Infrastructure-Assisted Collaborative Perception in Automated Valet Parking: Enhancing Safety
מושגי ליבה
Enhancing safety in Automated Valet Parking through infrastructure-assisted collaborative perception.
תקציר
Introduction to the challenges of environmental perception in AVP.
Proposal of a BEV feature-based CP network architecture for infrastructure-assisted AVP systems.
Techniques used for data compression and fusion to fit within NR-V2X network constraints.
Observations from synthetic AVP dataset showing improved perception performance, especially for pedestrians.
Demonstration of increased safe cruising speed by up to 3m/s in safety-critical scenarios.
Framework of an infrastructure-assisted AVP system with route planning and collision avoidance modules.
Infrastructure-Assisted Collaborative Perception in Automated Valet Parking
סטטיסטיקה
"The bandwidth can hardly accommodate raw sensor data such as HD images or LiDAR point clouds, which take tens of megabytes per second at a sampling rate of 10Hz."
"The size of a BEV feature map is effectively compressed to fit in the feasible data rate of the NR-V2X network."
ציטוטים
"Inspired by collaborative perception (CP) widely investigated in open roads, we propose an infrastructure-assisted CP solution to address the safety issues of AVP."
"Our main contributions are summarized as follows: A BEV feature-based CP architecture is proposed, features are effectively compressed to fit within NR-V2X communication rates, and safety performance is tested in two typical scenarios."
How can the deployment position and configuration of infrastructures be optimized for smart parking garages?
In optimizing the deployment position and configuration of infrastructures for smart parking garages, several factors need to be considered. Firstly, strategically placing roadside sensors in critical areas such as intersections, blind spots, and pedestrian crossings can enhance the overall perception capabilities of connected vehicles. These sensors should cover a wide field of view to minimize occlusions and provide comprehensive environmental data.
Furthermore, leveraging infrastructure-to-vehicle communication protocols like NR-V2X can facilitate seamless data transmission between roadside sensors and connected vehicles. By ensuring proper synchronization references in environments where GNSS signals are unavailable (such as underground or multi-story garages), the accuracy of localization information can be improved.
Additionally, optimizing the density and coverage area of infrastructure sensors based on traffic flow patterns, congestion hotspots, and potential collision zones is crucial. This strategic placement can enhance safety measures within parking facilities by providing real-time data on vehicle movements, pedestrian activities, and potential hazards.
Moreover, considering scalability in infrastructure deployment is essential to accommodate future advancements in automated driving technologies. Flexibility in sensor configurations that allow for easy upgrades or additions as technology evolves will ensure long-term effectiveness in enhancing safety and efficiency within smart parking environments.
How might advancements in collaborative perception impact other areas beyond automated valet parking?
Advancements in collaborative perception have far-reaching implications beyond automated valet parking (AVP) systems. One significant area that could benefit from these advancements is urban mobility management. By implementing collaborative perception techniques across interconnected vehicles and infrastructure networks, cities can improve traffic flow optimization, reduce congestion levels, enhance road safety measures through early hazard detection systems.
Moreover,
collaborative perception has applications
in autonomous delivery services,
where coordinated interactions between
autonomous vehicles enable efficient
parcel deliveries with minimal human intervention.
This could revolutionize logistics operations,
improve delivery timelines,
and optimize resource utilization.
Another area that could see a positive impact
is public transportation systems.
By integrating collaborative perception technologies into buses,
trains,
or trams,
public transport services can offer enhanced safety features such as pedestrian detection alerts at stops or junctions.
Additionally,
the application of collaborative perception techniques
in emergency response scenarios could significantly improve situational awareness for first responders.
Connected emergency vehicles equipped with advanced sensing capabilities would be able to share real-time data about road conditions,
obstacles,
or incidents ahead with other emergency units en route to a crisis site.
Overall,
advancements in collaborative perception have the potential to transform various sectors beyond AVP by enhancing operational efficiencies,
increasing safety standards,
and enabling more intelligent decision-making processes based on shared environmental insights.
What are the potential implications of communication delays
and localization errors on infrastructure-assisted CP systems?
Communication delays
can significantly impact the effectiveness
of infrastructure-assisted Collaborative Perception (CP) systems
by introducing latency issues
that hinder real-time data exchange between roadside sensors
and connected vehicles.
These delays may lead to inaccuracies
in object detection results,
compromising overall system reliability
Localization errors
pose another challenge
for infrastructure-assisted CP systems.
Inaccurate positioning information
can result in misalignments
between sensor inputs from different sources,
leading to incorrect fusion outcomes
during environment mapping or object recognition tasks.
Furthermore,
communication delays
combined with localization errors
may exacerbate coordination challenges among networked entities,
resulting
in suboptimal decision-making processes
within an automated system.
To mitigate these implications,
robust error correction mechanisms
real-time feedback loops,
redundant communication channels,
and accurate calibration procedures
should be implemented
to address communication delays
localization errors effectively.
By prioritizing system resilience
against these challenges,
infrastructure-assisted CP systems
can maintain high performance levels
enhance overall operational efficiency.
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Infrastructure-Assisted Collaborative Perception in Automated Valet Parking: Enhancing Safety
Infrastructure-Assisted Collaborative Perception in Automated Valet Parking
How can the deployment position and configuration of infrastructures be optimized for smart parking garages?
How might advancements in collaborative perception impact other areas beyond automated valet parking?
What are the potential implications of communication delays