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1. Locomotion Dynamics of an Underactuated Three-Link Robotic Vehicle

Author

Rizyaev, Leonid and Or, Yizhar

Subjects
Computer Science - Robotics
Abstract

The wheeled three-link snake robot is a well-known example of an underactuated system modelled using nonholonomic constraints, preventing lateral slippage (skid) of the wheels. A kinematically controlled configuration assumes that both joint angles are directly prescribed as phase-shifted periodic input. In another configuration of the robot, only one joint is periodically actuated while the second joint is passively governed by a visco-elastic torsion spring. In our work, we constructed the two configurations of the wheeled robot and conducted motion experiments under different actuation inputs. Analysis of the motion tracking measurements reveals a significant amount of wheels' skid, in contrast to the assumptions used in standard nonholonomic models. Therefore, we propose modified dynamic models which include wheels' skid and viscous friction forces, as well as rolling resistance. After parameter fitting, these dynamic models reach good agreement with the motion measurements, including effects of input's frequency on the mean speed and net displacement per period. This illustrates the importance of incorporating wheels' skid and friction into the system's model.

Published
2024

2. Dynamic single-input control of multi-state multi-transition soft robotic actuator

Author

Yamit, Geron, Eran, Ben-Haim, Amir, Gat D., Yizhar, Or, and Sefi, Givli

Subjects
Computer Science - Robotics, Physics - Applied Physics
Abstract

Soft robotics is an attractive and rapidly emerging field, in which actuation is coupled with the elastic response of the robot's structure to achieve complex deformation patterns. A crucial challenge is the need for multiple control inputs, which adds significant complication to the system. We propose a novel concept of single-input control of an actuator composed of interconnected bi-stable elements. Dynamic response of the actuator and pre-designed differences between the elements are exploited to facilitate any desired multi-state transition, using a single dynamic input. We show formulation and analysis of the control system's dynamics and pre-design of its multiple equilibrium states, as well as their stability. Then we fabricate and demonstrate experimentally on single-input control of two- and four-element actuators, where the latter can achieve transitions between up to 48 desired states. Our work paves the way for next-generation soft robotic actuators with minimal actuation and maximal dexterity., Comment: 6 figures

Published
2024

3. Multistable Physical Neural Networks

Author

Ben-Haim, Eran, Givli, Sefi, Or, Yizhar, and Gat, Amir

Subjects
Computer Science - Neural and Evolutionary Computing, Nonlinear Sciences - Adaptation and Self-Organizing Systems
Abstract

Artificial neural networks (ANNs), which are inspired by the brain, are a central pillar in the ongoing breakthrough in artificial intelligence. In recent years, researchers have examined mechanical implementations of ANNs, denoted as Physical Neural Networks (PNNs). PNNs offer the opportunity to view common materials and physical phenomena as networks, and to associate computational power with them. In this work, we incorporated mechanical bistability into PNNs, enabling memory and a direct link between computation and physical action. To achieve this, we consider an interconnected network of bistable liquid-filled chambers. We first map all possible equilibrium configurations or steady states, and then examine their stability. Building on these maps, both global and local algorithms for training multistable PNNs are implemented. These algorithms enable us to systematically examine the network's capability to achieve stable output states and thus the network's ability to perform computational tasks. By incorporating PNNs and multistability, we can design structures that mechanically perform tasks typically associated with electronic neural networks, while directly obtaining physical actuation. The insights gained from our study pave the way for the implementation of intelligent structures in smart tech, metamaterials, medical devices, soft robotics, and other fields., Comment: 21 pages, 6 figures

Published
2024

4. A bistable inhibitory optoGPCR for multiplexed optogenetic control of neural circuits

Author

Wietek, Jonas, Nozownik, Adrianna, Pulin, Mauro, Saraf-Sinik, Inbar, Matosevich, Noa, Gowrishankar, Raajaram, Gat, Asaf, Malan, Daniela, Brown, Bobbie J., Dine, Julien, Imambocus, Bibi Nusreen, Levy, Rivka, Sauter, Kathrin, Litvin, Anna, Regev, Noa, Subramaniam, Suraj, Abrera, Khalid, Summarli, Dustin, Goren, Eva Madeline, Mizrachi, Gili, Bitton, Eyal, Benjamin, Asaf, Copits, Bryan A., Sasse, Philipp, Rost, Benjamin R., Schmitz, Dietmar, Bruchas, Michael R., Soba, Peter, Oren-Suissa, Meital, Nir, Yuval, Wiegert, J. Simon, and Yizhar, Ofer

Published
2024
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6. Dynamics of Purcell-type microswimmers with active-elastic joints

Author

Zigelman, Anna, Zvi, Gilad Ben, and Or, Yizhar

Subjects
Physics - Fluid Dynamics, Mathematical Physics, Nonlinear Sciences - Chaotic Dynamics
Abstract

Purcell's planar three-link microswimmer is a classic model of swimming in low-Reynolds-number fluid, inspired by motion of flagellated microorganisms. Many works analyzed this model, assuming that the two joint angles are directly prescribed in phase-shifted periodic inputs. In this work, we study a more realistic scenario by considering an extension of this model which accounts for joints' elasticity and mechanical actuation of periodic torques, so that the joint angles are dynamically evolving. Numerical analysis of the swimmer's dynamics reveals multiplicity of periodic solutions, depending on parameters of the inputs - frequency and amplitude of excitation, joints' stiffness ratio, as well as joint's activation. We numerically study swimming direction reversal, as well as bifurcations, stability transitions, and symmetry breaking of the periodic solutions, which represent the effect of buckling instability observed in swimming microorganisms. The results demonstrate that this variant of Purcell's simple model displays rich nonlinear dynamic behavior with actuated-elastic joints. Similar results are also obtained when studying an extended model of a six-link microswimmer.

Published
2023
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7. Co-coding of head and whisker movements by both VPM and POm thalamic neurons

Author

Tess Baker Oram, Alon Tenzer, Inbar Saraf-Sinik, Ofer Yizhar, and Ehud Ahissar

Subjects
Science
Abstract

Abstract Rodents continuously move their heads and whiskers in a coordinated manner while perceiving objects through whisker-touch. Studies in head-fixed rodents showed that the ventroposterior medial (VPM) and posterior medial (POm) thalamic nuclei code for whisker kinematics, with POm involvement reduced in awake animals. To examine VPM and POm involvement in coding head and whisker kinematics in awake, head-free conditions, we recorded thalamic neuronal activity and tracked head and whisker movements in male mice exploring an open arena. Using optogenetic tagging, we found that in freely moving mice, both nuclei equally coded whisker kinematics and robustly coded head kinematics. The fraction of neurons coding head kinematics increased after whisker trimming, ruling out whisker-mediated coding. Optogenetic activation of thalamic neurons evoked overt kinematic changes and increased the fraction of neurons leading changes in head kinematics. Our data suggest that VPM and POm integrate head and whisker information and can influence head kinematics during tactile perception.

Published
2024
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9. Nonlinear dynamics and bifurcations of a planar undulating magnetic microswimmer

Author

Paul, Jithu, Or, Yizhar, and Gendelman, Oleg

Subjects
Physics - Fluid Dynamics, Nonlinear Sciences - Chaotic Dynamics
Abstract

Swimming micro-organisms such as flagellated bacteria and sperm cells have fascinating locomotion capabilities. Inspired by their natural motion, there is an ongoing effort to develop artificial robotic nano-swimmers for potential in-body biomedical applications. A leading method for actuation of nano-swimmers is by applying a time-varying external magnetic field. Such systems have rich and nonlinear dynamics that calls for simple fundamental models. A previous work studied forward motion of a simple two-link model with passive elastic joint, assuming small-amplitude planar oscillations of the magnetic field about a constant direction. In this work, we found that there exists a faster, backward motion of the swimmer with very rich dynamics. By relaxing the small-amplitude assumption, we analyze the multiplicity of periodic solutions, as well as their bifurcations, symmetry breaking, and stability transitions. We have also found that the net displacement and/or mean swimming speed are maximized for optimal choices of various parameters. Asymptotic calculations are performed for the bifurcation condition and the swimmer's mean speed. The results may enable significantly improving the design aspects of magnetically-actuated robotic microswimmer., Comment: version 3, revised and resubmitted for review as journal publication

Published
2022
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10. Genomic characterization and therapeutic utilization of IL-13-responsive sequences in asthma

Author

Koh, Kyung Duk, Bonser, Luke R, Eckalbar, Walter L, Yizhar-Barnea, Ofer, Shen, Jiangshan, Zeng, Xiaoning, Hargett, Kirsten L, Sun, Dingyuan I, Zlock, Lorna T, Finkbeiner, Walter E, Ahituv, Nadav, and Erle, David J

Subjects
Biochemistry and Cell Biology, Bioinformatics and Computational Biology, Genetics, Biological Sciences, Lung, Biotechnology, Asthma, Human Genome, 2.1 Biological and endogenous factors, Aetiology, Respiratory, Good Health and Well Being, CRISPRi, HBEC, IL-13, SPDEF, asthma, cell-specific, enhancer
Abstract

Epithelial responses to the cytokine interleukin-13 (IL-13) cause airway obstruction in asthma. Here we utilized multiple genomic techniques to identify IL-13-responsive regulatory elements in bronchial epithelial cells and used these data to develop a CRISPR interference (CRISPRi)-based therapeutic approach to downregulate airway obstruction-inducing genes in a cell type- and IL-13-specific manner. Using single-cell RNA sequencing (scRNA-seq) and acetylated lysine 27 on histone 3 (H3K27ac) chromatin immunoprecipitation sequencing (ChIP-seq) in primary human bronchial epithelial cells, we identified IL-13-responsive genes and regulatory elements. These sequences were functionally validated and optimized via massively parallel reporter assays (MPRAs) for IL-13-inducible activity. The top secretory cell-selective sequence from the MPRA, a novel, distal enhancer of the sterile alpha motif pointed domain containing E-26 transformation-specific transcription factor (SPDEF) gene, was utilized to drive CRISPRi and knock down SPDEF or mucin 5AC (MUC5AC), both involved in pathologic mucus production in asthma. Our work provides a catalog of cell type-specific genes and regulatory elements involved in IL-13 bronchial epithelial response and showcases their use for therapeutic purposes.

Published
2023

11. Hearing temperatures: employing machine learning for elucidating the cross-modal perception of thermal properties through audition

Author

Mohr Wenger, Amber Maimon, Or Yizhar, Adi Snir, Yonatan Sasson, and Amir Amedi

Subjects
cross-modal correspondences, multisensory integration, sensory, thermal perception, multimodal, Psychology, BF1-990
Abstract

People can use their sense of hearing for discerning thermal properties, though they are for the most part unaware that they can do so. While people unequivocally claim that they cannot perceive the temperature of pouring water through the auditory properties of hearing it being poured, our research further strengthens the understanding that they can. This multimodal ability is implicitly acquired in humans, likely through perceptual learning over the lifetime of exposure to the differences in the physical attributes of pouring water. In this study, we explore people’s perception of this intriguing cross modal correspondence, and investigate the psychophysical foundations of this complex ecological mapping by employing machine learning. Our results show that not only can the auditory properties of pouring water be classified by humans in practice, the physical characteristics underlying this phenomenon can also be classified by a pre-trained deep neural network.

Published
2024
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13. Dynamics of reconfigurable straw-like elements

Author

Ilssar, Dotan, Pukshansky, Michael, Or, Yizhar, and Gat, Amir D.

Subjects
Physics - Applied Physics, Physics - Fluid Dynamics
Abstract

In this paper, we discuss the dynamic modeling of fluid-filled straw-like elements consisting of serially interconnected elastic frusta with both axisymmetric and antisymmetric degrees of freedom, assuming planar motion. Under appropriate conditions each sub-structure has four stable equilibrium states. This gives the system under investigation the ability to remain stable in a large number of complex states, which is a vital ability for myriad of applications, including reconfigurable structures and soft robots. The theoretical model explains the dynamics of a single straw-like element in a discrete manner, considering inertial, damping, and gravitational effects, while taking into account the nonlinear elasticity of the elastic frusta, and assuming hydrostatic behavior of the entrapped fluid. After identifying the geometric and elastic parameters of the theoretical model based on relatively simple experiments, the model is validated compared to numerical simulations and experiments. The numerical simulations validate the theoretical elasticity of the elastic frusta, whereas the overall dynamic behavior of the system and the influence of unmodeled fluidic effects are examined experimentally. It is demonstrated both theoretically and empirically that straw-like elements cannot be adequately modeled using simple uniaxial deformations. In addition, the experimental validation indicates that the suggested model can accurately capture their overall dynamics., Comment: 13 pages, 10 figures

Published
2022

14. Geometric analysis of gaits and optimal control for three-link kinematic swimmers

Author

Wiezel, Oren, Ramasamy, Suresh, Justus, Nathan, Or, Yizhar, and Hatton, Ross

Subjects
Computer Science - Robotics, Electrical Engineering and Systems Science - Systems and Control
Abstract

Many robotic systems locomote using gaits - periodic changes of internal shape, whose mechanical interaction with the robot's environment generate characteristic net displacements. Prominent examples with two shape variables are the low Reynolds number 3-link "Purcell swimmer" with inputs of 2 joint angles and the "ideal fluid" swimmer. Gait analysis of these systems allows for intelligent decisions to be made about the swimmer's locomotive properties, increasing the potential for robotic autonomy. In this work, we present comparative analysis of gait optimization using two different methods. The first method is variational approach of "Pontryagin's maximum principle" (PMP) from optimal control theory. We apply PMP for several variants of 3-link swimmers, with and without incorporation of bounds on joint angles. The second method is differential-geometric analysis of the gaits based on curvature (total Lie bracket) of the local connection for 3-link swimmers. Using optimized body-motion coordinates, contour plots of the curvature in shape space give visualization that enables identifying distance-optimal gaits as zero level sets. Combining and comparing results of the two methods enables better understanding of changes in existence, shape and topology of distance-optimal gait trajectories, depending on the swimmers' parameters., Comment: accepted to Automatica, 2023

Published
2021

15. Lamb-type solution and properties of unsteady Stokes equations

Author

Fouxon, Itzhak, Leshansky, Alexander, Rubinstein, Boris, and Or, Yizhar

Subjects
Physics - Fluid Dynamics
Abstract

We derive the general solution of the unsteady Stokes equations for an unbounded fluid in spherical polar coordinates, in both time and frequency domains. The solution is an expansion in vector spherical harmonics and given as a sum of a particular solution, proportional to pressure gradient exhibiting power-law spatial dependence, and a solution of vector Helmholtz equation decaying exponentially in far field, the decomposition originally introduced by Lamb. The solution can be applied to construct the transient exterior flow induced by an arbitrary velocity distribution at the spherical boundary, such as arising in the squirmer model of a microswimmer. It can be used to construct solutions for transient flows driven by initial conditions, unbounded flows driven by volume forces or disturbance to the unsteady flow due to a stationary spherical particle. The long-time behavior of solution is controlled by the flow component corresponding to average (or collective) motion of the boundary. This conclusion is illustrated by the study of decay of transversal wave in the presence of a fixed sphere. We further show that the general representation reduces to the well-known solutions for unsteady flow around a sphere undergoing oscillatory rigid-body (translation and rotation) motion. The proposed solution representation provides an explicit form of the velocity potential far from an oscillating body ("generalized" Darcy's law) and high- and low-frequency expansions. The leading-order high-frequency expansion yields the well-known ideal (inviscid) flow approximation, and the leading-order low-frequency expansion yields the steady Stokes equations. We derive the higher-order corrections to these approximations and discuss d'Alembert paradox. Continuation of the general solution to imaginary frequency yields the general solution of the Brinkman equations describing viscous flow in porous medium., Comment: 30 pages, revised version

Published
2021

16. Fluid-driven traveling waves in soft robots

Author

Salem, Lior, Gat, Amir D., and Or, Yizhar

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

Many marine creatures, gastropods, and earthworms generate continuous traveling waves in their bodies for locomotion within marine environments, complex surfaces, and inside narrow gaps. In this work, we study theoretically and experimentally the use of embedded pneumatic networks as a mechanism to mimic nature and generate bi-directional traveling waves in soft robots. We apply long-wave approximation to theoretically calculate the required distribution of pneumatic network and inlet pressure oscillations needed to create desired moving wave patterns. We then fabricate soft robots with internal pneumatic network geometry based on these analytical results. The experimental results agree well with our model and demonstrate the propagation of moving waves in soft robots, along with locomotion capabilities. The presented results allow fabricating soft robots capable of continuous moving waves via the common approach of embedded pneumatic networks and requiring only two input controls.

Published
2021

17. A non-canonical striatopallidal Go pathway that supports motor control

Author

Marie A. Labouesse, Arturo Torres-Herraez, Muhammad O. Chohan, Joseph M. Villarin, Julia Greenwald, Xiaoxiao Sun, Mysarah Zahran, Alice Tang, Sherry Lam, Jeremy Veenstra-VanderWeele, Clay O. Lacefield, Jordi Bonaventura, Michael Michaelides, C. Savio Chan, Ofer Yizhar, and Christoph Kellendonk

Subjects
Science
Abstract

Abstract In the classical model of the basal ganglia, direct pathway striatal projection neurons (dSPNs) send projections to the substantia nigra (SNr) and entopeduncular nucleus to regulate motor function. Recent studies have re-established that dSPNs also possess axon collaterals within the globus pallidus (GPe) (bridging collaterals), yet the significance of these collaterals for behavior is unknown. Here we use in vivo optical and chemogenetic tools combined with deep learning approaches in mice to dissect the roles of dSPN GPe collaterals in motor function. We find that dSPNs projecting to the SNr send synchronous motor-related information to the GPe via axon collaterals. Inhibition of native activity in dSPN GPe terminals impairs motor activity and function via regulation of Npas1 neurons. We propose a model by which dSPN GPe axon collaterals (striatopallidal Go pathway) act in concert with the canonical terminals in the SNr to support motor control by inhibiting Npas1 neurons.

Published
2023
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21. Neurophotonic tools for microscopic measurements and manipulation: status report

Author

Abdelfattah, Ahmed S, Ahuja, Sapna, Akkin, Taner, Allu, Srinivasa Rao, Brake, Joshua, Boas, David A, Buckley, Erin M, Campbell, Robert E, Chen, Anderson I, Cheng, Xiaojun, Čižmár, Tomáš, Costantini, Irene, De Vittorio, Massimo, Devor, Anna, Doran, Patrick R, Khatib, Mirna El, Emiliani, Valentina, Fomin-Thunemann, Natalie, Fainman, Yeshaiahu, Fernandez-Alfonso, Tomas, Ferri, Christopher GL, Gilad, Ariel, Han, Xue, Harris, Andrew, Hillman, Elizabeth MC, Hochgeschwender, Ute, Holt, Matthew G, Ji, Na, Kılıç, Kıvılcım, Lake, Evelyn MR, Li, Lei, Li, Tianqi, Mächler, Philipp, Miller, Evan W, Mesquita, Rickson C, Nadella, KM Naga Srinivas, Nägerl, U Valentin, Nasu, Yusuke, Nimmerjahn, Axel, Ondráčková, Petra, Pavone, Francesco S, Campos, Citlali Perez, Peterka, Darcy S, Pisano, Filippo, Pisanello, Ferruccio, Puppo, Francesca, Sabatini, Bernardo L, Sadegh, Sanaz, Sakadzic, Sava, Shoham, Shy, Shroff, Sanaya N, Silver, R Angus, Sims, Ruth R, Smith, Spencer L, Srinivasan, Vivek J, Thunemann, Martin, Tian, Lei, Tian, Lin, Troxler, Thomas, Valera, Antoine, Vaziri, Alipasha, Vinogradov, Sergei A, Vitale, Flavia, Wang, Lihong V, Uhlířová, Hana, Xu, Chris, Yang, Changhuei, Yang, Mu-Han, Yellen, Gary, Yizhar, Ofer, and Zhao, Yongxin

Subjects
Engineering, Biomedical and Clinical Sciences, Neurosciences, Biomedical Engineering, 1.1 Normal biological development and functioning, Underpinning research, Neurological, optical imaging, molecular sensors, optogenetics, fluorescence, label free, blood flow, multimodal, Medical Biotechnology, Biomedical engineering
Abstract

Neurophotonics was launched in 2014 coinciding with the launch of the BRAIN Initiative focused on development of technologies for advancement of neuroscience. For the last seven years, Neurophotonics' agenda has been well aligned with this focus on neurotechnologies featuring new optical methods and tools applicable to brain studies. While the BRAIN Initiative 2.0 is pivoting towards applications of these novel tools in the quest to understand the brain, this status report reviews an extensive and diverse toolkit of novel methods to explore brain function that have emerged from the BRAIN Initiative and related large-scale efforts for measurement and manipulation of brain structure and function. Here, we focus on neurophotonic tools mostly applicable to animal studies. A companion report, scheduled to appear later this year, will cover diffuse optical imaging methods applicable to noninvasive human studies. For each domain, we outline the current state-of-the-art of the respective technologies, identify the areas where innovation is needed, and provide an outlook for the future directions.

Published
2022

22. Viscous flow-fields in hyperelastic Chambers

Author

Ben-Haim, Eran, Ilssar, Dotan, Or, Yizhar, and Gat, Amir D.

Subjects
Physics - Fluid Dynamics
Abstract

Viscous flows in hyperelastic chambers are relevant to many biological phenomena such as inhalation into the lung's acinar region and medical applications such as the inflation of a small chamber in minimally invasive procedures. In this work, we analytically study the viscous flow and elastic deformation created due to inflation of such spherical chambers from one or two inlets. Our investigation considers the shell's constitutive hyperelastic law coupled with the flow dynamics inside the chamber. For the case of a narrow tube filling a larger chamber, the pressure within the chamber involves a large spatially uniform part, and a small order correction. We derive a closed-form expression for the inflation dynamics, accounting for the effect of elastic bi-stability. Interestingly, the obtained pressure distribution shows that the maximal pressure on the chamber's surface is greater than the pressure at the entrance to the chamber. The calculated series solution of the velocity and pressure fields during inflation is verified by using a fully coupled finite element scheme, resulting in excellent agreement. Our results allow estimating the chamber's viscous resistance at different pressures, thus enabling us to model the process of inflation and deflation., Comment: 30 pages, 11 figures

Published
2021

26. Absent from DNA and protein: genomic characterization of nullomers and nullpeptides across functional categories and evolution

Author

Georgakopoulos-Soares, Ilias, Yizhar-Barnea, Ofer, Mouratidis, Ioannis, Hemberg, Martin, and Ahituv, Nadav

Subjects
Biological Sciences, Bioinformatics and Computational Biology, Genetics, Human Genome, Biotechnology, Generic health relevance, Animals, Base Pairing, Base Sequence, DNA, Evolution, Molecular, Gene Frequency, Genetic Variation, Genome, Human, Humans, Peptides, Phylogeny, Proteins, Proteome, Species Specificity, Nullomers, Nullpeptides, Primes, Negative selection, Transposable elements, Human population, Phylogenetics, Environmental Sciences, Information and Computing Sciences, Bioinformatics
Abstract

Nullomers and nullpeptides are short DNA or amino acid sequences that are absent from a genome or proteome, respectively. One potential cause for their absence could be their having a detrimental impact on an organism. RESULTS: Here, we identify all possible nullomers and nullpeptides in the genomes and proteomes of thirty eukaryotes and demonstrate that a significant proportion of these sequences are under negative selection. We also identify nullomers that are unique to specific functional categories: coding sequences, exons, introns, 5'UTR, 3'UTR, promoters, and show that coding sequence and promoter nullomers are most likely to be selected against. By analyzing all protein sequences across the tree of life, we further identify 36,081 peptides up to six amino acids in length that do not exist in any known organism, termed primes. We next characterize all possible single base pair mutations that can lead to the appearance of a nullomer in the human genome, observing a significantly higher number of mutations than expected by chance for specific nullomer sequences in transposable elements, likely due to their suppression. We also annotate nullomers that appear due to naturally occurring variants and show that a subset of them can be used to distinguish between different human populations. Analysis of nullomers and nullpeptides across vertebrate evolution shows they can also be used as phylogenetic classifiers. CONCLUSIONS: We provide a catalog of nullomers and nullpeptides in distinct functional categories, develop methods to systematically study them, and highlight the use of variability in these sequences in other analyses.

Published
2021

27. Experimental Verification of Stability Theory for a Planar Rigid Body with Two Unilateral Frictional Contacts

Author

Or, Yizhar and Varkonyi, Peter L.

Subjects
Computer Science - Robotics, Physics - Applied Physics
Abstract

Stability of equilibrium states in mechanical systems with multiple unilateral frictional contacts is an important practical requirement, with high relevance for robotic applications. In our previous work, we theoretically analyzed finite-time Lyapunov stability for a minimal model of planar rigid body with two frictional point contacts. Assuming inelastic impacts and Coulomb friction, conditions for stability and instability of an equilibrium configuration have been derived. In this work, we present for the first time an experimental demonstration of this stability theory, using a variable-structure rigid ''biped'' with frictional footpads on an inclined plane. By changing the biped's center-of-mass location, we attain different equilibrium states, which respond to small perturbations by divergence or convergence, showing remarkable agreement with the predictions of the stability theory. Using high-speed recording of video movies, good quantitative agreement between experiments and numerical simulations is obtained, and limitations of the rigid-body model and inelastic impact assumptions are also studied. The results prove the utility and practical value of our stability theory., Comment: Accepted for publication by IEEE Transactions on Robotics

Published
2020

28. Dynamic Inchworm Crawling: Performance Analysis and Optimization of a Three-link Robot

Author

Gamus, Benny, Gat, Amir D., and Or, Yizhar

Subjects
Computer Science - Robotics
Abstract

Inchworm crawling allows for both quasistatic and dynamic gaits at a wide range of actuation frequencies. This locomotion mechanism is common in nonskeletal animals and exploited extensively in the bio-inspired field of soft robotics. In this work we develop and simulate the hybrid dynamic crawling of a three-link robot, with passive frictional contacts. We fabricate and experimentally test such robot under periodic inputs of joints' angles, with good agreement to the theoretical predictions. This allows to comprehend and exploit the effects of inertia in order to find optimal performance in inputs' parameters. A simple criterion of robustness to uncertainties in friction is proposed. Tuning the inputs according to this criterion improves the robustness of low-frequency actuation, while increasing the frequency allows for gaits with both high advancement velocity and robustness. Finally, the advantages of uneven mass distribution are studied. Time-scaling technique is introduced to shape inputs that achieve similar effect without reassembling the robot. A machine-learning based optimization is applied to these inputs to further improve the robot's performance in traveling distance.

Published
2020

29. A non-canonical striatopallidal Go pathway that supports motor control

Author

Labouesse, Marie A., Torres-Herraez, Arturo, Chohan, Muhammad O., Villarin, Joseph M., Greenwald, Julia, Sun, Xiaoxiao, Zahran, Mysarah, Tang, Alice, Lam, Sherry, Veenstra-VanderWeele, Jeremy, Lacefield, Clay O., Bonaventura, Jordi, Michaelides, Michael, Chan, C. Savio, Yizhar, Ofer, and Kellendonk, Christoph

Published
2023
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33. Understanding Legged Crawling for Soft-Robotics

Author

Gamus, Benny, Salem, Lior, Gat, Amir D., and Or, Yizhar

Subjects
Condensed Matter - Soft Condensed Matter, Computer Science - Robotics
Abstract

Crawling is a common locomotion mechanism in soft robots and nonskeletal animals. In this work we propose modeling soft-robotic legged locomotion by approximating it with an equivalent articulated robot with elastic joints. For concreteness we study our soft robot with two bending actuators via an articulated three-link model. The solution of statically indeterminate systems with stick-slip contact transitions requires for a novel hybrid-quasitatic analysis. Then, we utilize our analysis to investigate the influence of phase-shifted harmonic inputs on performance of crawling gaits, including sensitivity analysis to friction uncertainties and energetic cost of transport. We achieve optimal values of gait parameters. Finally, we fabricate and test a fluid-driven soft robot. The experiments display remarkable agreement with the theoretical analysis, proving that our simple model correctly captures and explains the fundamental principles of inchworm crawling and can be applied to other soft-robotic legged robots.

Published
2019
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34. Leveraging viscous peeling in soft actuators and reconfigurable microchannel networks

Author

Salem, Lior, Gamus, Benny, Or, Yizhar, and Gat, Amir D.

Subjects
Physics - Fluid Dynamics, Physics - Applied Physics
Abstract

The research fields of microfluidics and soft robotics both involve complex small-scale internal channel networks, embedded within a solid structure. This work examines leveraging viscous peeling as a mechanism to create and activate soft actuators and microchannel networks, including complex elements such as valves, without the need for fabrication of structures with micron-scale internal cavities. We consider configurations composed of an internal slender structure embedded within another elastic solid. Pressurized viscous fluid is introduced into the interface between the two solids, thus peeling the two elastic structures and creating internal cavities. Since the gap between the solids is determined by the externally applied pressure, the characteristic size of the fluidic network may vary in time and be much smaller than the resolution of the fabrication method. This work presents a model for the highly nonlinear elastic-viscous dynamics governing the flow and deformation of such configurations. Fabrication and experimental demonstrations of micron-scale valves and channel-networks created from millimeter scale structures are presented, as well as the transient dynamics of viscous peeling based soft actuators. The experimental data is compared with the suggested model, showing very good agreement., Comment: 8 pages, 6 figures

Published
2019

35. Single-Input Control of Multiple Fluid-Driven Elastic Actuators Via Interaction Between Bi-Stability and Viscosity

Author

Ben-Haim, Eran, Salem, Lior, Or, Yizhar, and Gat, Amir D.

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Fluid Dynamics
Abstract

A leading concept in soft robotics actuation, as well as in microfluidics applications such as valves in lab-on-a-chip devices, is applying pressurized flow in cavities embedded within elastic bodies. Generating complex deformation patterns typically requires control of several inputs, which greatly complicates the system's operation. In this work, we present a novel method for single-input control of a serial chain of bi-stable elastic chambers connected by thin tubes. Controlling a single flow rate at the chain's inlet, we induce an irreversible sequence of transitions that can reach any desired state combination of all bi-stable elements. Mathematical formulation and analysis of the system's dynamics reveal that these transitions are enabled thanks to bi-stability combined with pressure lag induced by viscous resistance. The results are demonstrated via numerical simulations combined with experiments for chains of up to 5 chambers, using water-diluted glycerol as the injected fluid. The proposed technique has a promising potential for development of sophisticated soft actuators with minimalistic control., Comment: Supplementary document will be added soon

Published
2019

36. Determinants of functional synaptic connectivity among amygdala-projecting prefrontal cortical neurons in male mice

Author

Yoav Printz, Pritish Patil, Mathias Mahn, Asaf Benjamin, Anna Litvin, Rivka Levy, Max Bringmann, and Ofer Yizhar

Subjects
Science
Abstract

Little is known about the synaptic organization of associative cortical structures such as the medial prefrontal cortex. Here, the authors use two-photon optogenetic stimulation to obtain a detailed cellular resolution map of functional synaptic connectivity of the mouse medial prefrontal cortex, finding unique spatial patterns of local-circuit connectivity in neurons that project to the basolateral amygdala.

Published
2023
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40. Dynamic Walking on Slippery Surfaces: Demonstrating Stable Bipedal Gaits with Planned Ground Slippage

Author

Ma, Wen-Loong, Or, Yizhar, and Ames, Aaron D.

Subjects
Computer Science - Robotics
Abstract

Dynamic bipedal robot locomotion has achieved remarkable success due in part to recent advances in trajectory generation and nonlinear control for stabilization. A key assumption utilized in both theory and experiments is that the robot's stance foot always makes no-slip contact with the ground, including at impacts. This assumption breaks down on slippery low-friction surfaces, as commonly encountered in outdoor terrains, leading to failure and loss of stability. In this work, we extend the theoretical analysis and trajectory optimization to account for stick-slip transitions at point foot contact using Coulomb's friction law. Using AMBER-3M planar biped robot as an experimental platform, we demonstrate for the first time a slippery walking gait which can be stabilized successfully both on a lubricated surface and on a rough no-slip surface. We also study the influence of foot slippage on reducing the mechanical cost of transport, and compare energy efficiency in both numerical simulations and experimental measurements., Comment: 7 pages, 8 figures, submitted to 2019 International Conference on Robotics and Automation (ICRA)

Published
2018

41. Energy-optimal strokes for multi-link microswimmers: Purcell's loops and Taylor's waves reconciled

Author

Alouges, François, DeSimone, Antonio, Giraldi, Laetitia, Or, Yizhar, and Wiezel, Oren

Subjects
Physics - Fluid Dynamics, Condensed Matter - Soft Condensed Matter, Physics - Biological Physics
Abstract

Micron-scale swimmers move in the realm of negligible inertia, dominated by viscous drag forces. In this paper, we formulate the leading-order dynamics of a slender multi-link (N-link) microswimmer assuming small-amplitude undulations about its straight configuration. The energy-optimal stroke to achieve a given prescribed displacement in a given time period is obtained as the largest eigenvalue solution of a constrained optimal control problem. Remarkably, the optimal stroke is an ellipse lying within a two-dimensional plane in the (N-1)-dimensional space of joint angles, where N can be arbitrarily large. For large N, the optimal stroke is a traveling wave of bending, modulo edge effects. If the number of shape variables is small, we can consider the same problem when the prescribed displacement in one time period is large, and not attainable with small variations of the joint angles. The fully nonlinear optimal control problem is solved numerically for the cases N=3 (Purcell's three-link swimmer) and N=5 showing that, as the prescribed displacement becomes small, the optimal solutions obtained using the small-amplitude assumption are recovered. We also show that, when the prescribed displacements become large, the picture is different. For N=3 we recover the non-convex planar loops already known from previous studies. For N=5 we obtain non-planar loops, raising the question of characterizing the geometry of complex high-dimensional loops.

Published
2018
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43. Rhodopsin-bestrophin fusion proteins from unicellular algae form gigantic pentameric ion channels

Author

Rozenberg, Andrey, Kaczmarczyk, Igor, Matzov, Donna, Vierock, Johannes, Nagata, Takashi, Sugiura, Masahiro, Katayama, Kota, Kawasaki, Yuma, Konno, Masae, Nagasaka, Yujiro, Aoyama, Mako, Das, Ishita, Pahima, Efrat, Church, Jonathan, Adam, Suliman, Borin, Veniamin A., Chazan, Ariel, Augustin, Sandra, Wietek, Jonas, Dine, Julien, Peleg, Yoav, Kawanabe, Akira, Fujiwara, Yuichiro, Yizhar, Ofer, Sheves, Mordechai, Schapiro, Igor, Furutani, Yuji, Kandori, Hideki, Inoue, Keiichi, Hegemann, Peter, Béjà, Oded, and Shalev-Benami, Moran

Published
2022
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45. Rapid but specific perceptual learning partially explains individual differences in the recognition of challenging speech

Author

Karen Banai, Hanin Karawani, Limor Lavie, and Yizhar Lavner

Subjects
Medicine, Science
Abstract

Abstract Perceptual learning for speech, defined as long-lasting changes in speech recognition following exposure or practice occurs under many challenging listening conditions. However, this learning is also highly specific to the conditions in which it occurred, such that its function in adult speech recognition is not clear. We used a time-compressed speech task to assess learning following either brief exposure (rapid learning) or additional training (training-induced learning). Both types of learning were robust and long-lasting. Individual differences in rapid learning explained unique variance in recognizing natural-fast speech and speech-in-noise with no additional contribution for training-induced learning (Experiment 1). Rapid learning was stimulus specific (Experiment 2), as in previous studies on training-induced learning. We suggest that rapid learning is key for understanding the role of perceptual learning in online speech recognition whereas longer training could provide additional opportunities to consolidate and stabilize learning.

Published
2022
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46. Inertial self-propulsion of spherical microswimmers by rotation-translation coupling

Author

Fouxon, Itzhak and Or, Yizhar

Subjects
Physics - Fluid Dynamics
Abstract

We study swimming of small spherical particles who regulate fluid flow on their surface by applying tangential squirming strokes. We derive translational and rotational velocities for any given stroke which is not restricted by axial symmetry as assumed usually. The formulation includes inertia of both the fluid and the swimmer, motivated by inertia's relevance for large Volvox colonies. We show that inertial contribution to mean speed comes from dynamic coupling between translation and rotation, which occurs only for strokes that break axial symmetry. Remarkably, this effect enables overcoming the scallop theorem on impossibility of propulsion by time-reversible stroke. We study examples of tangential strokes of axisymmetric travelling wave, and of asymmetric time-reversible flapping. In the latter case, we find that inertia-driven mean speed is optimized for flapping frequency and swimmer's size which fall well within the range of realistic physical values for Volvox colonies. We conjecture that similarly to Paramecium, large Volvox could use time-reversible strokes for inertia-driven swimming coupled with their rotations., Comment: Final version. Accepted to Physical Review Fluids on January 2018

Published
2017
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47. Planar Multi-link Swimmers: Experiments and Theoretical Investigation Using 'Perfect Fluid' Model

Author

Virozub, Evgenia, Wiezel, Oren, Wolf, Alon, and Or, Yizhar

Subjects
Physics - Fluid Dynamics
Abstract

Robotic swimmers are currently a subject of extensive research and development for several underwater applications. Clever design and planning must rely on simple theoretical models that account for the swimmer's hydrodynamics in order to optimize its structure and control inputs. In this work, we study a planar snake-like multi-link swimmer by using the `perfect fluid' model that accounts for inertial hydrodynamic forces while neglecting viscous drag effects. The swimmer's dynamic equations of motion are formulated and reduced into a first-order system due to symmetries and conservation of generalized momentum variables. Focusing on oscillatory inputs of joint angles, we study optimal gaits for 3-link and 5-link swimmers via numerical integration. For the 3-link swimmer, we also provide a small-amplitude asymptotic solution which enables obtaining closed-form approximations for optimal gaits. The theoretical results are then corroborated by experiments and motion measurement of untethered robotic prototypes with 3 and 5 links floating in a water pool, showing a reasonable agreement between experiments and the theoretical model.

Published
2017

48. Nonlinear parametric excitation effect induces stability transitions in swimming direction of flexible superparamagnetic microswimmers

Author

Harduf, Yuval, Jin, Dongdong, Or, Yizhar, and Zhang, Li

Subjects
Physics - Fluid Dynamics, Mathematics - Dynamical Systems
Abstract

Microscopic artificial swimmers have recently become highly attractive due to their promising potential for biomedical applications. The pioneering work of Dreyfus et al (2005) has demonstrated the motion of a microswimmer with an undulating chain of superparamagnetic beads, which is actuated by an oscillating external magnetic field. Interestingly, it has also been theoretically predicted that the swimming direction of this swimmer will undergo a $90^\circ$-transition when the magnetic field's oscillations amplitude is increased above a critical value of $\sqrt{2}$. In this work, we further investigate this transition both theoretically and experimentally by using numerical simulations and presenting a novel flexible microswimmer with a superparamagnetic head. We realize the $90^\circ$-transition in swimming direction, prove that this effect depends on both frequency and amplitude of the oscillating magnetic field, and demonstrate the existence of an optimal amplitude, under which, maximal swimming speed can be achieved. By asymptotically analyzing the dynamic motion of microswimmer with a minimal two-link model, we reveal that the stability transitions representing the changes in the swimming direction are induced by the effect of nonlinear parametric excitation., Comment: 14 pages main paper, followed by 31 pages of supplementary document. Supplementary videos are not included

Published
2017

50. Loss of action-related function and connectivity in the blind extrastriate body area

Author

Or Yizhar, Zohar Tal, and Amir Amedi

Subjects
congenital blindness, neuroimaging, body representation, resting-state fMRI, visuomotor interactions, extrastriate body area, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

The Extrastriate Body Area (EBA) participates in the visual perception and motor actions of body parts. We recently showed that EBA’s perceptual function develops independently of visual experience, responding to stimuli with body-part information in a supramodal fashion. However, it is still unclear if the EBA similarly maintains its action-related function. Here, we used fMRI to study motor-evoked responses and connectivity patterns in the congenitally blind brain. We found that, unlike the case of perception, EBA does not develop an action-related response without visual experience. In addition, we show that congenital blindness alters EBA’s connectivity profile in a counterintuitive way—functional connectivity with sensorimotor cortices dramatically decreases, whereas connectivity with perception-related visual occipital cortices remains high. To the best of our knowledge, we show for the first time that action-related functions and connectivity in the visual cortex could be contingent on visuomotor experience. We further discuss the role of the EBA within the context of visuomotor control and predictive coding theory.

Published
2023
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