Operators collaborate with industry partners to drive new mission-critical services globally using 5G
01 March 2018
BT, Verizon and Ericsson, in partnership with academics at King's College London and autonomy-as-a-service experts, Unmanned Life, have teamed up to demonstrate how 5G technology can enable a raft of mission critical services globally and show why 5G will deliver so much more than just enhanced mobile broadband.
BT and Verizon have been researching the power of technologies like virtualization, edge cloud computing and federated network slicing as key enablers for the next generation of roaming, allowing operators to offer their customers premium global services while ensuring quality of service excellence.
Previous generations of mobile technology have not been capable of supporting certain kinds of mission critical communications, in particular, those that require real-time communications and specifically when operating in a different country or across different geographical locations. However, through deploying 5G radio, core and network slicing, these requirements can be met. By harnessing 5G technology, together with virtualized network functions, operators can have a deeper integration within each other's networks by creating network slices, federated across operators, which enables ultra-low latency services to exist across countries and continents.
On February 21, 2018, BT, Verizon, King's, Ericsson and Unmanned Life demonstrated autonomous control and management of a fleet of drones in central London, which was launched from the US by Verizon, on a dedicated 5G network slice within BT's network. These techniques can deliver a vast array of applications, including mission critical services that require ultra-low latency and high availability to achieve real-time feedback loops that enable applications like remote operations regardless of geographical location. These applications could include advanced disaster recovery services using drones, such as delivery of equipment, medicine, food, water and blood.
The demonstration, which utilized new pre- commercial 5G radio, was achieved by building a 5G core and creating two network slices with similar characteristics: one, a low latency breakout for a BT end user; the other, a Verizon customer with Verizon network functionality with a local UK breakout.
The Verizon user on BT's network is recognized and authenticated in the normal manner except that this user, with a low latency requirement, is directed to Verizon's UK network slice where a low latency service is provided. This ensures the path between the end device and the control application is kept to a minimum and enables real-time control.
By instantiating Verizon network functions and applications within BT's network, customers can experience the same level of service in the UK as they experience in the US. This advancement opens up a wide range of opportunities and makes it possible to deliver applications such as remote and/or autonomous control of drones and rovers, to real-time search and rescue applications – something that was not previously possible.
BT, Verizon, Ericsson, King's and Unmanned Life demonstrated a number of use cases at the University's central London location. The use cases were centered around disaster response scenarios including:
- Delivery of emergency kit or rescue equipment to a disaster area using drones
- Search missions with HD imaging in disaster recovery zones, specifically areas of difficult access
- Coordinated missions where multi drone fleets from multiple countries could be used to inspect an emergency area or perform specific tasks (e.g. load handling)
These use cases were enabled by an AI driven autonomous platform provided by Unmanned Life. Together, the companies showed how emergency response teams from different countries can immediately deploy and control their drone fleets in a remote disaster zone with no need for an in-country subscription with a local operator.
These applications demonstrate that combining 5G radio, with its inherent higher bandwidth and lower latency characteristics, together with network slicing and network function virtualization, can enable operators like BT and Verizon to deliver specialized services to public and private sectors on a global basis. In addition to the use cases demonstrated, this technology can assist in other use cases including health and remote surgery applications and assisted driving or autonomous vehicles.