StreetDrone Proposes Top 10 Safety Rules for AV Developers

Report stresses importance of retaining OE safety-related controls and systems.

To deploy AVs on public roads, StreetDrone builds its own by-wire vehicle control system into standard production models, including the Nissan e-NV200. Shown is the company’s system together with other components. (StreetDrone)

OE vehicle safety systems must remain connected, in hard engineering terms and intellectually, during autonomous vehicle (AV) development, stresses Mike Potts, CEO of StreetDrone, a company specializing in AV design, engineering, and testing. “Providing the ability to allow a vehicle to drive itself means adding at least 10x in additional technology, all of which must obey safety criteria in its entirety,” Potts asserted.

StreetDrone CEO Mike Potts regards his company’s recently published AV rule guide as addressing a vital industry need. (StreetDrone)

To help those involved in AV R&D – from OEMs and universities to transport and delivery operators – StreetDrone has published an in-depth safety report based on its first-hand experience of ensuring that a vehicle’s own OE-installed control systems form an integral part of the overall autonomous system. The report  proposes a set of “must have” rules. They address what StreetDrone considers to be “a systemic oversight across the industry of vital hardware considerations,” Potts said. “Too often, the vehicle element of the autonomous technology stack is not fully considered.”

StreetDrones claims to be the first business in Europe to have run a public-road autonomous trial using open-source, self-driving hardware in 2019. Its expertise  spans the full stack of AV disciplines from hardware and mechanical design through to AI and software, together with wide experience of city center highway trials.

The AV “operational safety case” as seen by StreetDrone. (StreetDrone)

All vehicles used in the company’s testing and development are adapted from regular production models, with components such as steering and braking motors, sensors, cameras, a computer, data networking and 4/5G/Wi-Fi communications added. Its platform approach operates upstream, leaving the OE systems functionally intact rather than reverse-engineering or ‘hacking’ existing vehicle control system capabilities, according to Potts.

The proposed set of rules for AV design, engineering, development and testing include:

  1. No hacking, spoofing or reverse engineering of the base vehicle control systems (those installed by the OEM) when adding StreetDrones’ drive-by-wire system for autonomy
  2. No single points-of-failure in the autonomous drive-by-wire system, including in the sensors used for system monitoring
  3. Base vehicle safety systems, like emergency braking, always take precedence over self-driving commands
  4. The control “state” of the vehicle – whether the self-driving software or the safety driver is in control – must be clear and understood by the safety driver
  5. Comprehensive vehicle deployment protocols are based on published safety best-practices
  6. Clearly defined operational parameters, for instance where, geographically, any vehicles are able to travel, are published and include all aspects of safety driver responsibilities
  7. Safety drivers require full engineering insight and understanding across the vehicle system
  8. Errors must be traceable through all levels of the autonomous system’s data, including at vehicle level
  9. In Britain, collection and transparency of vehicle data must be compliant with the U.K. Department of Transport’s Automated Testing Code of Practice 1
  10. Autonomous software testing incorporates comprehensive simulation of real-world scenarios

StreetDrones’ current hardware platforms embrace the L7e class Renault Twizy and the Nissan e-NV200 in various iterations, using StreetDrone’s autonomous-ready technology conversion. Its proprietary control system works in parallel with the vehicle’s original safety systems to ensure all OEM safety validation is maintained.