vehicle (CV) OEMs are also leading adoption of autonomous trucking (AT) technologies and building homegrown fleet management solutions. Pervasive connectivity with edge deployments supporting mission critical V2X communications is a pre-requisite for CV OEMs to embrace autonomous trucking. Platooning, considered to be the first commercial AT application, is expected to generate TCO savings of ~45% by the end of this decade. Fleet management solutions for electrified, autonomous trucks will subsequently leverage 5G connectivity for predictive diagnostics and maintenance of vehicle components and powertrain. Figure 1 has an overview of connected vehicle 5G-enhanced use-cases.
Figure 1. Connected vehicle 5G-enhanced use cases
Cisco’s vision for a 5G connected transportation future
To achieve this vision of a 5G connected future in transportation, we are enabling vehicle OEMs to take the control needed to deliver a safer and more sustainable fleet. That requires deep integration with networks and a deep understanding of the quality of service (QoS) that comes from it.
QoS becomes critical for services that depend on specific characteristics or SLAs like safety or autonomous driving. OEMs need to know how vehicles are performing, and to be able to address issues as they arise, not open a ticket with their communications service provider (CSP) and wait for a response. They need a framework where CSPs allow them certain control and configuration privileges, like applying a slice to a network service or deploying additional edge nodes when capacity dictates they are needed.
This level of control will allow OEMs to provide unique customer experiences, with a reliable QoS to deliver their services. The car becomes a digital extension of the passenger’s journey, whether it’s a privately owned vehicle, or a shared mobility service. And this goes beyond the connected car.
OEMs and municipalities must work together to build intelligent systems that will power the connected roads and corridors. They must learn how to bring disparate sources of data together, process them into intelligent decisions and then feed that information back to drivers or infrastructure that can act upon it.
The next generation of both cars and networks will change transportation and mobile networks in ways we can’t even fathom yet. But unless you have a strategy for how to bring these two together, you will struggle to unlock the power that is just at our fingertips.
Source: cisco.com
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