CHROMA

CHROMA - 2025

2025Activity reportProject-TeamCHROMA

RNSR: 201521334D

Research‌ centers Inria Lyon Centre Inria Centre at Université‌ Grenoble Alpes
In partnership with:Institut national des‌ sciences appliquées de Lyon
Team name: Cooperative and‌ Human-aware Robot Navigation in Dynamic Environments
In collaboration‌ with:Centre d'innovation en télécommunications et intégration de‌ services

Creation of the Project-Team: 2017 December 01‌

Each year, Inria research teams publish an Activity‌ Report presenting their work and results over the‌ reporting period. These reports follow a common structure,‌ with some optional sections depending on the specific‌ team. They typically begin by outlining the overall‌ objectives and research programme, including the main research‌ themes, goals, and methodological approaches. They also describe‌ the application domains targeted by the team, highlighting‌ the scientific or societal contexts in which their‌ work is situated.

The reports then present the‌ highlights of the year, covering major scientific achievements,‌ software developments, or teaching contributions. When relevant, they‌ include sections on software, platforms, and open data,‌ detailing the tools developed and how they are‌ shared. A substantial part is dedicated to new‌ results, where scientific contributions are described in detail,‌ often with subsections specifying participants and associated keywords.‌

Finally, the Activity Report addresses funding, contracts, partnerships,‌ and collaborations at various levels, from industrial agreements‌ to international cooperations. It also covers dissemination and‌ teaching activities, such as participation in scientific events,‌ outreach, and supervision. The document concludes with a‌ presentation of scientific production, including major publications and‌ those produced during the year.

Keywords

Computer Science‌ and Digital Science

A1.3.2. Mobile distributed systems
A1.5.2.‌ Communicating systems
A2. Software sciences
A2.3. Embedded and‌ cyber-physical systems
A5.1. Human-Computer Interaction
A5.6.2. Augmented reality‌
A5.6.3. Avatar simulation and embodiment
A5.10.1. Design
A5.10.2.‌ Perception
A5.10.3. Planning
A5.10.4. Robot control
A5.10.5. Robot‌ interaction (with the environment, humans, other robots)
A5.10.6.‌ Swarm robotics
A5.11.1. Human activity analysis and recognition‌
A6.1.2. Stochastic Modeling
A6.1.3. Discrete Modeling (multi-agent, people‌ centered)
A6.2.3. Probabilistic methods
A6.2.6. Optimization
A6.4.1. Deterministic‌ control
A6.4.2. Stochastic control
A6.4.3. Observability and Controlability‌
A6.4.4. Stability and Stabilization
A7.1.1. Distributed algorithms
A8.2.‌ Optimization
A8.2.1. Operations research
A8.2.2. Evolutionary algorithms
A8.11.‌ Game Theory
A9.2. Machine learning
A9.2.1. Supervised learning‌
A9.2.2. Unsupervised learning
A9.2.3. Reinforcement learning
A9.2.4. Optimization‌ and learning
A9.2.5. Bayesian methods
A9.2.6. Neural networks‌
A9.2.8. Deep learning
A9.5. Robotics and AI
A9.6.‌ Decision support
A9.7. AI algorithmics
A9.9. Distributed AI,‌ Multi-agent
A9.10. Hybrid approaches for AI
A9.12.1. Object‌ recognition
A9.12.2. Activity recognition
A9.12.4. 3D and spatio-temporal‌ reconstruction
A9.12.5. Object tracking and motion analysis
A9.12.6.‌ Object localization
A9.12.7. Visual servoing
A9.15. Symbolic AI‌

2 Overall objectives

2.1 Origin‌ of the project

Chroma‌ is a bi-localized project-team‌‌ at Inria Lyon and Inria Grenoble (in Auvergne-Rhône-Alpes‌ region). The project was‌ launched in 2015 before‌‌ it became officially an Inria project-team on December‌ 1st, 2017. It brings‌ together experts in perception‌‌ and decision-making for mobile robotics and intelligent transport,‌ all of them sharing‌ common approaches that mainly‌‌ relate to the fields of Artificial Intelligence and‌ Control. It was originally‌ founded by members of‌‌ the working group on robotics at CITI lab‌1, led by‌ Prof. Olivier Simonin (INSA‌‌ Lyon2), and members from Inria project-team‌ eMotion (2002-2014), led by‌ Christian Laugier, at Inria‌‌ Grenoble. Academic members of‌ the team are Olivier Simonin (Prof. INSA Lyon),‌ Anne Spalanzani (Prof., U. Grenoble-Alpes), Christian Laugier (Inria‌ researcher emeritus, Grenoble), Agostino Martinelli (Inria researcher CR,‌ Grenoble), Alessandro Renzaglia (Inria researcher CR, Lyon, since‌ 2021) and Baudouin Saintyves (Inria researcher ISFP, Lyon,‌ since 2024). Jacques Saraydaryan and Fabrice Jumel are‌ two associate members as lecturer-researcher from CPE Lyon,‌ since 2015.

Before joining the University of Groningen‌ (NL) as Professor, Jilles Dibangoye was a member‌ of the team from 2015 to 2023 (as‌ Asso. Prof. INSA Lyon). Christine Solnon (Prof. INSA‌ Lyon) was also a member of the team‌ from 2020 to 2024.

2.2 Research themes

The‌ overall objective of Chroma is to address fundamental‌ and open issues that lie at the intersection‌ of the emerging research fields called “Human Centered‌ Robotics”3, “Multi-Robot Systems"4, and‌ AI for humanity. More precisely, our goal is‌ to design algorithms and models that allow autonomous‌ agents to perceive, decide, learn, and finally adapt‌ to their environment. A focus is given to‌ unknown and human-populated environments, where robots or vehicles‌ have to navigate and cooperate to fulfill complex‌ tasks. In this context, recent advances in‌ embedded computational power, sensor and communication technologies, and‌ miniaturized mechatronic systems, make the required technological breakthroughs‌ possible.

To address the mentioned challenges, we take‌ advantage of recent advances in: probabilistic methods, machine‌ learning, planning and optimization methods, multi-agent decision making,‌ and swarm intelligence. We also draw inspiration from‌ other disciplines such as Sociology, to take into‌ account human models, or Physics/Biology, to design self-organized‌ robots.

Chroma research is organized in two thematic‌ axes : i) Perception and Situation Awareness ii)‌ Decision Making. Next, we elaborate more about these‌ axes.

Perception and Situation Awareness. This axis aims‌ at understanding complex dynamic scenes, involving mobile objects‌ and human beings, by exploiting prior knowledge and‌ streams of perceptual data coming from various sensors.‌ To this end, we investigate three complementary research‌ problems:
- Bayesian & AI based Perception: How‌ to interpret in real-time a complex dynamic scene‌ perceived using a set of different sensors, and‌ how to predict the near future evolution of‌ this dynamic scene and the related collision risks‌ ? How to extract the semantic information and‌ to process it for the autonomous navigation step.‌
- Modeling and simulation of dynamic environments: How‌ to model or learn the behavior of dynamic‌ agents (pedestrians, cars, cyclists...) in order to better‌ anticipate their trajectories?
- Robust state estimation: Acquire‌ a deep understanding on several sensor fusion problems‌ and investigate their observability properties in the case‌ of unknown inputs.

Decision making. This second axis‌ aims to design algorithms and architectures that can‌ achieve both scalability and quality for decision making‌ in intelligent robotic systems and more generally for‌ problem solving. Our methodology builds upon advantages of‌ three (complementary) approaches: planning & control, machine learning,‌ and swarm intelligence.
- Planning under constraints: In this theme we study‌ planning algorithms for a‌ single or a fleet‌‌ of mobile robots when they face complex and‌ dynamics environments, i.e. populated‌ by humans and/or mostly‌‌ unknown. Approaches include heuristics and exact methods (eg.‌ constraint programming).
- Machine learning‌: We search for‌‌ efficient and adaptive behaviours based on deep &‌ reinforcement learning methods to‌ solve complex single or‌‌ multi-agent decision-making tasks.
- Decentralized models: This theme‌ explores decentralised algorithms and‌ models for the control‌‌ of multi-agent/multi-robot systems. In particular, we study swarm‌ robotics for its ability‌ to generate systems that‌‌ are self-organising, robust and adaptive to perturbations.

Chroma‌ is also concerned with‌ applications and transfer of‌‌ the scientific results. Our main applications include autonomous‌ and connected vehicles, service‌ robotics, exploration & mapping‌‌ tasks with ground and aerial robots. Chroma is‌ currently involved in several‌ projects in collaboration with‌‌ automobile companies (Renault, Toyota) and robotics compagnies such‌ as Enchanted Tools (see‌ Section 4).

3 Research‌‌ program

3.1 Introduction

The Chroma team aims to‌ deal with different issues‌ of autonomous robot(s) navigation:‌‌ perception, decision-making and cooperation. Figure 1 schemes the‌ different themes and sub-themes‌ investigated by Chroma.

Figure‌‌ 1: Research themes of the team and‌ their relation

We present‌ here after our approaches‌‌ to address these different themes of research, and‌ how they combine altogether‌ to contribute to the‌‌ general problem of robot navigation. Chroma pays particular‌ attention to the problem‌ of autonomous navigation in‌‌ highly dynamic environments populated by humans and cooperation‌ in multi-robot systems. We‌ share this goal with‌‌ other major robotic laboratories/teams in the world, such‌ as Autonomous Systems Lab‌ at ETH Zurich, Robotic‌‌ Embedded Systems Laboratory at USC, KIT 5 (Prof.‌ Christoph Stiller lab and‌ Prof. Ruediger Dillmann lab),‌‌ UC Berkeley, Vislab Parma (Prof. Alberto Broggi), and‌ iCeiRA 6 laboratory in‌ Taipei, to cite a‌‌ few. Chroma collaborates at various levels (visits, postdocs,‌ research projects, common publications,‌ etc.) with most of‌‌ these laboratories.

3.2 Perception and Situation Awareness

Project-team‌ positioning

The team carries‌ out research across the‌‌ full (software) stack of an autonomous driving system.‌ This goes from perception‌ of the environment to‌‌ motion forecasting and trajectory optimization. While most of‌ the techniques that we‌ develop can stand on‌‌ their own and are typically tested on our‌ experimental platforms, we slowly‌ move towards their complete‌‌ integration. This will result in a functioning autonomous‌ driving software stack. Beyond‌ that point, we envision‌‌ focusing our research on developing new methods that‌ improve the individual performance‌ of each of the‌‌ stack’s components, as well as the global performance.‌ This is similar to‌ how autonomous driving companies‌‌ operate (e.g. Waymo, Cruise, Tesla). The research topics‌ that we explore are‌ addressed by a very‌‌ long list of international research laboratories and private‌ companies. However, in terms‌ of scope, we find‌‌ the research groups of‌ Prof. Dr.-Ing. Christoph Stiller (KIT), Prof. Marcelo Ang‌ (NUS), Prof. Daniela Rus (MIT) and Prof. Wolfram‌ Burgard (TRI California) to be the closest to‌ us; we have active interconnections with these research‌ groups (e.g. in the scope of the IEEE‌ RAS Technical Committee AGV-ITS we are co-chairing any‌ of the related annual Workshops). At the national‌ level, we are cooperating in the framework of‌ several R&D projects with UTC, Institut Pascal Clermont-Ferrand,‌ University Gustave Eiffel, and the Inria Teams ASTRA,‌ ACENTAURI and CONVECS. Our main research originality relies‌ in the combination of Bayesian approaches, AI technologies,‌ Human-Vehicle interactions models, Robust State Estimation formalism,‌ and a mix of Real experiments and Formal‌ methods for validating our technologies in complex real-world‌ dynamic scenarios.

Our research on visual-inertial sensor fusion‌ is closely related to the research carried out‌ by the group of Prof. Stergios Roumeliotis (University‌ of Minnesota) and the group of Prof. Davide‌ Scaramuzza (University of Zurich). Our originality in this‌ context is the introduction of closed-form solutions instead‌ of filter-based approaches.

Collaborations

Philippe Martinet, Research Director‌ at Inria, ACENTAURY team (Sophia Antipolis).Co-supervision of a‌ PhD thesis (K. Bhowmik) with A. Spalanzani. Road‌ users motion prediction. Publications 18 and partner in‌ projects ANR 'Annapolis'.
Radu Matescu, Research Director at‌ Inria, head of the CONVECS team, Grenoble.Co-supervision of‌ a PhD thesis (J.B. Horel, co-supervised with A.‌ Renzaglia and C. Laugier). Joint publications and joint‌ participation in the PRISSMA project.

3.3 Decision Making‌

Project-team positioning

In his reference book Planning algorithms‌32, S. LaValle discusses the different dimensions‌ that make the motion planning a complex problem,‌ which are the number of robots, the obstacle‌ regions, the uncertainty of perception and action, and‌ the allowable velocities. In particular, it is emphasized‌ that multiple robots planning problems in complex environments‌ are NP-hard problems, which implies that exact approaches‌ have exponential time complexities in the worst case‌ (unless P=NP). Moreover, dynamic and uncertain environments, as‌ human-populated ones, expand this complexity. In this context,‌ we aim at scaling up decision-making in human-populated‌ environments and in multi-robot systems, while dealing with‌ the intrinsic limits of the robots and machines‌ (computation capacity, limited communication). To address these challenges,‌ we explore new algorithms and AI architectures following‌ three directions: online planning/self-organization for real-time decision/control, machine‌ learning to adapt to the complexity of uncertain‌ environments, and combinatorial optimization to deal with offline‌ constrained problems. Combining these approaches, seeking to scale‌ them up, and also evaluating them with real‌ platforms are also elements of originality of our‌ work.

We share these goals with other laboratories/teams‌ in the world, such as the IntRoLab at‌ Sherbrooke University (Canada) led by Prof. F. Michaud‌ (we have established an associated team since 2024).‌ We can also mention the Learning Agents Research‌ Group (LARG) within the AI Lab at the‌ University of Texas (Austin, USA) led by Prof.‌ P. Stone, the Autonomous Systems Lab at ETH Zurich (Switzerland) led by‌ R. Siegwart, the Robotic‌ Sensor Networks Lab at‌‌ the University of Texas (Austin, USA) led by‌ Prof. V. Isler, and‌ the Autonomous Robots Lab‌‌ at NTNU (Norway) to cite a few. At‌ Inria, we share some‌ of the objectives with‌‌ the LARSEN team in Nancy (multi-agent machine learning,‌ multi-robot planning) and the‌ RAINBOW team in Rennes‌‌ (multi-UAV planning). We have also collaborations with the‌ ACENTAURY team, in Sophia‌ Antipolis, about autonomous navigation‌‌ among humans. In France, among other labs involved‌ in similar subjects, we‌ can cite the LAAS/RIS‌‌ team (CNRS, Toulouse), the ISIR lab/Sorbonne U. Paris‌ (Prof. N. Bredeche on‌ swarm robotics), the CRISTAL‌‌ Lab in Lille University (eg. the SMAC team‌ led by Prof. P.‌ Mathieu), and the MAD‌‌ team of GREYC lab in Caen University.

Collaborations‌

Isabelle Guerin Lassous, Prof.‌ at LIP lab., Univ.‌‌ Lyon 1. Co-supervision of two PhD thesis, A.‌ Bonnefond and T. Balaguer‌ 26, with O.‌‌ Simonin. Cooperation on communication in UAV fleets. Publications‌ 15, 16 and‌ partner in projects ANR‌‌ 'CONCERTO' and Inria/AID 'DynaFlock'.
Isabelle Fantoni, CNRS Research‌ Director at LS2N Lab.,‌ Nantes. Co-supervision of the‌‌ PhD thesis of T. Balaguer 26 with O.‌ Simonin. Cooperation on control‌ of UAV fleets. Publications‌‌ 15, 16 and partner in the ANR‌ 'VORTEX' project.
Laetitia Matignon,‌ Asso. Professor at LIRIS‌‌ lab., Univ. Lyon. Cooperation on Multi-Robot Deep/RL methods‌ with O. Simonin and‌ J. Saraydaryan. Publications, eg.‌‌ 31, and partner in 'REMEMBER' AI Chair‌ and ANR/BPI 'SOLAR-Nav' projects.‌
Lara Brinon Arranz, Asso.‌‌ Professor INP at GIPSA Lab, Grenoble. Cooperation on‌ multi-robot source seeking with‌ A. Renzaglia 30.‌‌ Partner in the new ANR 'ARCAVE' project.
Jaeger‌ Lab at University of‌ Chicago: B. Saintyves is‌‌ collaborating with Heinrich Jaeger, full professor at University‌ of Chicago, on material‌ testing and physical simulations‌‌ for Granulobot and on the development of the‌ Shellbot prototype.

Figure 2.a — Figure 2: Some‌ of the CHROMA platforms:‌‌ the autonomous version of the Renault Zoe car,‌ the Mirokaï humanoid (lent‌ by our partner Enchanted‌‌ Tools), the PX4-Vision UAV.

Figure 2.b — Figure 2: Some‌ of the CHROMA platforms:‌‌ the autonomous version of the Renault Zoe car,‌ the Mirokaï humanoid (lent‌ by our partner Enchanted‌‌ Tools), the PX4-Vision UAV.

4 Application domains

Applications‌ in CHROMA are organized‌ in two main domains‌‌ : i) Autonomous cars and robots in human-populated‌ environments, ii) Cooperative ground‌ and aerial robots for‌‌ mapping, exploration and services. The scientific objectives‌ described in the previous‌ sections are intended to‌‌ apply equally to these applicative domains. Even if‌ our work on Bayesian‌ Perception is today applied‌‌ to the intelligent vehicle domain, we aim to‌ generalize to any mobile‌ robots. The same remark‌‌ applies to the work on multi-agent decision making.‌ We aim to apply‌ algorithms to any fleet‌‌ of mobile robots (service robots, connected vehicles, UAVs).‌ This is the philosophy‌ of the team since‌‌ its creation.

The team‌ beneficiates from several robotics platforms (see figure 2‌). In Lyon, we have a set of‌ quadrirotors UAVs (autonomous drones) : 5 PX4 Vision‌ and 20 mini-crazyflies, plus a lighthouse localization system.‌ In Grenoble, we have two outdoor autonomous vehicles‌ : an autonomous Renault Zoe car and a‌ mobile robot Barakuda from AID (loaned in the‌ context of the ANR MOBILEX challenge).

We have‌ also 2 Mirokai semi-humanoids (dispatched between Lyon and‌ Grenoble) which are loaned by the company Enchanted‌ Tools in the context of the ANR/BPI SOLAR-Nav‌ project.

5 Social and environmental responsibility

                  
5.1 Footprint​​​‌ of research activities

                  Some﻿​﻿﻿ of our research topics​‌﻿﻿ involve high CPU usage.​​﻿﻿ Some researchers in the​​​‌ team use the Grid5000﻿​﻿﻿ computing cluster, which guarantees​‌﻿﻿ efficient management of computing​​﻿﻿ resources and facilitates the​​​‌ reproducibility of experiments. Some﻿​﻿﻿ researchers in the team​‌﻿﻿ keep a log summarizing​​﻿﻿ all the uses of​​​‌ computing servers in order﻿​﻿﻿ to be able to​‌﻿﻿ make statistics on these​​﻿﻿ uses and assess their​​​‌ environmental footprint more finely.﻿​﻿﻿

5.2 Impact of research‌ results

Baudouin Saintyves gave outreach talks and one‌ live performances with his art and science collective‌ (1) at the Artifice Numerique Festival in Nice,‌ France, in November 2024, and (2) at the‌ Society for Art and Techonologies in Montreal, Canada‌ in October 2025 (website). Their work‌ was highlighted in the press, including in the‌ Canada National radio science show "Moteur de recherche"‌ on October 16th, 2025 7

                
6 Highlights of​​​‌ the year

6.1 Team﻿​﻿﻿ member involvement in the​‌﻿﻿ community

                  Olivier Simonin was​​﻿﻿ appointed deputy director of​​​‌ the FIL (Federation Informatique﻿​﻿﻿ de Lyon) at the​‌﻿﻿ end of 2025.
Olivier​​﻿﻿ Simonin has been appointed​​​‌ as member of the﻿​﻿﻿ scientific board of the​‌﻿﻿ GDR Robotique (since 1/1/2025).​​﻿﻿
Christian Laugier
he has​​​‌ been appointed as a﻿​﻿﻿ member of the "comité​‌﻿﻿ des sages" of the​​﻿﻿ GDR Robotique.
Christian Laugier​​​‌ has completed in 2025﻿​﻿﻿ his third years term​‌﻿﻿ has "Editor-in-Chief" of the​​﻿﻿ IEEE-RAS IROS conference.
Christian​​​‌ Laugier has been elected﻿​﻿﻿ as President of the​‌﻿﻿ steering committee of the​​﻿﻿ IEEE/RAS IROS conference for​​​‌ the period 2026-28.

6.2﻿​﻿﻿ Design of Robotic platform​‌﻿﻿

                  In the fall of​​﻿﻿ 2025, we designed our​​​‌ own UAV platform (Autonomous﻿​﻿﻿ Aerial Vehicle), in the​‌﻿﻿ context of a new​​﻿﻿ collaboration between CHROMA, the​​​‌ INSA Lyon Mechanical Engineering﻿​﻿﻿ Department & Ampere Lab​‌﻿﻿ and the Agora team.​​﻿﻿ This project was mainly​​​‌ led by Nicolas Valle.﻿​﻿﻿

7 Latest software developments,‌ platforms, open data

CMCDOT Framework

Software Family
1. vehicle‌: Software as a Vehicle for Research.
2. transfer‌: Transfer software.
Audience:
1. personal: personal or‌ internal project-team prototype (to experiment with an idea);‌
2. team: to be used by people in‌ the project-team or close to the project-team (including‌ contractual partners);
3. partners: to be used by‌ people inside and outside the project-team but without‌ a clear and strong dissemination and support action‌ plan;
Evolution and maintenance:
1. lts: long term‌ support.
Duration of the Development (Duration): more than 500 man-months, 2013-2025
Free‌ Description: The CMCDOT framework‌ is a generic probabilistic‌‌ perception and navigation system based on Bayesian filtering‌ of dynamic occupancy grids‌ (CMCDOT), allowing parallelized estimation‌‌ for each cell of a grid of occupancy‌ probabilities, inference of speed‌ distributions, prediction of collision‌‌ risks, path planning and monitoring with obstacle avoidance,‌ in real time on‌ an on-board calculation card.‌‌ Automotive and indoor robotics demonstration and presentation videos‌ are available here and‌ here. Widely used‌‌ in the team in various projects, and already‌ the subject of transfer‌ and licensing to industrial‌‌ partners in the past, the software is currently‌ being transferred to an‌ Inria spin-off, Yona-Robotics.
Web‌‌ site

SPACISS

Software Family
1. vehicle: Software as‌ a Vehicle for Research.‌
Audience:
1. personal: personal‌‌ or internal project-team prototype (to experiment with an‌ idea);
2. team: to‌ be used by people‌‌ in the project-team or close to the project-team‌ (including contractual partners);
3. partners‌: to be used‌‌ by people inside and outside the project-team but‌ without a clear and‌ strong dissemination and support‌‌ action plan;
Evolution and maintenance:
1. basic: maintenance‌ to keep the software‌ alive.
Duration of the‌‌ Development (Duration): 4 years, 2018-2022
Free Description: Simulation‌ of pedestrians and an‌ autonomous vehicle in various‌‌ shared space scenarios. Adaptation of the original Pedsimros‌ model to simulate heterogeneous‌ crowds in shared spaces‌‌ (individuals, social groups, etc.) with a vehicle. The‌ car model is integrated‌ into the simulator and‌‌ the interactions between pedestrians and the autonomous vehicle‌ are modeled. The autonomous‌ vehicle can be controlled‌‌ from inside the simulation or from outside the‌ simulator by ROS commands.‌ The simulator was primarily‌‌ developed by M. Predhumeau as part of her‌ PhD thesis. 33
Web‌ site

NAMO-SIM

Software Family‌‌
1. vehicle: Software as a Vehicle for Research.‌
Audience:
1. personal: personal‌ or internal project-team prototype‌‌ (to experiment with an idea);
2. team: to‌ be used by people‌ in the project-team or‌‌ close to the project-team (including contractual partners);
3. community‌: large audience software,‌ usable by people inside‌‌ and outside the field with a clear and‌ strong dissemination, validation, and‌ support action plan
Evolution‌‌ and maintenance:
1. basic: maintenance to keep the‌ software alive.
Duration of‌ the Development (Duration): 5‌‌ years, 2021-2025
Free Description: NAMOSIM is a mobile‌ robot motion planner and‌ simulator designed for the‌‌ problem of Navigation Among Movable Obstacles (NAMO). The‌ planner simulates robots navigating‌ in 2D polygonal environments‌‌ where certain obstacles can be grasped and relocated‌ to enable robots to‌ reach their goals. NAMOSIM‌‌ is intended for researchers and developers working on‌ robot navigation in dynamic‌ environments, particularly where physical‌‌ interaction is necessary. NAMOSIM is packaged as a‌ ROS 2 package to‌ facilite integration with commonly-used‌‌ robotics tools such as Nav2 and Gazebo, but‌ it can also be‌ used as a standalone‌‌ Python module. Simulations are displayed in a Tkinter‌ window and ROS 2‌ messages are published for‌‌ more-detailed visualization in RViz.‌ The simulator was first developed by B. Renault‌ during his PhD thesis, then extended by D.‌ Brown (ADT Inria NAMOEX), see 11.
Web‌ site

DANCERS

Software Family
1. vehicle: Software as‌ a Vehicle for Research.
Audience:
1. personal: personal‌ or internal project-team prototype (to experiment with an‌ idea);
2. team: to be used by people‌ in the project-team or close to the project-team‌ (including contractual partners);
3. partners: to be used‌ by people inside and outside the team but‌ without a clear and strong dissemination and support‌ action plan
Evolution and maintenance:
1. basic: maintenance‌ to keep the software alive.
Duration of the‌ Development (Duration): 5 years, 2021-2025
Free Description: Since‌ 2022, T. Balaguer (PhD student) develops DANCERS, a‌ novel co-simulation platform providing synchronization and information exchange‌ between any robotic and any network simulator. Managing‌ the interplay between the physical and network aspects‌ of connected multi-robot systems proves challenging because existing‌ physics simulators often lack realistic communication models, while‌ network simulators typically use over-simplified physics and mobility‌ models. The DANCERS co-simulator is presented in the‌ article 15.
Web site

7.1 New platforms‌

7.1.1 Aerial Robot platform : "DIONE" project

Participants:‌ Nicolas Valle, Theo Porche [INSA intern],‌ Olivier Simonin.

Design of a UAV (drone)‌ platform, in collaboration with INSA Mechanical Engineering Department‌ & Ampere Lab (Ludovic Pouliquen, Paolo Masssioni) and‌ the Agora team. This project, called DIONE (Drone‌ Intelligent pour l’Observation et la Navigation autonome multi-Environnement),‌ is led by Nicolas Valle and aims to‌ develop a modular aerial robotics platform. The goal‌ is to obtain a four-motor UAV on which‌ different sensors can be mounted according to the‌ research needs of team members. Initially, the robot‌ will offer several geolocation options (GNSS, GNSS-RTK, indoor‌ infrared LightHouse), and a 2-axis mount on the‌ underside that can accommodate a Livox 360° LiDar.‌ The DIONE project is currently being developed in-house‌ and will eventually be available as open-source.

7.1.2‌ Barakuda

Participants: Lukas Rummelhard, Thomas Genevois,‌ Robin Baruffa, Hugo Bantignies, Nicolas Turro‌.

Within the scope of the ANR Challenge‌ MOBILEX, a 4-wheel all-terrain Barakuda robot from Shark‌ Robotics is provided, and will be equipped with‌ sensors and compute capabilities to achieve increasing level‌ of autonomy.

8 New results

8.1 Bayesian Perception‌ : evolution of the CMCDOT framework

Participants: Lukas‌ Rummelhard, Robin Baruffa, Hugo Bantignies,‌ Nicolas Turro, Jean-Baptiste Horel, Christian Laugier‌.

Recognized as one of the core technologies‌ developed within the team over the years (see‌ related sections in previous activity report of Chroma,‌ and previously e-Motion reports), the CMCDOT framework is‌ a generic Bayesian Perception framework, designed to estimate‌ a dense representation of dynamic environments and the‌ associated risks of collision, by fusing and filtering‌ multi-sensor data. This whole perception system has been‌ developed, implemented and tested on embedded devices, incorporating‌ over time new key modules. Now extended to 3D for grid fusion‌ and incorporating semantic states‌ in the whole process,‌‌ this framework, and the corresponding software, is at‌ the core of many‌ important industrial partnerships and‌‌ academic contributions, and to be the subject of‌ important developments, both in‌ terms of research and‌‌ engineering.

Historically based on LiDAR sensor technologies, the‌ embedded Bayesian perception system‌ was developed notably for‌‌ its ability to integrate and fuse diverse information‌ sources from heterogeneous sensors.‌ Once a relevant sensor‌‌ model is developed - in other words, once‌ a probabilistic occupancy grid‌ can be generated at‌‌ a given time from the sensor data, modeling‌ the probabilities and uncertainties‌ of obstacles being present‌‌ at a given location given the received data‌ —, the entire downstream‌ perception and navigation chain‌‌ can integrate this sensor data. The grids generated‌ by the different sensors‌ are thus merged, filtered,‌‌ and interpreted through explainable rules, independent of the‌ modality involved. Adding more‌ sensor modalities can lead‌‌ to a general improvement in perception, through redundancy‌ and complementarity (each sensor‌ modality behaving differently with‌‌ different types of obstacles, compensating each other weaknesses).‌

In addition to LiDAR‌ and depth cameras, two‌‌ new modalities were added this year : radar‌ and ultrasound sensors. Sensor‌ models, and associated sofware‌‌ and parameter tuning, were designed and developped based‌ on sensor data sheets,‌ bibliographic analysis, and experimentation.‌‌ Significant work was also done to optimize the‌ perception system on GPU,‌ resulting in a substantial‌‌ improvement in performance, notably on embedded devices.

8.2‌ Situation Awareness & Decision-making‌ for Autonomous Vehicles

Participants:‌‌ Christian Laugier, Manuel Alejandro Diaz-Zapata, Alessandro‌ Renzaglia, Anne Spalanzani‌, Wenqian Liu,‌‌ Rabbia Asghar, Lukas Rummelhard, Gustavo Salazar-Gomez‌, Olivier Simonin.‌

In this section, we‌‌ present all the novel results in the domains‌ of perception, motion prediction‌ and decision-making for autonomous‌‌ vehicles.

8.2.1 Situation Understanding and Motion Forecasting

Participants:‌ Kaushik Bhowmik, Anne‌ Spalanzani.

Trajectory forecasting‌‌ in urban environments is a critical task that‌ needs to be addressed‌ for the safety of‌‌ autonomous vehicles, particularly in urban road intersection scenarios,‌ where agents exhibit diverse‌ behaviors mainly due to‌‌ complex interactions between agents and the environment and‌ the diversity of paths‌ available to the agents.‌‌ Current state-of-the-art methods do not perform well in‌ urban road intersection scenarios.‌ To address this issue,‌‌ the proposed novel framework CandidateGraph-Net (CG-Net), improves trajectory‌ prediction in urban road‌ intersection scenarios by encoding‌‌ the available candidate centerlines at the current location‌ of the target agent.‌ The proposed interaction encoder‌‌ in CG-Net is inspired by human behavior. It‌ is modeled utilizing a‌ bipartite graph attention network‌‌ to predict the trajectory of the target agent.‌ It estimates the trajectory‌ in the same way‌‌ as humans anticipate the trajectory of other vehicles‌ and pedestrians in dynamic‌ environments. The agent embeddings‌‌ in the interaction encoder at each time step‌ pay attention to nearby‌ agents and surrounding scene‌‌ elements simultaneously. This enables‌ the model to learn how to prioritize interactions‌ between nearby agents and the environment map. Further,‌ CG-Net’s performance is evaluated using the Argoverse 2‌ motion forecasting dataset. The results demonstrate its effectiveness‌ in urban road intersection scenarios, with an overall‌ improvement in key metrics such as minFDE and‌ minADE compared to baseline methods. These improvements highlight‌ CG-Net’s ability to perform better motion forecasting in‌ urban road intersection scenarios. This work was accepted‌ to the IROS 2025 conference 18.

8.2.2‌ AI-driven Motion Planning and Temporal Multi-Modality Sensor Fusion‌ for Semantic Grid Prediction

Participants: Gustavo Salazar-Gomez,‌ Anne Spalanzani, Lukas Rummelhard, Christian Laugier‌.

Local trajectory planning for autonomous vehicles in‌ urban scenarios requires reliable decisions around dense traffic‌ and several agents' interactions. The planner's input strongly‌ influences its reaction to different situations, hence the‌ importance of choosing the appropriate representation. Birds' eye-‌ view (BEV) grids provide spatial coverage, while vectorized‌ representations offer efficiency but risk missing information. We‌ propose to use flow-guided occupancy grids, which are‌ BEV occupancy maps augmented with cell flow vectors‌ to combine occupancy, motion and uncertainty. Based on‌ this representation, we have developed PlanFlow, a model‌ based on a compact CNN as backbone with‌ a MLP decoder, trained combining L1 and collision‌ aware losses. We trained and evaluated PlanFlow on‌ nuScenes against BEV input baselines, achieving robust accuracy‌ and low collision rates, displaying improvement over the‌ SOTA approaches by using flow-guided grids for trajectory‌ planning reasoning. This work will be presented at‌ IEEE Intelligent Vehicle(IV) 2026.

8.2.3 Dynamic Scene Prediction‌ for Urban Driving Scene Using Occupancy Grid Maps‌

Participants: Rabbia Asghar, Lukas Rummelhard, Anne‌ Spalanzani, Christian Laugier.

Accurate prediction of‌ driving scenes is essential for road safety and‌ autonomous driving. This remains a challenging task due‌ to uncertainty in sensor data, the complex behaviors‌ of agents, and possibility of multiple feasible futures.‌ Over the course of Rabbia's PhD, we have‌ addressed the prediction problem by representing the scene‌ as dynamic occupancy grid maps (DOGMs) and integrating‌ semantic information. We employ deep learning-based spatiotemporal approach‌ to predict the evolution of scene and learn‌ complex behaviours. We have proposed a novel multi-task‌ framework that leverages dynamic OGMs and semantic information‌ to predict both future vehicle semantic grids and‌ the future flow of the scene. This incorporation‌ of semantic flow not only offers intermediate scene‌ features but also enables the generation of warped‌ semantic grids. Evaluation on the real-world NuScenes dataset‌ demonstrates improved prediction capabilities and enhanced ability of‌ the model to retain dynamic vehicles within the‌ scene 28. We then focused on predicting‌ the behaviors of vehicle agents but also identifying‌ other dynamic entities within the scene and anticipating‌ their possible evolutions. Scene evolution is predicted as‌ agent semantic grids, dynamic occupancy grid maps, and‌ scene flow grids. Leveraging flow-guided prediction, these grids‌ enable diverse future predictions for vehicles and dynamic elements while also capturing‌ inter-grid dependencies through specialized‌ loss functions 29.‌‌ Rabbia Asghar defended her PhD in July 2025‌ 25.

Figure 3‌‌: Illustration of agent-agnostic scene predictions and agent-specific‌ predictions in the dynamic‌ occupancy grid framework.

8.3‌‌ Robust state estimation

Participants: Agostino Martinelli.

In‌ 2025, Dr. Martinelli achieved‌ a significant advance in‌‌ the theory of nonlinear system identification by establishing‌ the first-ever necessary and‌ sufficient algebraic condition for‌‌ local identifiability of nonlinear systems with time-varying parameters‌13. By treating‌ time-varying parameters as unknown‌‌ inputs, this work extends the framework of the‌ unknown input observability problem‌ and builds upon the‌‌ solutions originally developed in 2022 and 2023.

The‌ criterion proposed is fully‌ constructive, requiring only standard‌‌ derivative and matrix rank computations, and its application‌ to canonical nonlinear biological‌ models—including HIV dynamics and‌‌ the genetic toggle switch—uncovered critical discrepancies in the‌ existing literature while revealing‌ new structural properties of‌‌ these models. This contribution demonstrates both the broad‌ applicability and the transformative‌ impact of the theoretical‌‌ tools developed by Dr. Martinelli, and it is‌ expected to guide future‌ research in system identification‌‌ and control theory.

8.4 Online planning and learning‌ for robot navigation

8.4.1‌ Motion-planning in dense pedestrian‌‌ environments

Participants: Anne Spalanzani, Jason Chemin,‌ Manuel Diaz Zapata.‌

Under the coordination of‌‌ Anne Spalanzani, we study new motion planning algorithms‌ to allow robots/vehicles to‌ navigate in human populated‌‌ environment while predicting pedestrians' motions. We model pedestrians‌ and crowd behaviors using‌ notions of social forces‌‌ and cooperative behavior estimations. We investigate new methods‌ to build safe and‌ socially compliant trajectories using‌‌ theses models of behaviors. We propose proactive navigation‌ solutions as well as‌ deep learning ones.

Since‌‌ 2018 we've been working on modelling crowds and‌ autonomous vehicles using Extended‌ Social Force Models (in‌‌ the scope of Manon Predhumeau's PhD) and Proactive‌ Navigation for navigating dense‌ human populated environments (in‌‌ the scope of Maria Kabtoul's PhD). The focus‌ of the first work‌ has been on the‌‌ realistic simulation of crowds in shared spaces with‌ an autonomous vehicle (AV),‌ see Fig. 4.a.‌‌ We proposed an agent-based model for pedestrian reactions‌ to an AV in‌ a shared space, based‌‌ on empirical studies and the state of the‌ art. The model includes‌ an AV with Renault‌‌ Zoé car's characteristics, and pedestrians' reactions to the‌ vehicle. The model extends‌ the Social Force Model‌‌ with a new decision model, which integrates various‌ observed reactions of pedestrians‌ and pedestrians groups. The‌‌ SPACiSS simulator is an opensource simulator still used‌ by the team. In‌ the scope of the‌‌ Solar-Nav project, we have adapted this work on‌ the Mirokai Robot in‌ an hospital context.

Figure 4.a — Figure‌‌ 4: a. Illustration of a typical scene‌ of an Mirokai and‌ Zoe car sharing their‌‌ space with pedestrians.

Figure 4.b — Figure‌‌ 4: a. Illustration of a typical scene‌ of an Mirokai and‌ Zoe car sharing their‌‌ space with pedestrians.

8.4.2‌ Attention Graph for Multi-Robot Social Navigation with Deep‌ Reinforcement Learning

Participants: Jacques Saraydaryan, Takieddine Soualhi‌.

Figure 5: Overview of‌ the MultiSoc architecture. For the agent of interest‌ (surrounded by dotted line), the input is its‌ intrinsic information and a graph limited to its‌ FoV. Each node is composed of the current‌ and consecutive predicted positions of the observed entities,‌ and by a label discriminating entities following their‌ nature.

Learning robot navigation strategies among pedestrian is‌ crucial for domain based applications. Combining perception, planning‌ and prediction allows to model the interactions between‌ robots and pedestrians, resulting in impressive outcomes especially‌ with recent approaches based on deep reinforcement learning‌ (RL). However, these works do not consider multi-robot‌ scenarios.

In this work, we defined MultiSoc,‌ a new method for learning multi-agent socially aware‌ navigation strategies using RL (see illustration fig. 5‌). Inspired by recent works on multi-agent deep‌ RL, our method leverages graph-based representation of agent‌ interactions, combining the positions and fields of view‌ of entities (pedestrians and agents). We evaluated our‌ approach on simulation and provided a series of‌ experiments in a set of various conditions (number‌ of agents/pedestrians). Empirical results show that our method‌ learns faster than social navigation deep RL mono-agent‌ techniques, and enables efficient multi-agent implicit coordination in‌ challenging crowd navigation with multiple heterogeneous humans. See‌ AAMAS 2024 publication 31.

This work continued‌ in 2025 (supported by the SOLAR-Nav project) and‌ aims to integrate the real constraints of robots‌ into an experiment with real robots. The RL‌ simulator has been upgraded to incorporate robot probes‌ (e.g. LiDAR) and a new HAMRON (Human-Aware multi-Robot‌ Navigation) model inspired by Multisoc has been trained.‌ We demonstrate that our navigation policy can handle‌ both human and static obstacles thanks its perception‌ system. This contribution is currently under review at‌ ICRA 2026. We extend this work by improving‌ our robot's social compliance around humans. To achieve‌ this, we are currently investigating a new reward‌ function that takes human proxemics into account. Initial‌ results are promising, showing improved performance across the‌ employed social metrics compared to existing approaches.

8.5‌ Multi-Robot path planning and mapping

Figure 6.a — Figure 6: Illustration of‌ a) S-NAMO planning b) MR-NAMO planning c) Real‌ exp. Turtlebot

Figure 6.b — Figure 6: Illustration of‌ a) S-NAMO planning b) MR-NAMO planning c) Real‌ exp. Turtlebot

8.5.1 Navigation Among Movable Obstacles (NAMO):‌ extension to multi-robot and social constraints

Participants: Jacques‌ Saraydaryan, Olivier Simonin, David Brown.‌

In CHROMA, we study NAMO (Navigation Among Movable‌ Obstacles) problems since 2018 . The PhD thesis‌ of Benoit Renault (2019-23) allowed us to extend‌ existing algorithms with the social cost of object‌ placement (Social-NAMO 35) and the generalisation to‌ multi-robot NAMO problems 34.

In 2023, we‌ obtained an Inria ADT project, called NAMOEX, aiming‌ to extend the Benoit Renault's NAMO simulator. Thanks‌ to David Brown (Ing., 2023-25), we robustified the simulator and studied multi-robot‌ NAMO strategies, leading to‌ a publication in IROS‌‌ 2024 34. In 2024 and 2025, we‌ developped a connexion between‌ our S-NAMO planner and‌‌ the Gazebo robotic simulator, also extended as a‌ monitoring tool for experiments‌ with real mobile robots,‌‌ see Fig. 6. This new simulator, NAMO-SIM,‌ has been published recently‌ in journal JOSS 11‌‌ (open-source software diffusion).

8.5.2 Multi-UAV Exploration and 3D‌ Reconstruction

Participants: Alessandro Renzaglia‌, Benjamin Sportich,‌‌ Kenza Boubakri, Olivier Simonin.

Figure 7‌‌: Illustration of UAVs trajectories during the exploration‌ and reconstruction of a‌ 3D urban environment.

Multi-robot‌‌ teams, especially when they include Unmanned Aerial Vehicles‌ (UAVs), are highly efficient‌ systems for assisting humans‌‌ in gathering information on large and complex environments‌ (see Figure 7).‌ In these scenarios, cooperative‌‌ exploration and 3D reconstruction are two fundamental problems‌ with numerous important applications,‌ such as mapping, inspection‌‌ of complex structures, and search and rescue missions.‌ In both cases, the‌ goal of the robots‌‌ is to navigate through the environment and cooperate‌ to acquire new information‌ in order to complete‌‌ the mission in the shortest possible time 36‌.

This line of‌ research is mainly carried‌‌ out within the ANR project AVENUE, which focuses‌ on the coordination of‌ a fleet of UAVs‌‌ to efficiently explore and reconstruct unknown 3D complex‌ scenes. In particular, both‌ the task execution time‌‌ and the accuracy of the final map are‌ considered as the key‌ metrics to optimize. First‌‌ results focused on the single-robot version of the‌ problem, and we proposed‌ a novel modular Next-Best-View‌‌ (NBV) planning framework that explicitly uses a reconstruction‌ quality objective to guide‌ the exploration planning 27‌‌. To do so, our approach introduced new‌ and efficient methods for‌ view generation and selection‌‌ of viewpoint candidates that are adaptive to user-defined‌ quality requirements, fully exploiting‌ the uncertainty encoded in‌‌ a Truncated Signed Distance Field (TSDF) representation of‌ the environment. This results‌ in informed and efficient‌‌ exploration decisions tailored towards the predetermined objective. Current‌ work is now focused‌ on extending this solution‌‌ to multi-UAV systems to coordinate their decision-making in‌ order to fully exploit‌ the capabilities of a‌‌ fleet of UAVs carrying out the task cooperatively.‌

8.5.3 Multi-robot agricultural itineraries‌ planning (NINSAR project)

Participants:‌‌ Simon Ferrier, Olivier Simonin, Alessandro Renzaglia‌.

Figure 8: Example of a multi-robot multi-row‌ planning simulated in Gazebo‌

The NINSAR project, part‌‌ of the PEPR AgroEcologie & Numerique, aims to‌ use robots to help‌ the agricultural sector. In‌‌ the PhD thesis of Simon Ferrier, started on‌ summer 2024, we define‌ and study algorithms for‌‌ the mission planning of a fleet of mobile‌ robots treating rows of‌ fields of any-shape.

To‌‌ deal with minimum time mission (makespan), we defined‌ and compared two approaches:‌ 1) a heuristic-based division‌‌ and allocation of rows‌ to robots 2) a Branch and Bound algorithm‌ computing the optimal solution, and an anytime version‌ combining both. An illustration of the problem and‌ of a solution is presented in figure 8‌. This work is under review for publication.‌

In 2025, we generalized this work to the‌ Multi-Robot Task Allocation (MRTA) problem. We propose a‌ new heuristic-based clustering algorithm (AttrAP), that aims to‌ minimize the maximum cost among the robots (makespan).‌ AttrAP is divided into three parts: (1) heuristic-based‌ allocation of each task iteratively to a robot,‌ (2) solving a TSP for each robot, and‌ (3) improving the solution with local optimization. We‌ compared our approach to a state-of-the-art GA algorithm,‌ showing we obtain generally better solutions in shorter‌ time. This work has been subimitted for publication.‌

Our next objective is to integrate reparing plans‌ within online scenarios having unexpected events.

8.6 Swarm‌ Robotics & UAV Fleets

8.6.1 UAV Chain Network‌ Creation in Cluttered Environment with Flocking Rules and‌ Routing Data

Participants: Théotime Balaguer, Olivier Simonin‌.

Figure 9.a — Figure 9:‌ a. principle of the UAV chain creation with‌ flocking stretching b. example of UAV chains connecting‌ several target areas and comparison to the Steiner‌ tree.

Figure 9.b — Figure 9:‌ a. principle of the UAV chain creation with‌ flocking stretching b. example of UAV chains connecting‌ several target areas and comparison to the Steiner‌ tree.

In the context of the PhD thesis‌ of Théotime Balaguer and the associated team with‌ Univ. of Sherbrooke (ROBLOC project), we proposed a‌ new decentralized algorithm to allow a fleet of‌ drones to connect a source area to one‌ or several target areas. Our approach relies on‌ the extension of the flocking model. We propose‌ an algorithm ensuring the emergence of “mission” communication‌ paths from a base drone to leaders flying‌ towards their target areas. Drones dynamically integrate the‌ “mission” path while the flocking stretches. We also‌ added a new avoiding force close to obstacles‌ perturbating communication. The originality of the model is‌ to be decentralized and to exploit routing data‌ to optimize dynamically the mission paths in term‌ of distance and QoS. This work is illustrated‌ in figure 9 and was published in the‌ IROS 2025 conference 16. Théotime Balaguer, co-supervized‌ by O. Simonin, I. Guérin Lassous (Lyon1/LIP) and‌ I. Fantoni (CNRS/LS2N Nantes), defended his PhD thesis‌ on November 2025 26. The relative co-simulator‌ we developed and used, DANCERS, has been published‌ in ECMR 2025 15.

8.6.2 Swarm of‌ visualy connected UAVs for exploration of unknown subterrean‌ environments

Participants: Mathis Fleuriel, Olivier Simonin,‌ Elena Vanneaux.

The use of unmanned aerial‌ systems (UAS) is a promising solution for search‌ and rescue (SAR) operations conducted to find missing‌ persons. In the ANR VORTEX project, we study‌ how it is possible to deploy rapidly autonomous‌ drones in indoor environments without using conventional communications‌ or mapping but by leveraging cameras & vision-based‌ processes. We propose to explore an approach where‌ a swarm of small UAVs (quadrotors) will quickly‌ deploy in the environment while forming a dynamic mesh of sensors. By‌ flying autonomously but keeping‌ visual contact with at‌‌ least another UAV, each drone will be able‌ to estimate its relative‌ location but also to‌‌ communicate information from drone to drone. As a‌ consequence, drones can form‌ a dynamic chain, guided‌‌ by a leader, allowing the exploration of the‌ environment.

Since 2024 we‌ study exploration stategies through‌‌ Mathis Fleuriel's PhD thesis (co-supervized by E. Vanneaux‌ and O. Simonin). We‌ proposed a first multi-agent‌‌ strategy allowing to maintain and reconfigure a chain‌ of drones, following a‌ dynamic leader (the leader‌‌ role can change when the chain meet a‌ deadend or a detect‌ a loop). This work‌‌ has been published in ECMR 2025 conference 19‌. In the end‌ of 2025, we proved‌‌ in discretized environment the termination and completude of‌ the strategy. We also‌ developed a new discrete‌‌ simulator (based on Mesa) to study different variants‌ of the strategy.

8.6.3‌ Robotic Matter

Participants: Baudouin‌‌ Saintyves, Olivier Simonin.

Figure 10‌: Tensile test experiment‌‌ on a passive proof of concept, toward the‌ conception of Shellbots. Full‌ deformation cycle from left‌‌ to right.

Baudouin Saintyves made progress on the‌ systematic mechanical study of‌ a preliminary passive version‌‌ of the shellbot, exploring mechanical properties that‌ can be used for‌ a robotic implementation. After‌‌ a first experimental campaign using a tensile test‌ machine, he is currently‌ building an experimental platform‌‌ to test the monolayers by controlling more deformation‌ degree of freedom and‌ develop design rules for‌‌ robotization. In parallel, a project has been submitted‌ to a PEPR Organic‌ Robotics (O2R) call. It‌‌ aims at funding the study and development of‌ distributed control and tasks‌ in robotic granular shell‌‌ monolayers, in cooperation with Prof. H. Jaeger from‌ Chicago University.

B. Saintyves‌ is also involved in‌‌ activities combining robotics, physics, and arts. In 2025,‌ he was invited with‌ his project shapes of‌‌ emergence for a residency including development and a‌ week of performance and‌ outreach presentations at the‌‌ Society for Arts and Technologies in Montreal, Canada.‌

9 Bilateral contracts and‌ grants with industry

9.1‌‌ Bilateral contracts with industry

9.1.1 IRT Nanoelec PULSE‌ – Security of Autonomous‌ Mobile Robotics (2023-2026)

Participants:‌‌ Lukas Rummelhard, Robin Baruffa, Hugo Bantignies‌, Jean-Baptiste Horel,‌ Nicolas Turro, Christian‌‌ Laugier.

CHROMA coord. : Lukas Rummelhard.

CHROMA‌ participates in a project‌ supported by PIA in‌‌ the scope of the program PULSE of IRT‌ Nanoelec. The objective of‌ this project is to‌‌ integrate, develop and promote technological bricks of context‌ capture, for the safety‌ of the autonomous vehicle.‌‌ Building on Embedded Bayesian Perception for Dynamic Environment‌, Bayesian data fusion‌ and filtering technologies from‌‌ sets of heterogeneous sensors. These software bricks make‌ it possible to secure‌ the movements of vehicles,‌‌ but also provide them‌ with an enriched and useful representation for autonomy‌ functions themselves. In this context, various demonstrators embedding‌ those technology bricks are developed in cooperation with‌ industrial partners. Current work is mainly focused on‌ adding new sensor modalities (radar, ultrasound) in the‌ perception system, GPU optimization, and integration of Neural-Network-based‌ systems into these probabilistic frameworks.

9.2 Bilateral grants‌ with industry

9.2.1 Start-up maturation : Yona-Robotics (2024-2025)‌

Participants: Lukas Rummelhard, Christian Laugier.

CHROMA‌ coord. : Lukas Rummelhard.

In order to address‌ the emerging markets for mobile robotics, in particular‌ in industrial contexts (industrial robotics, handling, logistics, agricultural‌ robotics, inspection robots, service robots, etc.), a technology‌ maturation project on the Embedded Bayesian Perception and‌ Navigation systems of the team (CMCDOT framework) have‌ started this year. Thanks to the support of‌ the SATT LINKSIUM GRENOBLE ALPES, the start-up Yona-Robotics‌ was created. See Yona-Robotics.

10 Partnerships and‌ cooperations

10.1 International initiatives

10.1.1 Inria associate team‌ not involved in an IIL or an international‌ program

Associated Team with Univ. Sherbrooke, Canada, 3IT‌ Institute, IntroLab team, called “ROBLOC" (Robot Localization‌ and Navigation Team), 2024-2026 (12 K€/year).

The coordinators‌ are Olivier Simonin (CHROMA) and François Michaud (U.‌ Sherbrooke / 3IT).
The two teams share common‌ topics as mapping unknown environments, UAVs (drones) localization‌ and navigation, and human-robot interaction. The proposed associate‌ team aims to explore these subjects to build‌ new research paths by sharing respective approaches and‌ tools. More precisely, the collaboration concerns: 1) UAV‌ fleet navigation, 2) mapping for social navigation, 3)‌ multi-robot path-planning: exploration of underground environments. We are‌ co-supervising several master's students and we are preparing‌ new collaborative projects.

                  
10.2​​﻿﻿ International research visitors

10.2.1​​​‌ Visits of international scientists﻿​﻿﻿

                        François Ferland
                      
                      Status:Professor​‌﻿﻿
Institution of origin:University​​﻿﻿ of Sherbrooke / 3IT​​​‌ Institute
Country:Canada
Dates:﻿​﻿﻿June, 16-26, 2025
Context​‌﻿﻿ of the visit:EA​​﻿﻿ ROBLOC
Mobility program/type of​​​‌ mobility:research stay

10.2.2﻿​﻿﻿ Visits to international teams​‌﻿﻿

                        Olivier Simonin
                      
                      Visited institution:​​﻿﻿University of Sherbrooke /​​​‌ 3IT Institute
Country:Canada﻿​﻿﻿
Dates:July, 15-29, 2025​‌﻿﻿
Context of the visit:​​﻿﻿EA ROBLOC
Mobility program/type​​​‌ of mobility:research stay﻿​﻿﻿

10.3 National initiatives

10.3.1‌ ANR

ANR/BPI Tranfert Robotique "Solar-Nav" project (2025-2027)

Participants:‌ Anne Spalanzani, Olivier Simonin, Jacques Saraydaryan‌, Alessandro Renzaglia, Nicolas Turro, Lukas‌ Rummelhard, Maxime Bernard, Takieddine Soualhi,‌ Nicolas Valle, Antonin Betaille, Damien Rambeau‌, Manuel Diaz Zapata, Jason Chemin.‌

Title : SOcial Logistics Advanced Robotic NAVigation Partners‌ : Inria Lyon/Grenoble CHROMA, Station H (Hospices Civils‌ de Lyon), Chaire valeur du soin Lyon 3,‌ Enchanted Tools company (Paris).

Coord. : A. Spalanzani‌ (CHROMA)

Budget : 3,7 Millions € (CHROMA: 1,2‌ M€)

The Solar-Nav project aims at transfering social‌ navigation models developed in the CHROMA team to‌ the Mirokai robot produced by the Enchanted Tool‌ company. The focus is made on the perception‌ of human populated environments as well as on‌ social navigation in the hospital context. This project funds 5 engineers and‌ 2 postdoc for two‌ years within the CHROMA‌‌ team (based in Inria Lyon, Grenoble and Nancy).‌

ANR TSIA "VORTEX" project‌ (2024-2028)

Participants: Olivier Simonin‌‌, Mathis Fleuriel, Elena Vanneau, Alessandro‌ Renzaglia, Nicolas Valle‌.

Title : Vision-based‌‌ Reconfigurable Drone Swarms for Fast Exploration. Partners :‌ CITI/INSA Lyon CHROMA, LS2N‌ (Nantes), ENSTA (Paris), ONERA‌‌ (Paris), LabSTICC/IMT (Brest).

PI : O. Simonin (CHROMA)‌

Budget : 694 K€‌ (CHROMA: 150 K€)

The‌‌ VORTEX project proposes a new approach for exploring‌ unknown indoor environments using‌ a fleet of autonomous‌‌ mini-drones (UAVs). We propose to define a strategy‌ based on swarm intelligence‌ exploiting only vision-based behaviors.‌‌ The fleet will deploy as a dynamic graph‌ self reconfiguring according to‌ events and discovered areas.‌‌ Without requiring any mapping or wireless communication, the‌ drones will coordinate by‌ mutual perception and communicate‌‌ by visual signs. This approach will be developed‌ with RGB and event‌ cameras to achieve fast‌‌ and low-energy navigation. Performance, swarm properties, and robustness‌ will be evaluated by‌ building a demonstrator extending‌‌ a quadrotor prototype developed in the consortium.

ANR‌ JCJC "AVENUE" (2023-2026)

Participants:‌ Alessandro Renzaglia, Benjamin‌‌ Sportich, Kenza Boubakri, Olivier Simonin.‌

Title : Cooperative Aerial‌ Vehicles for Non-Uniform Mapping‌‌ of 3D Unknown Environments

Coord. : A. Renzaglia‌ (CHROMA)

Budget : 250K€‌

The objective of AVENUE‌‌ is to propose new efficient solutions to generate‌ online trajectories for a‌ team of cooperating aerial‌‌ vehicles to achieve complete exploration and non-uniform mapping‌ of an unknown 3D‌ environment. The main challenges‌‌ will be the definition of new criteria to‌ predict the expected information‌ gain brought by future‌‌ candidate observation points and the design of a‌ distributed strategy to optimally‌ assign future viewpoints to‌‌ the robots to finally minimize the total mission‌ time. The project is‌ funding a PhD thesis‌‌ (B. Sportich) and an engineer (K. Boubakri).

ANR‌ "ANNAPOLIS" (2022-2026)

Participants: Anne‌ Spalanzani, Kaushik Bhowmik‌‌.

Title: "AutoNomous Navigation Among Personal mObiLity devIceS".‌ Total budget : 831‌ K€ (CHROMA: 163 K€).‌‌ Coord. : A. Spalanzani

In ANNAPOLIS, unforeseen and‌ unexpected events take source‌ from situations where the‌‌ perception space is hidden by bulky road obstacles‌ (e.g. truck/bus) or an‌ occluding environment, from the‌‌ presence of new powered personal mobility platforms, or‌ from erratic behaviors of‌ unstable pedestrians using (or‌‌ not) new electrical mobility systems and respecting (or‌ not) the traffic rules‌ ANNAPOLIS will increase the‌‌ vehicle's perception capacity both in terms of precision,‌ measurement field of view‌ and information semantics, through‌‌ vehicle to intelligent infrastructure communication.

ANR Challenge MOBILEX‌ : 'NAVIR' project (2024-2026)‌

Participants: Lukas Rummelhard,‌‌ Robin Baruffa, Hugo Bantignies, Jean-Baptiste Horel‌, Nicolas Turro,‌ Christian Laugier.

CHROMA‌‌ partner coord. : Lukas Rummelhard Budget: 220 K€‌ (Chroma)

NAVIR is a‌ project selected for the‌‌ MOBILEX Challenge, a co-funded call launched by ANR‌ and the Defence Innovation‌ Agency (AID), with co-organization‌‌ by the National Centre‌ for Space Studies (CNES) and the Agency for‌ Transport Innovation (AIT).

The development of advanced piloting‌ assistance, on board or remote in the form‌ of an autopilot, to manage the trajectory of‌ a land vehicle taking into account the complexity‌ of its environment (slopes, unstructured roads, landslides, etc.),‌ and its evolution (meteorological hazards), represents a crucial‌ research challenge for the civil, military and space‌ fields. Having such a level of assistance would‌ not only relieve the pilots, but also free‌ up cognitive and/or physical resources, whether for construction,‌ fire-fighting or military vehicles for example. In this‌ context, the MOBILEX Challenge aims at evaluating different‌ technological solutions integrating all the functions and constraints‌ to be taken into account to manage the‌ local trajectory of a land vehicle in an‌ autonomous way in a complex environment. More globally,‌ it aims to advance research and innovation in‌ this field.

ANR "MaestrIoT" (2021-2025)

Participants: Jilles Dibangoye‌, Olivier Simonin.

Title : Multi-Agent Trust‌ Decision Process for the Internet of Things Consortium:‌ LITIS (coord.), CHROMA/CITI, LCIS, IHF/LIMOS. Total funding 536‌ K€ (CHROMA: 120 K€)

The main objective of‌ the MaestrIoT project is to develop an algorithmic‌ framework for ensuring trust in a multi-agent system‌ handling sensors and actuators of a cyber-physical environment.‌ Trust management has to be ensured from the‌ perception to decision making and integrating the exchange‌ of information between WoT devices.

EquipEx+ "TIRREX" (2021-30)‌

Participants: Olivier Simonin, Alessandro Renzaglia, Christian‌ Laugier, Lukas Rummelhard.

Title : "Technological‌ Infrastructure for Robotics Research of Excellence" ( $\sim‌$ 12M€). TIRREX is led by CNRS and involves‌ 32 laboratories. CHROMA is involved in two research‌ axes :

"Aerial Robotics", CHROMA/CITI lab. is a‌ major partner of this axis (INSA Lyon &‌ Inria). We can benefit from the experimental platforms‌ (in Grenoble and Marseille) and their support.
"Autonomous‌ land robotics", CHROMA/CITI lab. is a secondary partner‌ of this axis (INSA Lyon & Inria).

10.3.2‌ PEPR

PEPR Agroécologie et Numérique : NINSAR project‌ (2023-28)

Participants: Simon Ferrier, Olivier Simonin,‌ Alessandro Renzaglia.

Title : New ItiNerarieS for‌ Agroecology using cooperative Robots

CHROMA partner coord.: Olivier‌ Simonin

Budget : 2,2 M€ (CHROMA: 170 K€)‌

The NINSAR project is coordinated by Inria and‌ INRAE. It involved three Inria teams (ACENTAURI, CHROMA‌ and Rainbow) and several partners such as INRAE‌ (Clermont Ferrand), CEA (LIST), CNRS (LAAS) and XLIM‌ (Limoges). In CHROMA, the project funds the PhD‌ thesis of Simon Ferrier (since Sept. 2024). This‌ thesis adresses the problem of planning heterogeneous multi-robot‌ itineraries for crop operations. In NINSAR, Olivier Simonin‌ coordinates the CHROMA partner and co-heads the Work-package‌ 2 "Data acquisition for decision and robotic mission‌ planning".

PEPR O2R Organic Robotics

(2023-28)

Participants: Olivier‌ Simonin, Anne Spalanzani, Alessandro Renzaglia,‌ Jacques Saraydaryan.

CHROMA is involved in a‌ O2R's project called "Interactive Mobile Manipulation" (led by‌ Andrea Cherubini from LS2N / Nantes University) (3.5 M€).

It is planned‌ that CHROMA will work‌ on social navigation and‌‌ multi-robot planning from 2026 onwards.

10.3.3 INRIA/AID AI‌ projects

"BioSwarm" (2023-2027)

Participants:‌ Olivier Simonin, Hamidou‌‌ Diallo.

Title : Algorithmes bio-inspirés pour la‌ recherche collective et la‌ prise de décision dans‌‌ les essaims de drones

Co-led by Emanuele Natale‌ (Inria COATI, Sophia A.)‌ and Olivier Simonin (CHROMA).‌‌

Funding of BioSwarm : 253 K€ / Chroma:‌ 130 K€.

The BioSwarm‌ project concerns the application‌‌ of decentralised algorithms, originally motivated by modelling the‌ collective behaviour of biological‌ systems, to swarms of‌‌ drones dealing with a collective task. We are‌ focusing on search strategies‌ in unknown environments and‌‌ on collective decision-making by consensus. Focusing on the‌ context of defence-related applications,‌ we study these topics‌‌ by particular attention to the robustness of the‌ proposed solutions (e.g. to‌ adversary attacks), and we‌‌ are aiming for solutions that, while adaptable to‌ large swarms, are already‌ effective for small fleets‌‌ of just half a dozen drones. The project‌ funds a PhD thesis‌ in the COATI team‌‌ (strated in 2024) and an engineer in the‌ CHROMA team (H. Diallo,‌ from July 2025).

11‌‌ Dissemination

11.1 Promoting scientific activities

11.1.1 Scientific events:‌ organisation

                      General chair, scientific﻿﻿﻿‌ chair
                      Christian Laugier has﻿‌​‌ been nominated as the﻿​​﻿ future General Chair of​​​‌ the IEEE/RSJ IROS Steering﻿﻿﻿‌ Committee (2026-28).

Member of‌‌ the organizing committees

Olivier Simonin co-organized the "13eme‌ MAFTEC Journées" with L.‌ Matignon and M. Morge‌‌ (LIRIS), in I-Factory, Lyon 22-23 January 2026. (GDR‌ RADIA & AFIA event).‌ Web site

                    
11.1.2 Scientific﻿‌​‌ events: selection

                      Chair of﻿​​﻿ conference program committees
                      Christian​​​‌ Laugier was Editor-in-Chief of﻿﻿﻿‌ the Conference Paper Review﻿‌​‌ Board (CPRB) of the﻿​​﻿ IEEE/RSJ IROS International Conference​​​‌ on Intelligent Robots and﻿﻿﻿‌ Systems (2023-25).

                      Member of﻿‌​‌ the conference program committees﻿​​﻿
                      Christian Laugier was Program​​​‌ Co-Chair of the IEEE/RSJ﻿﻿﻿‌ IROS international conference from﻿‌​‌ 2023 to 2025. He﻿​​﻿ was also a member​​​‌ of the Senior Program﻿﻿﻿‌ Committee of these conferences.﻿‌​‌
Olivier Simonin was Senior﻿​​﻿ Editor for IROS from​​​‌ 2023 to 2025 (IEEE/RSJ﻿﻿﻿‌ International Conference on Intelligent﻿‌​‌ Robots and Systems).
Alessandro﻿​​﻿ Renzaglia was Associate Editor​​​‌ for IROS from 2021﻿﻿﻿‌ to 2025 (IEEE/RSJ International﻿‌​‌ Conference on Intelligent Robots﻿​​﻿ and Systems).
Agostino Martinelli​​​‌ was Associate Editor for﻿﻿﻿‌ ICRA from 2019 to﻿‌​‌ 2025 (IEEE International Conference﻿​​﻿ on Robotics and Automation).​​​‌
Anne Spalanzani was associate﻿﻿﻿‌ editor of the IV﻿‌​‌ 2025 conference.

                      Reviewer
                      O.﻿​​﻿ Simonin, A. Martinelli, A.​​​‌ Spalanzani and A. Renzaglia﻿﻿﻿‌ serve each year as﻿‌​‌ reviewers in conferences IEEE﻿​​﻿ IROS and IEEE ICRA​​​‌ among others.
O. Simonin﻿﻿﻿‌ and A. Renzaglia served﻿‌​‌ as reviewer in the﻿​​﻿ conference ICAPS 2026.

                    
11.1.3​​​‌ Journal

                      Member of the﻿﻿﻿‌ editorial boards
                      Christian Laugier﻿‌​‌ is member of the﻿​​﻿ Editorial Board of the​​​‌ journal IEEE Transactions on﻿﻿﻿‌ Intelligent Vehicles.
Christian Laugier﻿‌​‌ is member of the﻿​​﻿ Editorial Board of the​​​‌ IEEE Journal Robomech.
Olivier﻿﻿﻿‌ Simonin is a member﻿‌​‌ of the editorial board﻿​​﻿ of ROIA, the french​​​‌ revue of AI since﻿﻿﻿‌ 2018 (ex RIA).

                      Reviewer﻿‌​‌ - reviewing activities
                      Alessandro​​​‌ Renzaglia served as reviewer﻿​﻿﻿ for IEEE Robotics and​‌﻿﻿ Automation Letters (RA-L) (2023-2025),​​﻿﻿ Journal of Artificial Intelligence​​​‌ Research (JAIR) (2025), Journal﻿​﻿﻿ on Intelligent Service Robotics​‌﻿﻿ (2025).
Agostino Martinelli served​​﻿﻿ as reviewer for IEEE​​​‌ Transactions on Automatic Control,﻿​﻿﻿ IEEE Transactions on Robotics​‌﻿﻿ (TRO), International Journal of​​﻿﻿ Robotics Research, and IEEE​​​‌ Robotics and Automation Letters﻿​﻿﻿ (RA-L).
Baudouin Saintyves served​‌﻿﻿ as reviewer for Science​​﻿﻿ Robotics, Advanced Functional Materials​​​‌ and RA-L Journal (IEEE﻿​﻿﻿ Robotics and Automation Letter).​‌﻿﻿

                    
11.1.4 Invited talks

                    Olivier​​﻿﻿ Simonin, "Des techniques d'interaction​​​‌ aux stratégies collectives dans﻿​﻿﻿ les essaims de robots",​‌﻿﻿ Sherbrooke University, Canada, July​​﻿﻿ 2025.
Baudouin Saintyves, "Granulobots:​​​‌ A Self-Coordinating Robotic Aggregate﻿​﻿﻿ using Tunable Material-Like Responses",​‌﻿﻿ Sherbrooke University, Canada, June​​﻿﻿ 2025.

11.1.5 Leadership within‌ the scientific community

Olivier Simonin has been appointed‌ as member of the scientific board of the‌ GDR Robotique (since 1/1/2025).
Olivier Simonin is member‌ of the Executive Committee of the PEPR O2R‌ (Organic Robotics) 2023-2030 (www.cnrs.fr/en/pepr/pepr-exploratoire-o2r-robotique).
Christian Laugier‌ is member of the GDR Robotique "comité des‌ sages".
Christian Laugier is a founding member and‌ co-chair of the IEEE RAS Technical Committee on‌ "Autonomous Ground Vehicles and Intelligent Transportation Systems".
Anne‌ Spalanzani co-animates the TS5 "Robotique centrée sur les‌ données" theme for the GDR Robotique.
Anne Spalanzani‌ chaired the ANR CE33 Robotics and Interaction committee.‌

                    
11.1.6 Scientific expertise

                    Anne﻿​﻿﻿ Spalanzani is a jury​‌﻿﻿ member of the Georges​​﻿﻿ Giralt best European PhD​​​‌ in Robotic.
Anne Spalanzani﻿​﻿﻿ chaired the ANR CE33​‌﻿﻿ Robotics and Interaction committee​​﻿﻿ (2023-2025).
Olivier Simonin is​​​‌ reviewer for the ERC﻿​﻿﻿ european funding program (2025).​‌﻿﻿
Olivier Simonin is reviewer​​﻿﻿ each year for ANR​​​‌ projects (Robotics and/or AI﻿​﻿﻿ calls).

                    
11.1.7 Research administration​‌﻿﻿

                    Olivier Simonin was appointed​​﻿﻿ deputy director of the​​​‌ FIL (Federation Informatique de﻿​﻿﻿ Lyon) at the end​‌﻿﻿ of 2025.
Olivier Simonin​​﻿﻿ is member of the​​​‌ Inria Lyon COS (Comité﻿​﻿﻿ d'orientation scientifique).
Olivier Simonin​‌﻿﻿ as been appointed scientific​​﻿﻿ director of the robotics​​​‌ hall of the I-Factory﻿​﻿﻿ (since Dec. 2025).

11.2‌ Teaching - Supervision - Juries - Educational and‌ pedagogical outreach

11.2.1 Supervision

Phd in progress :‌

Mathis Fleuriel,"Exploration coopérative et distribuée en intérieur par‌ des flottes de drones avec des communications limitées",‌ co-supervized by Olivier Simonin (Chroma) and Elena Vanneaux‌ (ENSTA Paris, U2IS), ANR "VORTEX" grant.
Simon Ferrier,‌ "Planification d'itinéraires multi-robots hétérogènes pour des opérations culturales",‌ co-supervized by Olivier Simonin and Alessandro Renzaglia, ANR‌ NINSAR/PEPR "AgroEcol. & Numerique" grant.
Kaushik Bhowmik, "Modeling‌ and prediction of pedestrian behavior on bikes, scooters‌ or hoverboards", co-supervized by A. Spalanzani (CHROMA) and‌ P. Martinet (ACENTAURI, Sophia Antipolis).
Benjamin Sportich, "Next-Best-View‌ Planning for 3D Reconstruction with Cooperative Multi-UAV Systems",‌ co-supervized by A. Renzaglia, O. Simonin (ANR AVENUE).‌
Manuel Diaz Zapata, "AI-based Framework for Scene Understanding‌ and Situation Awareness for Autonomous Vehicles", co-supervized by‌ C. Laugier, J. Dibangoye, O. Simonin.
Jean-Baptiste Horel,‌ "Validation des composants de perception basés sur l’IA‌ dans les véhicules autonomes", co-supervized by R. Mateescu‌ (Inria Convecs), A. Renzaglia, C. Laugier (funded by‌ PRISSMA project).
Gustavo Salazar Gomez, "AI-driven safe motion planning and driving decision-making‌ for autonomous driving", co-supervized‌ by A. Spalanzani, C.‌‌ Laugier.

Phd defended in 2025 :

Rabbia Asghar,‌ "Real-time analysis of complex‌ traffic situations by Predicting/Characterizing‌‌ Abnormal Behaviors and Dangerous Situations", co supervissed by‌ A. Spalanzani, C. Laugier,‌ L. Rummerhard. Defended on‌‌ july 10 2025.
Théotime Balaguer, "Cooperative UAV Fleet‌ based on Wireless Communication,‌ a Flocking Perspective", O.‌‌ Simonin (INSA/Inria Chroma), I. Guérin Lassous (Lyon1/LIP), I.‌ Fantoni (CNRS/LS2N Nantes). Defended‌ in on November, 25th,‌‌ 2025.

11.2.2 Juries

Anne Spalanzani reported on the‌ following PhD and HDR:‌

Charlotte Beaune, Thèse de‌‌ l'école centrale de Nantes, Déc 2025.
Adam Gouget,‌ Thèse de l'Université de‌ Lille, Déc 2025 (President‌‌ of the jury).
Louis Dambacher, Thèse de l'Université‌ Clermont-Auvergne, Juillet 2025.
Yunzhong‌ Zhou, Thèse de l'Université‌‌ de Delft, Industrial Design Engineering, Mars 2025.
Kai‌ Zhang, Thèse de l'Institut‌ Polytechnique de Paris, Mars‌‌ 2025.

Anne Spalanzani examined the following PhD

Emmanuel‌ Alao, Thèse de l'Université‌ de Technologie de Compiègne,‌‌ décembre 2025.
Emilie Leblong, Thèse de l'Université de‌ Rennes, Juillet 2025.

Olivier‌ Simonin reported on the‌‌ following PhD:

Ikrame Yazidi, Thèse de l'Université Marie‌ et Louis Pasteur, FEMTO,‌ Montbéliard, December 19, 2025.‌‌
Shan He, Thèse de l'Université de Technologie de‌ Compiègne, Decembre 16, 2025.‌
Smail Ait Bouhsain, LAAS,‌‌ INSA Toulouse, April 2025 (President of the jury).‌
Marc-Antoine Maheux, Univ. Sherbrooke,‌ Canada, March 25, 2025.‌‌

Olivier Simonin examined the following PhD

Antonio Marino,‌ Université de Rennes, December‌ 4, 2025 (President of‌‌ the Jury).
Maxime Bernard, Université de Rennes, Apris‌ 30, 2025.

11.2.3 Educational‌ and pedagogical activities

Multidisciplinary‌‌ Teaching:

The Physics of Shapes, from Nature to‌ the Hand: Baudouin Saintyves,‌ art and science, 36h,‌‌ School of the Art Institute of Chicago, USA.‌

Teaching in Masters:

Olivier‌ Simonin is in charge‌‌ of the Robotics topic in the new international‌ Master of AI "MINDS",‌ at INSA Lyon, since‌‌ Sept. 2025. He teaches a 16-hour course on‌ introduction to robotics., and‌ a 16-hour course on‌‌ multi-robot cooperation in M2. Alessandro Renzaglia is also‌ teaching 4-hour in M1,‌ on multi-robot coverage and‌‌ exploration.
Alessandro Renzaglia is teaching, each year, at‌ INPG Ense3 Grenoble, Master‌ MARS: AI and Autonomous‌‌ Systems, 12h.
Anne Spalanzani is teaching, each year,‌ at INPG Ense3 Grenoble,‌ Master MARS: Autonomous Robot‌‌ Navigation 6h.
M2R MoSIG: A. Martinelli, Autonomous Robotics,‌ 12h, ENSIMAG

Olivier Simonin's‌ teachings at INSA Lyon‌‌ (engineering school), each year:

INSA Lyon 5th year‌ - Robotics option (20‌ students): AI for Robotics‌‌ (plannning, RL, bio-inspiration), Multi-Robot Systems, Robotics Projects, 80h,‌ Resp., Telecom Dept.
INSA‌ Lyon 4th year :‌‌ Artificial Intelligence (Intro AI, Metaheuristics), 10h (90 students),‌ Telecom Dept.
INSA Lyon‌ 3rd year : Algorithmics,‌‌ 50h (90 students), L3, Resp., Telecom Dept.

Alessandro‌ Renzaglia's teachings at INSA‌ Lyon:

INSA Lyon 5th‌‌ year / Master - Robotics option: Multi-Robot Systems,‌ 4h, Telecom Dept.
INSA‌ Lyon 3rd year /‌‌ Lic.: supervision of research initiation projects (groups of‌ 5 students) along one‌ semester, 15h, Telecom Dept.‌‌

Jacques Saraydaryan's teachings at‌ the CPE Lyon (engineering school), SN Dept.:

CPE‌ Lyon 5th year : Autonomous Robot Navigation 32h,‌ Particle Filter 12h.
CPE Lyon 4-5th year :‌ Software Architecture, 156h.
CPE Lyon 4-5th year :‌ Introduction to Cyber Security, 25h.
CPE Lyon 4-5th‌ year : Software development and big data projects‌ (supervision), 88h.
CPE Lyon 4-5th year : Software‌ Design and Big Data, Resp.

Fabrice Jumel's teachings‌ at the CPE Lyon (engineering school), SN Dept.,‌ each year:

CPE Lyon 4-5th year : Robotic‌ vision, cognitive science, HRI, deep learning, robotic platforms,‌ Kalman Filter, 250h / 288h.

                  
11.3 Popularization

11.3.1​​​‌ Specific official responsibilities in﻿​﻿﻿ science outreach structures

Shapes​‌﻿﻿ of emergence, Founder​​﻿﻿ and co-director of art​​​‌ and science performance project﻿​﻿﻿ Shapes of Emergence (With​‌﻿﻿ Severine Atis, CNRS).

11.3.2​​﻿﻿ Productions (articles, videos, podcasts,​​​‌ serious games, ...)

Society﻿​﻿﻿ for Art and Technology​‌﻿﻿ (SAT), Dome movie​​﻿﻿ Water Organoids, distributed in​​​‌ Dome theter by SAT.﻿​﻿﻿ As part of the​‌﻿﻿ 2025 dome residency program.​​﻿﻿ Montreal, Canada. (Last projection:​​​‌ between Nov 8 and﻿​﻿﻿ Dec 12, 2025).​‌﻿﻿

11.3.3 Participation in Live​​﻿﻿ events

                    « Fête de​​​‌ la science », CITI﻿​﻿﻿ Lab. Chroma, INSA &​‌﻿﻿ Inria Lyon, O. Simonin,​​﻿﻿ T. Balaguer (Phd student),​​​‌ H. Diallo, N. Valle.﻿​﻿﻿ Swarm of UAVs demos.​‌﻿﻿
“Pint of Sciences” O.​​﻿﻿ Simonin & F. Jumel,​​​‌ "L'aube des robots sociaux﻿​﻿﻿ : entre espoirs et​‌﻿﻿ défis", May 20, Lyon,​​﻿﻿ Repère(s).
Pop'Sciences, N. Valle​​​‌ "Danse avec les drones",﻿​﻿﻿ Belleville-en-Beaujolais festival popsciences universite-lyon​‌﻿﻿

Society for Art and​​﻿﻿ Technology, World premier​​​‌ immersive performance venue and﻿​﻿﻿ research center, with dome​‌﻿﻿ and 3d sound facility.​​﻿﻿ As part of the​​​‌ 2025 dome residency program.﻿​﻿﻿ Montreal, Canada. (Oct. 14,​‌﻿﻿ 15, 16, 17, 18,​​﻿﻿ 2025).

Lafayette Electronic​​​‌ Arts Festival, Performance﻿​﻿﻿ “Water Organoids", Lafayette, Colorado,​‌﻿﻿ USA. (May 30, 2025)​​﻿﻿.

11.3.4 Others science​​​‌ outreach relevant activities

                    «﻿​﻿﻿ Inauguration of the I-Factory​‌﻿﻿ - Robotics demos »,​​﻿﻿ A. Betaille, D. Rambeau,​​​‌ N. Valle, O. Simonin,﻿​﻿﻿ Demos of an autonomous​‌﻿﻿ Crazyflie UAV fleet flight​​﻿﻿ and presentation of the​​​‌ semi-humanoid Mirokaï (one day,﻿​﻿﻿ November 13, 2025, open​‌﻿﻿ to all)

12 Scientific production

12.1 Major publications‌

1 inproceedingsR.Rabbia Asghar, L.Lukas‌ Rummelhard, A.Anne Spalanzani and C.Christian‌ Laugier. Allo-centric Occupancy Grid Prediction for Urban‌ Traffic Scene Using Video Prediction Networks.ICARCV‌ 2022 - 17th International Conference on Control, Automation,‌ Robotics and VisionSingapore, SingaporeDecember 2022HAL‌
2 articleG.Guillaume Bono, J.Jilles‌ Dibangoye, O.Olivier Simonin, L.Laëtitia‌ Matignon and F.Florian Pereyron. Solving Multi-Agent‌ Routing Problems Using Deep Attention Mechanisms.IEEE‌ Transactions on Intelligent Transportation SystemsJuly 2021,‌ 1-10HAL DOI
3 incollectionA.Alberto Broggi‌, A.Alex Zelinsky, U.Umit Ozguner‌ and C.Christian Laugier. Handbook of Robotics‌ 2nd edition, Chapter 62 on ''Intelligent Vehicles''.‌Handbook of Robotics 2nd EditionSpringer VerlagJuly‌ 2016HAL
4 inproceedingsT.Thomas Genevois,‌ J.-B.Jean-Baptiste Horel, A.Alessandro Renzaglia and C.Christian Laugier.‌ Augmented Reality on LiDAR‌ data: Going beyond Vehicle-in-the-Loop‌‌ for Automotive Software Validation.IV 2022 -‌ 33rd IEEE Intelligent Vehicles‌ Symposium IVAachen, Germany‌‌IEEEJune 2022, 1-6HAL DOI
5‌ articleA.Agostino Martinelli‌. Local identifiability of‌‌ nonlinear ODE models with time-varying parameters: The general‌ algebraic condition.IEEE‌ Transactions on Automatic Control‌‌October 2025, 1-16HAL DOI
6 article‌A.Agostino Martinelli.‌ Nonlinear unknown input observability‌‌ and unknown input reconstruction: The general analytical solution‌.Information Fusion85‌September 2022, 23-51‌‌HAL DOI
7 articleX.Xiao Peng,‌ O.Olivier Simonin and‌ C.Christine Solnon.‌‌ Non-Crossing Anonymous MAPF for Tethered Robots.Journal‌ of Artificial Intelligence Research‌78October 2023,‌‌ 357-384HAL DOI
8 inproceedingsM.Manon Prédhumeau‌, L.Lyuba Mancheva‌, J.Julie Dugdale‌‌ and A.Anne Spalanzani. An Agent-Based Model‌ to Predict Pedestrians Trajectories‌ with an Autonomous Vehicle‌‌ in Shared Spaces.Proceedings of the 20th‌ International Conference on Autonomous‌ Agents and Multiagent Systems‌‌ (AAMAS 2021)AAMAS 2021 - 20th International Conference‌ on Autonomous Agents and‌ Multiagent SystemsOnline, France‌‌May 2021, 1-9HAL
9 inproceedingsB.‌Benoit Renault, J.‌Jacques Saraydaryan, D.‌‌David Brown and O.Olivier Simonin. Multi-Robot‌ Navigation among Movable Obstacles:‌ Implicit Coordination to Deal‌‌ with Conflicts and Deadlocks.IROS 2024 -‌ IEEE/RSJ International Conference on‌ Intelligent Robots and Systems‌‌Abu DHABI, United Arab EmiratesIEEE2024,‌ 1-7HAL DOI
10‌ articleA.Alessandro Renzaglia‌‌, J.Jilles Dibangoye, V.Vincent Le‌ Doze and O.Olivier‌ Simonin. A Common‌‌ Optimization Framework for Multi-Robot Exploration and Coverage in‌ 3D Environments.Journal‌ of Intelligent and Robotic‌‌ Systems2020HAL DOI

12.2 Publications of the‌ year

International journals

11‌ articleD.David Brown‌‌, J.Jacques Saraydaryan, B.Benoit Renault‌ and O.Olivier Simonin‌. NAMOSIM: a Robot‌‌ Motion Planner for Navigation Among Movable Obstacles.‌Journal of Open Source‌ Software10113September‌‌ 2025, 8816HALDOI back to text‌back to text
12‌ articleI.Iñaki Echeverría-Huarte‌‌, A.Antonin Roge, O.Olivier Simonin‌ and A.Alexandre Nicolas‌. Near-future projections in‌‌ continuous agent-based models for crowd dynamics: mathematical structures‌ in use and their‌ implications.Journal of‌‌ Statistical Mechanics: Theory and ExperimentMarch 2025,‌ 033403HAL DOI
13‌ articleA.Agostino Martinelli‌‌. Local identifiability of nonlinear ODE models with‌ time-varying parameters: The general‌ algebraic condition.IEEE‌‌ Transactions on Automatic ControlOctober 2025, 1-16‌HAL DOI back to‌ text
14 articleX.‌‌Xiao Peng, F.François Schwarzentruber, O.‌Olivier Simonin and C.‌Christine Solnon. Spanning-tree‌‌ based coverage for a tethered robot.IEEE‌ Robotics and Automation Letters‌January 2025, 1-8‌‌In press. HAL

International peer-reviewed conferences

15 inproceedings‌T.Théotime Balaguer,‌ O.Olivier Simonin,‌‌ I.Isabelle Guérin-Lassous and‌ I.Isabelle Fantoni. DANCERS: A Physics and‌ Network Co-Simulator for Communicating Multi-Robot Systems.SIMPAR‌ 2025 - IEEE International Conference on Simulation, Modeling,‌ and Programming for Autonomous RobotsPalermo, ItalyIEEE‌2025, 1-6HALback to text back‌ to text back to text back to text‌
16 inproceedingsT.Théotime Balaguer, O.Olivier‌ Simonin, I.Isabelle Guérin-Lassous and I.Isabelle‌ Fantoni. UAV Chain Network Creation in Cluttered‌ Environment with Flocking Rules and Routing Data.‌IROS 2025 - IEEE/RSJ International Conference on Intelligent‌ Robots and Systems (IROS)Hangzhou, China2025HAL‌back to text back to text back to‌ text
17 inproceedingsG.Guillermo Benito-Calvino, A.‌Ahmed Boubrima, H.Hervé Rivano, A.‌Alessandro Renzaglia and Z.Zhambyl Shaikhanov. Poster:‌ Joint RF-Gas Sensing for Victim Localization using UAV‌ Networks.Mobisys25 - 23rd ACM International Conference‌ on Mobile Systems, Applications, and ServicesAnaheim, United‌ States2025, 1-3HAL DOI
18 inproceedings‌K.Kaushik Bhowmik, A.Anne Spalanzani and‌ P.Philippe Martinet. CG-Net: Urban Trajectory Forecasting‌ with Bipartite Graphs for Agents, Scene Context and‌ Candidate Centerlines.IROS 2025 - IEEE/RSJ International‌ Conference on Intelligent Robots and SystemsHangzhou, China‌2025, 1-7HALback to text back‌ to text
19 inproceedingsM.Mathis Fleuriel,‌ E.Elena Vanneaux, D.David Filliat and‌ O.Olivier Simonin. Exploring Underground Environments by‌ Deploying and Reconfiguring a Chain of Visually Connected‌ UAVs.ECMR 2025 - European Conference on‌ Mobile RobotsPadoue, Italy2025, 1-7HAL‌back to text
20 inproceedingsJ.-B.Jean-Baptiste Horel‌, P.Philippe Ledent, R.Radu Mateescu‌, W.Wendelin Serwe and A.Aline Uwimbabazi‌. Assessing Test Scenarios for Autonomous Driving Using‌ Probabilistic Model Checking.Lecture Notes in Computer‌ ScienceICTSS 2025 - 37th IFIP WG 6.1‌ International Conference on Testing Software and Systems16107‌Lecture Notes in Computer ScienceLimassol, CyprusSpringer‌ Nature SwitzerlandSeptember 2026, 273-289HAL DOI‌
21 inproceedingsB.Benjamin Sportich, A.Alessandro‌ Renzaglia and S.Sara Bernardini. Energy-based Adaptive‌ Coverage Path Planning with Multiple Robots.International‌ conference on Intelligent Autonomous SystemsIAS 2025 -‌ 19th International conference on Intelligent Autonomous SystemsGenova,‌ Italy2025, 1-15HAL

National peer-reviewed Conferences‌

22 inproceedingsM.Mathis Fleuriel, E.Elena‌ Vanneaux, D.David Filliat and O.Olivier‌ Simonin. Exploration d'environnements souterrains par déploiement et‌ réorganisation d'une chaîne de drones.JFSMA 2025‌ - Journées Francophones des Système Multi-AgentsDijon, France‌July 2025HAL
23 inproceedingsC.Chanattan Sok‌ and O.Olivier Simonin. Simulation et résolution‌ de conflits spatiaux entre piétons fondée sur la‌ théorie du choix social.JFSMADijon, France‌CépaduèsJune 2025HAL
24 inproceedingsS.Stéphane‌ d'Alu, H.Hervé Rivano and O.Olivier‌ Simonin. Estimation de distances distribuée FTM-BC par‌ UWB sur systèmes embarqués.CORES 2025 - 10èmes Rencontres Francophones sur‌ la Conception de Protocoles,‌ l'Evaluation de Performances et‌‌ l'Expérimentation des Réseaux de CommunicationCORES 2025 -‌ 10èmes Rencontres Francophones sur‌ la Conception de Protocoles,‌‌ l'Evaluation de Performances et l'Expérimentation des Réseaux de‌ CommunicationSaint Valery-sur-Somme, France‌2025, 1-4HAL‌‌

Doctoral dissertations and habilitation theses

25 thesisR.‌Rabbia Asghar. Uncertainty-Aware‌ Motion Prediction with Dynamic‌‌ Occupancy Grid Maps.Inria Grenoble Rhône-Alpes, Université‌ de GrenobleJuly 2025‌HAL back to text‌‌
26 thesisT.Théotime Balaguer. Cooperative UAV‌ Fleet based on Wireless‌ Communication, a Flocking Perspective‌‌.INSA Lyon - Ecole doctorale d’Informatique et‌ Mathématique de LyonNovember‌ 2025HAL back to‌‌ text back to textback to text

Reports‌ & preprints

27 misc‌B.Benjamin Sportich,‌‌ K.Kenza Boubakri, O.Olivier Simonin and‌ A.Alessandro Renzaglia.‌ Quality-guided UAV Surface Exploration‌‌ for 3D Reconstruction.2025HAL back to‌ text

12.3 Cited publications‌

28 inproceedingsR.Rabbia‌‌ Asghar, W.Wenqian Liu, L.Lukas‌ Rummelhard, A.Anne‌ Spalanzani and C.Christian‌‌ Laugier. Flow-guided Motion Prediction with Semantics and‌ Dynamic Occupancy Grid Maps‌.ITSC 2024 -‌‌ 27th IEEE International Conference on Intelligent Transportation Systems‌Edmonton, CanadaIEEESeptember‌ 2024, 1-6HAL‌‌DOI back to text
29 miscR.Rabbia‌ Asghar, W.Wenqian‌ Liu, L.Lukas‌‌ Rummelhard, A.Anne Spalanzani and C.Christian‌ Laugier. Integrating Specialized‌ and Generic Agent Motion‌‌ Prediction with Dynamic Occupancy Grid Maps.Poster‌October 2024, 1-1‌HAL back to text‌‌
30 inproceedingsL.Lara Briñón-Arranz, M.Martin‌ Abou Hamad and A.‌Alessandro Renzaglia. Voronoi-based‌‌ Multi-Robot Formations for 3D Source Seeking via Cooperative‌ Gradient Estimation.ICARCV‌ 2024 - 18th International‌‌ Conference on Control, Automation, Robotics and VisionDubai,‌ United Arab EmiratesDecember‌ 2024, 1-6HAL‌‌back to text
31 inproceedingsE.Erwan Escudie‌, L.Laëtitia Matignon‌ and J.Jacques Saraydaryan‌‌. Attention Graph for Multi-Robot Social Navigation with‌ Deep Reinforcement Learning.‌Proceedings of the 23rd‌‌ International Conference on Autonomous Agents and Multiagent Systems‌Social Robot Navigation and‌ Multi-Agent and Reinforcement Learning‌‌ and Multi-Robot Navigation and Graph Neural Networks and‌ Predictive modelsAuckland, New‌ ZealandMay 2024HAL‌‌back to text back to text
32 book‌S. M.S. M.‌ LaValle. Planning Algorithms‌‌.Available at http://planning.cs.uiuc.edu/Cambridge, U.K.Cambridge University‌ Press2006back to‌ text
33 articleM.‌‌Manon Prédhumeau, L.Lyuba Mancheva, J.‌Julie Dugdale and A.‌Anne Spalanzani. Agent-Based‌‌ Modeling for Predicting Pedestrian Trajectories Around an Autonomous‌ Vehicle.Journal of‌ Artificial Intelligence Research73‌‌April 2022, 1385-1433HAL DOI back to‌ text
34 inproceedingsB.‌Benoit Renault, J.‌‌Jacques Saraydaryan, D.David Brown and O.‌Olivier Simonin. Multi-Robot‌ Navigation among Movable Obstacles:‌‌ Implicit Coordination to Deal with Conflicts and Deadlocks‌.IROS 2024 -‌ IEEE/RSJ International Conference on‌‌ Intelligent Robots and Systems‌Abu DHABI, United Arab EmiratesIEEEOctober 2024‌, 1-7HAL DOIback to text back‌ to text
35 inproceedingsB.Benoit Renault,‌ J.Jacques Saraydaryan and O.Olivier Simonin.‌ Modeling a Social Placement Cost to Extend Navigation‌ Among Movable Obstacles (NAMO) Algorithms.IROS 2020‌ - IEEE/RSJ International Conference on Intelligent Robots and‌ SystemsDOI is not yet properly functionnal, go‌ to IEEEXplore directly : https://ieeexplore.ieee.org/abstract/document/9340892Las Vegas, United‌ StatesOct 2020, 11345-11351HAL DOI back‌ to text
36 articleA.Alessandro Renzaglia,‌ J.Jilles Dibangoye, V.Vincent Le Doze‌ and O.Olivier Simonin. A Common Optimization‌ Framework for Multi-Robot Exploration and Coverage in 3D‌ Environments.Journal of Intelligent and Robotic Systems‌2020HAL DOI back to text

CHROMA - 2025

CHROMA - 2025

2025Activity reportProject-Team​​﻿﻿CHROMA

Keywords

Computer Science​​​‌ and Digital Science

Other Research Topics and​​﻿﻿ Application Domains

1 Team members, visitors,​​​‌ external collaborators

Research Scientists﻿​﻿﻿

Faculty Members​​​‌

Post-Doctoral Fellows

PhD​​​‌ Students

Technical﻿﻿﻿‌ Staff

Interns and Apprentices

Administrative Assistant﻿‌​‌

External Collaborators

2﻿​​﻿ Overall objectives

2.1 Origin​​​‌ of the project

2.2 Research themes

3 Research﻿‌​‌ program

3.1 Introduction

3.2 Perception﻿​​﻿ and Situation Awareness

Project-team​​​‌ positioning

Collaborations​​﻿﻿

3.3 Decision Making​​​‌

Project-team positioning

Collaborations​​​‌

4 Application domains

5 Social and​​﻿﻿ environmental responsibility

5.1 Footprint​​​‌ of research activities

5.2 Impact of research​‌﻿﻿ results

6 Highlights of​​​‌ the year

6.1 Team﻿​﻿﻿ member involvement in the​‌﻿﻿ community

6.2﻿​﻿﻿ Design of Robotic platform​‌﻿﻿

7 Latest software developments,​‌﻿﻿ platforms, open data

7.1 New platforms​‌﻿﻿

7.1.1 Aerial Robot platform​​﻿﻿ : "DIONE" project

7.1.2​​​‌ Barakuda

8 New﻿​﻿﻿ results

8.1 Bayesian Perception​‌﻿﻿ : evolution of the​​﻿﻿ CMCDOT framework

8.2​​​‌ Situation Awareness & Decision-making﻿﻿﻿‌ for Autonomous Vehicles

8.2.1 Situation Understanding﻿​​﻿ and Motion Forecasting

8.2.2​​​‌ AI-driven Motion Planning and﻿​﻿﻿ Temporal Multi-Modality Sensor Fusion​‌﻿﻿ for Semantic Grid Prediction​​﻿﻿

8.2.3 Dynamic Scene Prediction​​​‌ for Urban Driving Scene﻿​﻿﻿ Using Occupancy Grid Maps​‌﻿﻿

8.3﻿‌​‌ Robust state estimation

8.4﻿​​﻿ Online planning and learning​​​‌ for robot navigation

8.4.1﻿﻿﻿‌ Motion-planning in dense pedestrian﻿‌​‌ environments

8.4.2​​​‌ Attention Graph for Multi-Robot﻿​﻿﻿ Social Navigation with Deep​‌﻿﻿ Reinforcement Learning

8.5​​​‌ Multi-Robot path planning and﻿​﻿﻿ mapping

8.5.1 Navigation﻿​﻿﻿ Among Movable Obstacles (NAMO):​‌﻿﻿ extension to multi-robot and​​﻿﻿ social constraints

8.5.2﻿​​﻿ Multi-UAV Exploration and 3D​​​‌ Reconstruction

8.5.3 Multi-robot agricultural itineraries﻿﻿﻿‌ planning (NINSAR project)

8.6 Swarm​​​‌ Robotics & UAV Fleets﻿​﻿﻿

8.6.1 UAV Chain Network​‌﻿﻿ Creation in Cluttered Environment​​﻿﻿ with Flocking Rules and​​​‌ Routing Data

8.6.2 Swarm of​​​‌ visualy connected UAVs for﻿​﻿﻿ exploration of unknown subterrean​‌﻿﻿ environments

8.6.3﻿﻿﻿‌ Robotic Matter

9 Bilateral contracts and﻿﻿﻿‌ grants with industry

9.1﻿‌​‌ Bilateral contracts with industry﻿​​﻿

9.1.1 IRT Nanoelec PULSE​​​‌ – Security of Autonomous﻿﻿﻿‌ Mobile Robotics (2023-2026)

9.2 Bilateral grants​‌﻿﻿ with industry

9.2.1 Start-up​​﻿﻿ maturation : Yona-Robotics (2024-2025)​​​‌

10 Partnerships and​​​‌ cooperations

10.1 International initiatives﻿​﻿﻿

10.1.1 Inria associate team​‌﻿﻿ not involved in an​​﻿﻿ IIL or an international​​​‌ program

10.2​​﻿﻿ International research visitors

10.2.1​​​‌ Visits of international scientists﻿​﻿﻿

François Ferland

10.2.2﻿​﻿﻿ Visits to international teams​‌﻿﻿

Olivier Simonin

10.3 National initiatives

10.3.1​‌﻿﻿ ANR

ANR/BPI Tranfert Robotique​​﻿﻿ "Solar-Nav" project (2025-2027)

ANR TSIA "VORTEX" project﻿﻿﻿‌ (2024-2028)

ANR​​​‌ JCJC "AVENUE" (2023-2026)

ANR​​​‌ "ANNAPOLIS" (2022-2026)

ANR Challenge MOBILEX​​​‌ : 'NAVIR' project (2024-2026)﻿﻿﻿‌

ANR "MaestrIoT"﻿​﻿﻿ (2021-2025)

EquipEx+ "TIRREX" (2021-30)​‌﻿﻿

10.3.2​​​‌ PEPR

PEPR Agroécologie et﻿​﻿﻿ Numérique : NINSAR project​‌﻿﻿ (2023-28)

PEPR O2R Organic​​﻿﻿ Robotics

2025Activity reportProject-TeamCHROMA

Computer Science‌ and Digital Science

Other Research Topics and Application Domains

1 Team members, visitors,‌ external collaborators

Research Scientists

Faculty Members‌

PhD‌ Students

Technical‌ Staff

Administrative Assistant‌‌

2 Overall objectives

2.1 Origin‌ of the project

3 Research‌‌ program

3.2 Perception and Situation Awareness

Project-team‌ positioning

Collaborations

3.3 Decision Making‌

Collaborations‌

5 Social and environmental responsibility

5.1 Footprint‌ of research activities

5.2 Impact of research‌ results

6 Highlights of‌ the year

6.1 Team member involvement in the‌ community

6.2 Design of Robotic platform‌

7 Latest software developments,‌ platforms, open data

7.1 New platforms‌

7.1.1 Aerial Robot platform : "DIONE" project

7.1.2‌ Barakuda

8 New results

8.1 Bayesian Perception‌ : evolution of the CMCDOT framework

8.2‌ Situation Awareness & Decision-making‌ for Autonomous Vehicles

8.2.1 Situation Understanding and Motion Forecasting

8.2.2‌ AI-driven Motion Planning and Temporal Multi-Modality Sensor Fusion‌ for Semantic Grid Prediction

8.2.3 Dynamic Scene Prediction‌ for Urban Driving Scene Using Occupancy Grid Maps‌

8.3‌‌ Robust state estimation

8.4 Online planning and learning‌ for robot navigation

8.4.1‌ Motion-planning in dense pedestrian‌‌ environments

8.4.2‌ Attention Graph for Multi-Robot Social Navigation with Deep‌ Reinforcement Learning

8.5‌ Multi-Robot path planning and mapping

8.5.1 Navigation Among Movable Obstacles (NAMO):‌ extension to multi-robot and social constraints

8.5.2 Multi-UAV Exploration and 3D‌ Reconstruction

8.5.3 Multi-robot agricultural itineraries‌ planning (NINSAR project)

8.6 Swarm‌ Robotics & UAV Fleets

8.6.1 UAV Chain Network‌ Creation in Cluttered Environment with Flocking Rules and‌ Routing Data

8.6.2 Swarm of‌ visualy connected UAVs for exploration of unknown subterrean‌ environments

8.6.3‌ Robotic Matter

9 Bilateral contracts and‌ grants with industry

9.1‌‌ Bilateral contracts with industry

9.1.1 IRT Nanoelec PULSE‌ – Security of Autonomous‌ Mobile Robotics (2023-2026)

9.2 Bilateral grants‌ with industry

9.2.1 Start-up maturation : Yona-Robotics (2024-2025)‌

10 Partnerships and‌ cooperations

10.1 International initiatives

10.1.1 Inria associate team‌ not involved in an IIL or an international‌ program

10.2 International research visitors

10.2.1‌ Visits of international scientists

10.2.2 Visits to international teams‌

10.3.1‌ ANR

ANR/BPI Tranfert Robotique "Solar-Nav" project (2025-2027)

ANR TSIA "VORTEX" project‌ (2024-2028)

ANR‌ JCJC "AVENUE" (2023-2026)

ANR‌ "ANNAPOLIS" (2022-2026)

ANR Challenge MOBILEX‌ : 'NAVIR' project (2024-2026)‌

ANR "MaestrIoT" (2021-2025)

EquipEx+ "TIRREX" (2021-30)‌

10.3.2‌ PEPR

PEPR Agroécologie et Numérique : NINSAR project‌ (2023-28)

PEPR O2R Organic Robotics

10.3.3 INRIA/AID AI‌ projects

11‌‌ Dissemination

11.1 Promoting scientific activities

11.1.1 Scientific events:‌ organisation

General chair, scientific‌ chair

Member of‌‌ the organizing committees

11.1.2 Scientific‌‌ events: selection

Chair of conference program committees

Member of‌‌ the conference program committees

11.1.3‌ Journal

Member of the‌ editorial boards

Reviewer‌‌ - reviewing activities

11.1.5 Leadership within‌ the scientific community