6.1.1 ALIAS

• Name: Algorithms Library of Interval Analysis for Systems
• Keyword: Interval analysis
• Functional Description:

  The ALIAS library whose development started in 1998, is a collection of procedures based on interval analysis for systems solving and optimization.

  ALIAS is made of two parts:

  ALIAS-C++ : the C++ library (87 000 code lines) which is the core of the algorithms

  ALIAS-Maple : the Maple interface for ALIAS-C++ (55 000 code lines). This interface allows one to specify a solving problem within Maple and get the results within the same Maple session. The role of this interface is not only to generate the C++ code automatically, but also to perform an analysis of the problem in order to improve the efficiency of the solver. Furthermore, a distributed implementation of the algorithms is available directly within the interface.

• URL: http://www-sop.inria.fr/hephaistos/developpements/main.html
• Contact: Jean-Pierre Merlet
• Participants: Jean-Pierre Merlet, Odile Pourtallier

6.2.1 ALIAS, Algorithms Library of Interval Analysis for Systems

Participants: Jean-Pierre Merlet, Yves Papegay.

URL: http://www-sop.inria.fr/hephaistos/developpements/main.html

The ALIAS library whose development started in 1998, is a collection of procedures based on interval analysis for systems solving and optimization. As mentioned in the previous section it is one of the main software development of the team and is updated frequently with the addition of specific modules, most of which are developped when dealing with specific problems that have been treated during the year.

This year we have for example used ALIAS to provide certified solutions of the kinematicsof a cable-driven parallel robots, a very complex problem,  2. We have confirmed the solutions that has been provided by a computer intensive iterative methods and have shown that the interval analysis method was able to manage a more complex case for which the iterative method cannot be reasonably used.

6.2.2 Hardware platforms

We describe here only the new platforms that have been developed or improved in 2019 while we maintain a very large number of platforms (e.g. the cable-driven parallel robots of the MARIONET family, the ANG family of walking aids,r our experimental flat and the activities detection platform implemented in the day hospital Institut Claude Pompidou and EHPAD Valrose, Nice ).

7.1.1 Analysis of Cable-driven parallel robots

Participants: Jean-Pierre Merlet, Yves Papegay.

We have continued the analysis of suspended CDPRs for control and design purposes. This analysis is heavily dependent on the behavior of the cable. Three main models can be used: ideal (no deformation of the cable due to the tension, the cable shape is a straight line between the attachments points), elastic (cable length changes according to the tension to which it is submitted, straight line cable shape) and sagging (cable shape is not a line as the cable is submitted to its own mass). The different models leads to very different analysis with a complexity increasing from ideal to sagging. All cables exhibit sagging but the sagging effect is often neglected if the CDPR is relatively small while it definitively cannot be neglected for large CDPRs. The most used sagging model is the Irvine model  18. This is a non algebraic planar model with the upper attachment point of the cable is supposed to be grounded: it provides the coordinates of the lowest attachment point $B$ of the cable if the cable length $L_0$ at rest and the force applied at this point are known. It takes into account both the elasticity and deformation of the cable due to its own mass. A drawback of this model is that we will be more interested in a closed-form of the $L_0$ for a given pose of $B$ (for the inverse kinematics of CDPR) and in alternate form of the model that will provide constraint on the force components (for the direct kinematics). These equations appears in the kinematic equations for example in the inverse and direct kinematics (i.e finding all possible solutions for both problems) that are required for CDPRs control. This year the direct kinematics has been solved for the 4-1 CDPR (4 cables attached at the same point, leading to a 3dof robot)3.

7.1.2 Cable-Driven Parallel Robots for large scale additive manufacturing

Participants: Jean-Pierre Merlet, Yves Papegay.

Easy to deploy and to reconfigure, dynamically efficient in large workspaces even with payloads, cable-driven parallel robots are very attractive for solving displacement and positioning problems in architectural building at large scale seems to be a good alternative to crane and industrial manipulators in the area of additive manufacturing.

We have been contacted in 2018 by the artist Anne-Valérie Gasc that is interested in mimicking the 3D additive manufacturing process on large scale for a live art performance. She was interested in a mean for widespreading glass micro-beads on a given trajectory over a 21 $\times$ 9m large platform located at the contemporary art center Les Tanneries, located close to Montargis. She was especially interested in using a CDPR for that purpose because of the low visual intrusivity of the cables and its ability to move large load. After a few month of discussions we agree to recycle our old MARIONET-CRANE prototype (2009) for this exhibition although the place was not the most appropriate for the CDPR as the height of the location was only 3 meters.The system was fully operational a few days after the official opening of the exhibition and was at the heart of the artistic exhibition "Les Larmes du Prince - Vitrifications" (http://www.lestanneries.fr/exposition/larmes-prince-vitrifications), that was run during July and August 2019 under the control of a local student.

After this first successful operation we were planning to exhibit this robot as a demonstration during the largest robotics conference ICRA which was planned to be held at Paris in May 2020. The exhibition place was slightly different but our robot is designed to be modular in order to adapt his performance to the available size and requested performance. We have also analyzed from the large amount of data that has been retrieved during the 2019 experiments to improve our CDPR. A persistent problem for CDPR is improve the positioning accuracy. The pose of the moving platform is usually obtained from the estimation of the cable lengths that are fed to a direct kinematics solve that compute the pose. The cable lengths estimation are obtained from the measurement of the winch drums rotation but for large CDPR we have several layers on the drum and the coiling process is erratic. Consequently over time the lengths estimation may derive with time leading to an increasing inaccuracy. For the 2019 experiment we were measuring the altitude of the platform with a lidar so that we were fusing the length measurements with a partial observation of the pose that has led to an acceptable positioning accuracy. However we were willing to go on to improve this accuracy and we have thus first added 2 more horizontal lidars and have placed around the CDPR three vertical walls whose position in the reference frame has been calibrated with a theodolite. An algorithm has been developed that first detect the measured lidar points lying on these walls and then fit vertical planes on that points. This fit allow to determine the location of the center of the lidars in the reference frame from which we deduce the location of the moving platform. This method enables to locate the moving platform with an accuracy of less than 2mm in the horizontal direction and 0.5 mm in the vertical direction at a frequency of about 5Hz, this approach being original in the CDPR community. Provided that we know which cables are under tension (we have 4 cables but it has been proven that almost every case there will be at most 3 cables under tension while the other cables are slack) this pose estimation allows to determine what are the cable lengths. Hence we may update the estimation provided by the drum rotation and in between two lidars pose estimation we will gen an accurate pose estimation from the cable lengths at a frequency of about 100 Hz.

Hence there is necessity to determine which CDPR cables are slack. It may be thought that force sensor may be used but it has been shown that measuring cable tensions is extremely difficult to put in place and provide only very approximate measurements. Therefore we have decided to use another approach based on the measurement of the angle between the cable and the vertical at a specific point on the cable. This angle is measured by a small accelerometer that is fixed on the cable. Using the pose estimation and this angle we are able to use the Irvine equation to determine not only the tension in the cable but also its length and therefore to obtain an accurate estimation of all the cable lengths. A further interest is that when following trajectories there will be various set of cables under tension. As cable slackness is unavoidable it is of interest to have the length of slack cable always close to their length when under tension so that to avoid disturbances during a transition between various under-tension cables configuration. We have designed a control strategy based on the angle measurements for that purpose.

Our prototype, figure 1, in its ICRA configuration has been tested at INRIA and was ready to be shipped to Paris. Unfortunately ICRA has been canceled because of the Covid.

7.3.1 Behavior of the potter wasp insect

In 2020, through an international scientific cooperation with Israeli scientists located at the Ben-Gurion University of the Negev, we developed a probabilistic model whose aim is to understand a strange – and up to now not understandable – reproductive behavior of the potter wasp insect Delta dimidiatipenne (Hymenoptera). Females of this insect lay their eggs in mud chambers provisioned with caterpillars they capture to feed their young. Preliminary observations indicate that many of the caterpillars collected by this wasp are actually parasitized by a small gregarious parasitoid wasp and are providing a lower amount of food for the wasp progeny. As a result, all players in the interaction perish – the young potter wasp cannot fully exploit the caterpillars and presumably starve to death; and the small parasitoids complete their development, but cannot break out of the mud and remain trapped in the sealed pot. We developed a probabilistic model trying to find under what environmental conditions such a striking phenomenon (i.e., bringing back to the nest parasitized caterpillars), can be maintained, despite the high cost to all players. The graph 5 gives an example of the results obtained, showing the overall number of progeny produced as a function of the proportion of parasitized caterpillar in the environment pParasitized and the probability of the foraging female to be able to recognize correctly a healthy from a parasitized caterpillar pDiscrimination.

The number of overall progeny produced is almost always different from zero, i.e., wasp females are always able to produce progeny, so bringing back parasitized caterpillars to the nest can be a surviving strategy. The results will be included in a publication that will be submitted to an international scientific journal.

7.3.2 Optimized flower visiting strategy of bees

In 2020, through an international scientific cooperation with Israeli scientists located at the University of Haifa, we developed an optimization deterministic model trying to understand what should be the optimized flower visiting strategy of bees foraging for nectar. Bees are actually visiting either simple or complex flowers. The reward acquired on simple flowers is easy to obtain and do not need a learning ability. On complex flowers, however, bees need to learn how to forage on them to get a reward. Once the learning period has been done, however, the reward acquired on complex flowers is higher than on simple flowers. One question is how the beehive can sustain the time needed for the bees to learn how to forage on complex flowers. Are there bees keeping on foraging on simple flowers to get back sufficient food to the hive for the entire colony, and to enable others to take the needed time to learn? The model we developed keeps tract of bee foraging behavior starting their learning process on complex flower at different time following at optimized time schedule. The need for a fixed proportion of bees – that are “household workers” and/or larvae – to remain in the hive to maintain its activity, was also taken into account. Optimized results were obtained under different situations, based on specific computational algorithms that we had to implement. As an example, the graph 6 gives the optimized number of bees progressively going to complex flowers in the course of time, for an increasing proportion of bees remaining in the hive (all other parameters fixed to their default values, e.g., in this case there are 100 bees in the hive). The results we obtained are providing a couple of predictions that are now being tested on real animals in the University of Haifa in Israel. Also, these results will soon be included in a publication under preparation to be inserted in a Special Issue that will be published in the Philosophical Transactions of the Royal Society B.

8.1.1 Pedagogical cable-driven parallel robot

Participants: Jean-Pierre Merlet.

We have started to write a pedagogical manual describing various experiments allowing to physically illustrate scientific concepts in various fields (mathematics, computer network, mechanics, robotics, ...). This kit will tested by teachers and then commercialized by GenerationRobot probably at the end of 2021.

8.1.2 Symbolic tools for modeling and simulation

Participants: Yves Papegay.

This activity is the main part of a long-term ongoing collaboration with Airbus whose goal is to directly translate the conceptual work of aeronautics engineers into digital simulators to accelerate aircraft design.

An extensive modeling and simulation platform - MOSELA - has been designed which includes a dedicated modeling language for the description of aircraft dynamics models in term of formulae and algorithms, and a symbolic compiler producing as target an efficient numerical simulation code ready to be plugged into a flight simulator, as well as a formatted documentation compliant with industrial requirements of corporate memory.

Technology demonstrated by our prototype has been transferred : final version of our modeling and simulation environment has been delivered to Airbus in November 2012 and developer level know-how has been transferred in 2013 to a software company in charge of its industrialization and maintenance.

Since 2014, we are working on several enhancements and extension of functionalities, namely to enhance the performances and the numerical quality of the generated C simulation code, ease the integration of our environment into the airbus toolbox, help improving the robustness of the environment and the documentation.

Informal international partners

We have numerous international collaborations but we mention here only the one with activities that go beyond joint theoretical or experimental works:

• University of Bologna, Italy: 2 joint PhD student, publications
• University Innsbruck, Austria: joint conference organization
• Fraunhofer IPA, Stuttgar, Germany: joint conference organization
• Duisburg-Essen University, Germany: joint conference organization
• University of New-Brunswick, Canada: 1 joint PhD student 13
• University Laval, Québec, Canada: joint book
• University of Tokyo, Japan: joint conference organization
• Tianjin University, China: joint book

9.2.1 FP7 & H2020 Projects

A project called ROCABLE will be funded by the COVR project that received funding from the European Union's Horizon 2020 research and innovation programme. This project is intented to deal with the safety of cable-driven parallel robot with as partners LS2N, Hephaistos, IRT T Jules Verne and Eiffage-Clemessy.

10.1.1 Scientific Events: Organisation

• J-P. Merlet is a permanent member of the International Steering Committee of the IROS conference, of the CableCon conference and chairman of the scientific Committee of the Computational Kinematics workshop. He was also an advisor for the largest robotics conference ICRA 2020, that has finally being held virtually because of the Covid,
• Y. Papegay is a permanent member of the International Steering Committee of the International Mathematica Symposium conferences series. He is a member of the OpenMath Society, building an extensible standard for representing the semantics of mathematical objects.

10.1.2 Leadership within the scientific community

• J-P. Merlet is a member of the IFToMM (International Federation for the Promotion of Mechanism and Machine Science) Technical Committees on History and on Computational Kinematics. He is a member of the scientific committee of the CNRS GDR robotique and a chair of 3IA Côte d'Azur.

10.1.3 Scientific expertise

• J-P. Merlet was involved in project evaluations for several foreign funding agencies (Israel, Austria, ERC). He was also appointed as Nominator for the Japan's Prize.
• E. Wajnberg is involved in project evaluation for several foreign funding agencies (Belgium, Italy).
• E. Wajnberg was invited to be a committee number for recruiting an Institute Director by the CNR (Rome, Italy)

10.1.4 Research administration

• J-P. Merlet is a corresponding member of Inria ethical committee (COERLE) and member of the Research, Ethical Committees of UCA (CERNI). He is an elected member of Inria Scientific Committee
• Y. Papegay is a member of the CUMI (and its president since January 2021)(the committee managing the interaction between researchers and the computer support staff)
• O. Pourtallier was responsible of the Inria NICE committee until June 2020 (long term, she is now member of this committee. It is the committee for invited scientists and post-doctoral student selection.).
• O. Pourtallier was a board member of the Scientific and Pedagogical Council of DS4H graduate school of UCA until October 2020.
• O. Pourtallier is a substitute board member of SeaTech, an Engineering School of University of Toulon.
• O. Pourtallier was vice president of the local researcher recruitment jury.

10.2.1 Member of the editorial boards

• E. Wajnberg is Editor-in-Chief of the journal BioControl (published by Springer).
• E. Wajnberg is a board member of the journals Entomologia Experimentalis et Applicata (published by Wiley), Neotropical Entomology (published by Springer), Applied Entomology and Zoology (published by Springer), and Journal of Economical Entomology (Publish by Oxford University Press).

10.3.1 Teaching

• J-P. Merlet has taught 9 hours on parallel robots to Master ISC (M2) at University of Toulon.
• Y. Papegay has taught 6 hours on parallel robots to Master ISC (M2) at University of Toulon
• P. Pourtallier lectured 6 hours on game theory to Master OSE (M2), at École des Mines de Paris, Sophia Antipolis, France
• E. Wajnberg lectured One week course (about 30 h) about the use of the R program and statistics for PhD students and senior scientists in Rehovot (Israel, February)

10.3.2 Supervision

• W. Plouvier. Improving pest control efficiency: a modelling approach (2015-2020). Supervisor: E. Wajnberg.
• E. Thomine. Agencement cultural pour promouvoir le transfert des services écosystémiques de biocontrôle au sein des paysages agricoles (2016 to 2020). Supervisors : N. Desneux & E. Wajnberg.

10.3.3 Juries

• J-P. Merlet has been president of 2 PhD juries and jury members of 5 PhD theses.

10.4.1 Interventions

• the HEPHAISTOS project has on average about 100 visitors per year, either young students or teachers, to which we present our robotics and assistance activities

10.4.2 Internal action

• the HEPHAISTOS project has developed a set of cable-driven parallel robots, the MARIONET-SCHOOL series, that is used to illustrate visually scientific concepts in various domains

International journals

• 9 articleEricE. Conti, GonzaloG. Avila, BarbaraB. Barratt, FernandaF. Cingolani, StefanoS. Colazza, SalvatoreS. Guarino, KimK. Hoelmer, Raul AlbertoR. Laumann, LaraL. Maistrello, GuillaumeG. Martel, EzioE. Peri, CesarC. Rodriguez‐Saona, GabrieleG. Rondoni, MichaelM. Rostás, Pio FedericoP. Roversi, René F.H.R. Sforza, LucianaL. Tavella and EricE. Wajnberg. Biological control of invasive stink bugs: review of global state and future prospectsEntomologia Experimentalis et Applicata1691January 2021, 28-51
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• 10 articleEricE. Conti, EricE. Wajnberg and LeoL. Beukeboom. Entomophagous insects – an introductionEntomologia Experimentalis et Applicata1691January 2021, 3-5
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• 11 articleEricE. Conti, EricE. Wajnberg and LeoL. Beukeboom. Preface of Special Issue: 6th International Entomophagous Insects ConferenceEntomologia Experimentalis et Applicata1691January 2021, 2
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• 12 article YasufumiY. Nakamichi, MidoriM. Tuda and EricE. Wajnberg. Intraspecific interference between native parasitoids modified by a non-native parasitoid and its consequence on population dynamics Ecological Entomology November 2020
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• 13 articleJoshua K.J. Pickard, Juan AJ. Carretero and Jean-PierreJ.-P. Merlet. Appropriate synthesis of the four-bar linkageMechanism and Machine Theory153November 2020, 103965
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• 14 articleMichalM. Segoli and EricE. Wajnberg. The combined effect of host and food availability on optimized parasitoid life‐history traits based on a three‐dimensional trade‐off surfaceJournal of Evolutionary Biology336June 2020, 850-857
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• 15 article MilosM. Sevarika, Maria CristinaM. Foti, EzioE. Peri, StefanoS. Colazza and EricE. Wajnberg. Genetic variation in the behavioural mechanisms involved in the response of the egg parasitoid Trissolcus brochymenae to contact chemical cues left by the pest Murgantia histrionica Ecological Entomology January 2021
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Scientific book chapters

• 16 inbookStéphaneS. Caro and Jean-PierreJ.-P. Merlet. Failure Analysis of a Collaborative 4-1 Cable-Driven Parallel Robot89European Conference on Mechanism Science (EuCoMeS 2020): New Trends in Mechanism and Machine ScienceAugust 2020, 440-447
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Reports & preprints

• 17 misc StéphaneS. Caro and Jean-PierreJ.-P. Merlet. Failure Analysis of a Collaborative 4-1 Cable-Driven Parallel Robot April 2020
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