Search

Your search keyword '"Rodriguez, Ivan D."' showing total 90 results
Start Over Author "Rodriguez, Ivan D."

Refine your results

more »

more »

more »

more »
90 results on '"Rodriguez, Ivan D."'

1. Self-Supervised Online Learning for Safety-Critical Control using Stereo Vision

Author

Cosner, Ryan K., Rodriguez, Ivan D. Jimenez, Molnar, Tamas G., Ubellacker, Wyatt, Yue, Yisong, Ames, Aaron D., and Bouman, Katherine L.

Subjects
Computer Science - Robotics
Abstract

With the increasing prevalence of complex vision-based sensing methods for use in obstacle identification and state estimation, characterizing environment-dependent measurement errors has become a difficult and essential part of modern robotics. This paper presents a self-supervised learning approach to safety-critical control. In particular, the uncertainty associated with stereo vision is estimated, and adapted online to new visual environments, wherein this estimate is leveraged in a safety-critical controller in a robust fashion. To this end, we propose an algorithm that exploits the structure of stereo-vision to learn an uncertainty estimate without the need for ground-truth data. We then robustify existing Control Barrier Function-based controllers to provide safety in the presence of this uncertainty estimate. We demonstrate the efficacy of our method on a quadrupedal robot in a variety of environments. When not using our method safety is violated. With offline training alone we observe the robot is safe, but overly-conservative. With our online method the quadruped remains safe and conservatism is reduced., Comment: 7 pages, 4 figures, conference publication at ICRA 2022

Published
2022

2. Learning First-Order Representations for Planning from Black-Box States: New Results

Author

Rodriguez, Ivan D., Bonet, Blai, Romero, Javier, and Geffner, Hector

Subjects
Computer Science - Artificial Intelligence
Abstract

Recently Bonet and Geffner have shown that first-order representations for planning domains can be learned from the structure of the state space without any prior knowledge about the action schemas or domain predicates. For this, the learning problem is formulated as the search for a simplest first-order domain description D that along with information about instances I_i (number of objects and initial state) determine state space graphs G(P_i) that match the observed state graphs G_i where P_i = (D, I_i). The search is cast and solved approximately by means of a SAT solver that is called over a large family of propositional theories that differ just in the parameters encoding the possible number of action schemas and domain predicates, their arities, and the number of objects. In this work, we push the limits of these learners by moving to an answer set programming (ASP) encoding using the CLINGO system. The new encodings are more transparent and concise, extending the range of possible models while facilitating their exploration. We show that the domains introduced by Bonet and Geffner can be solved more efficiently in the new approach, often optimally, and furthermore, that the approach can be easily extended to handle partial information about the state graphs as well as noise that prevents some states from being distinguished.

Published
2021

3. Flexible FOND Planning with Explicit Fairness Assumptions

Author

Rodriguez, Ivan D., Bonet, Blai, Sardina, Sebastian, and Geffner, Hector

Subjects
Computer Science - Artificial Intelligence
Abstract

We consider the problem of reaching a propositional goal condition in fully-observable non-deterministic (FOND) planning under a general class of fairness assumptions that are given explicitly. The fairness assumptions are of the form A/B and say that state trajectories that contain infinite occurrences of an action a from A in a state s and finite occurrence of actions from B, must also contain infinite occurrences of action a in s followed by each one of its possible outcomes. The infinite trajectories that violate this condition are deemed as unfair, and the solutions are policies for which all the fair trajectories reach a goal state. We show that strong and strong-cyclic FOND planning, as well as QNP planning, a planning model introduced recently for generalized planning, are all special cases of FOND planning with fairness assumptions of this form which can also be combined. FOND+ planning, as this form of planning is called, combines the syntax of FOND planning with some of the versatility of LTL for expressing fairness constraints. A new planner is implemented by reducing FOND+ planning to answer set programs, and the performance of the planner is evaluated in comparison with FOND and QNP planners, and LTL synthesis tools., Comment: Extended version of ICAPS-21 paper

Published
2021
Full Text
View/download PDF

4. Learning to Control an Unstable System with One Minute of Data: Leveraging Gaussian Process Differentiation in Predictive Control

Author

Rodriguez, Ivan D. Jimenez, Rosolia, Ugo, Ames, Aaron D., and Yue, Yisong

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

We present a straightforward and efficient way to control unstable robotic systems using an estimated dynamics model. Specifically, we show how to exploit the differentiability of Gaussian Processes to create a state-dependent linearized approximation of the true continuous dynamics that can be integrated with model predictive control. Our approach is compatible with most Gaussian process approaches for system identification, and can learn an accurate model using modest amounts of training data. We validate our approach by learning the dynamics of an unstable system such as a segway with a 7-D state space and 2-D input space (using only one minute of data), and we show that the resulting controller is robust to unmodelled dynamics and disturbances, while state-of-the-art control methods based on nominal models can fail under small perturbations. Code is open sourced at https://github.com/learning-and-control/core .

Published
2021

5. Neural-Network Quantum States, String-Bond States, and Chiral Topological States

Author

Glasser, Ivan, Pancotti, Nicola, August, Moritz, Rodriguez, Ivan D., and Cirac, J. Ignacio

Subjects
Quantum Physics, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Strongly Correlated Electrons, Statistics - Machine Learning
Abstract

Neural-Network Quantum States have been recently introduced as an Ansatz for describing the wave function of quantum many-body systems. We show that there are strong connections between Neural-Network Quantum States in the form of Restricted Boltzmann Machines and some classes of Tensor-Network states in arbitrary dimensions. In particular we demonstrate that short-range Restricted Boltzmann Machines are Entangled Plaquette States, while fully connected Restricted Boltzmann Machines are String-Bond States with a nonlocal geometry and low bond dimension. These results shed light on the underlying architecture of Restricted Boltzmann Machines and their efficiency at representing many-body quantum states. String-Bond States also provide a generic way of enhancing the power of Neural-Network Quantum States and a natural generalization to systems with larger local Hilbert space. We compare the advantages and drawbacks of these different classes of states and present a method to combine them together. This allows us to benefit from both the entanglement structure of Tensor Networks and the efficiency of Neural-Network Quantum States into a single Ansatz capable of targeting the wave function of strongly correlated systems. While it remains a challenge to describe states with chiral topological order using traditional Tensor Networks, we show that Neural-Network Quantum States and their String-Bond States extension can describe a lattice Fractional Quantum Hall state exactly. In addition, we provide numerical evidence that Neural-Network Quantum States can approximate a chiral spin liquid with better accuracy than Entangled Plaquette States and local String-Bond States. Our results demonstrate the efficiency of neural networks to describe complex quantum wave functions and pave the way towards the use of String-Bond States as a tool in more traditional machine-learning applications., Comment: 15 pages, 7 figures

Published
2017
Full Text
View/download PDF

10. Introduction to Control

Author

Díaz-Rodríguez, Iván D., Han, Sangjin, Bhattacharyya, Shankar P., Díaz-Rodríguez, Iván D., Han, Sangjin, and Bhattacharyya, Shankar P.

Published
2019
Full Text
View/download PDF

16. Quasielectrons as inverse quasiholes in lattice fractional quantum Hall models

Author

Nielsen, Anne E. B., Glasser, Ivan, and Rodriguez, Ivan D.

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

From an experimental point of view, quasielectrons and quasiholes play very similar roles in the fractional quantum Hall effect. Nevertheless, the theoretical description of quasielectrons is known to be much harder than the one of quasiholes. The problem is that one obtains a singularity in the wavefunction if one tries to naively construct the quasielectron as the inverse of the quasihole. Here, we demonstrate that the same problem does not arise in lattice fractional quantum Hall models. This result allows us to make detailed investigations of the properties of quasielectrons, including their braiding statistics and density distribution on lattices on the plane and on the torus. We show that some of the states considered have high overlap with certain fractional Chern insulator states. We also derive few-body Hamiltonians, for which various states containing quasielectrons are exact ground states., Comment: 13 pages, 4 figures, v3: accepted version

Published
2016
Full Text
View/download PDF

17. Composite fermion model for entanglement spectrum of fractional quantum Hall states

Author

Davenport, Simon C., Rodríguez, Iván D., Slingerland, J. K., and Simon, Steven H.

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We show that the entanglement spectrum associated with a certain class of strongly correlated many-body states --- the wave functions proposed by Laughlin and Jain to describe the fractional quantum Hall effect --- can be very well described in terms of a simple model of non-interacting (or weakly interacting) composite fermions., Comment: 6 pages, 2 figures

Published
2015
Full Text
View/download PDF

18. Continuum limit of lattice models with Laughlin-like ground states containing quasiholes

Author

Rodriguez, Ivan D. and Nielsen, Anne E. B.

Subjects
Condensed Matter - Strongly Correlated Electrons, Quantum Physics
Abstract

There has been a significant interest in the last years in finding fractional quantum Hall physics in lattice models, but it is not always clear how these models connect to the corresponding models in continuum systems. Here we introduce a family of models that is able to interpolate between a recently proposed set of lattice models with Laughlin-like ground states constructed from conformal field theory and models with ground states that are practically the usual bosonic/fermionic Laughlin states in the continuum. Both the ground state and the Hamiltonian are known analytically, and we find that the Hamiltonian in the continuum limit does not coincide with the usual delta interaction Hamiltonian for the Laughlin states. We introduce quasiholes into the models and show analytically that their braiding properties are as expected if the quasiholes are screened. We demonstrate screening numerically for the 1/3 Laughlin model and find that the quasiholes are slightly smaller in the continuum than in the lattice. Finally, we compute the effective magnetic field felt by the quasiholes and show that it is close to uniform when approaching the continuum limit. The techniques presented here to interpolate between the lattice and the continuum can also be applied to other fractional quantum Hall states that are constructed from conformal field theory., Comment: 8 pages, 7 figures; v2: minor changes and accepted for publication in Phys. Rev. B

Published
2015
Full Text
View/download PDF

19. Entanglement Spectrum of Composite Fermion States in Real Space

Author

Rodriguez, Ivan D., Davenport, Simon C., Simon, Steven H., and Slingerland, J. K.

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

We study the entanglement spectra of many particle systems in states which are closely related to products of Slater determinants or products of permanents, or combinations of the two. Such states notably include the Laughlin and Jain composite fermion states which describe most of the observed conductance plateaus of the fractional quantum Hall effect. We identify a set of 'Entanglement Wave Functions' (EWF), for subsets of the particles, which completely describe the entanglement spectra of such product wave functions, both in real space and in particle space. A subset of the EWF for the Laughlin and Jain states can be recognized as Composite Fermion states. These states provide an exact description of the low angular momentum sectors of the real space entanglement spectrum (RSES) of these trial wave functions and a physical explanation of the branches of excitations observed in the RSES of the Jain states., Comment: 5 pages, 2 figures, 3 tables

Published
2013
Full Text
View/download PDF

20. Evaluation of ranks of real space and particle entanglement spectra for large systems

Author

Rodriguez, Ivan D., Simon, Steven H., and Slingerland, J. K.

Subjects
Condensed Matter - Strongly Correlated Electrons, Quantum Physics
Abstract

We devise a way to calculate the dimensions of symmetry sectors appearing in the Particle Entanglement Spectrum (PES) and Real Space Entanglement Spectrum (RSES) of multi-particle systems from their real space wave functions. We first note that these ranks in the entanglement spectra equal the dimensions of spaces of wave functions with a number of particles fixed. This also yields equality of the multiplicities in the PES and the RSES. Our technique allows numerical calculations for much larger systems than were previously feasible. For somewhat smaller systems, we can find approximate entanglement energies as well as multiplicities. We illustrate the method with results on the RSES and PES multiplicities for integer quantum Hall states, Laughlin and Jain composite fermion states and for the Moore-Read state at filling $\nu=5/2$, for system sizes up to 70 particles., Comment: 5 pages, 2 figures; minor changes; New version includes the Real Space ES of Jain states; accepted for publication in Phys.Rev.Lett

Published
2011
Full Text
View/download PDF

21. Entanglement entropy of integer Quantum Hall states in polygonal domains

Author

Rodriguez, Ivan D. and Sierra, German

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

The entanglement entropy of the integer Quantum Hall states satisfies the area law for smooth domains with a vanishing topological term. In this paper we consider polygonal domains for which the area law acquires a constant term that only depends on the angles of the vertices and we give a general expression for it. We study also the dependence of the entanglement spectrum on the geometry and give it a simple physical interpretation., Comment: 8 pages, 6 figures

Published
2010
Full Text
View/download PDF

22. Matrix Effective Theories of the Fractional Quantum Hall effect

Author

Cappelli, Andrea and Rodriguez, Ivan D.

Subjects
High Energy Physics - Theory, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The present understanding of nonperturbative ground states in the fractional quantum Hall effect is based on effective theories of the Jain "composite fermion" excitations. We review the approach based on matrix variables, i.e. D0 branes, originally introduced by Susskind and Polychronakos. We show that the Maxwell-Chern-Simons matrix gauge theory provides a matrix generalization of the quantum Hall effect, where the composite-fermion construction naturally follows from gauge invariance. The matrix ground states obtained by suitable projections of higher Landau levels are found to be in one-to-one correspondence with the Laughlin and Jain hierarchical states. The matrix theory possesses a physical limit for commuting matrices that could be reachable while staying in the same phase., Comment: 30 pages, 6 figures, to appear in the Al. Zamolodchikov memorial volume

Published
2009
Full Text
View/download PDF

23. Edge excitations of the Chern Simons matrix theory for the FQHE

Author

Rodriguez, Ivan D.

Subjects
High Energy Physics - Theory
Abstract

We study the edge excitations of the Chern Simons matrix theory, describing the Laughlin fluids for filling fraction $\nu=\frac{1}{k}$, with $k$ an integer. Based on the semiclassical solutions of the theory, we are able to identify the bulk and edge degrees of freedom. In this way we can freeze the bulk of the theory, to the semiclassical values, obtaining an effective theory governing the boundary excitations of the Chern Simons matrix theory. Finally, we show that this effective theory is equal to the chiral boson theory on the circle., Comment: 22 pages. Section 3.2. improved. 2 Appendices added. Accepted for publication in JHEP

Published
2008
Full Text
View/download PDF

24. Entanglement entropy of integer Quantum Hall states

Author

Rodriguez, Ivan D. and Sierra, German

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We compute the entanglement entropy, in real space, of the ground state of the integer Quantum Hall states for three different domains embedded in the torus, the disk and the sphere. We establish the validity of the area law with a vanishing value of the topological entanglement entropy. The entropy per unit length of the perimeter depends on the filling fraction, but it is independent of the geometry., Comment: 5 pages, 2 figures, minor changes, one reference added

Published
2008
Full Text
View/download PDF

25. Semiclassical Droplet States in Matrix Quantum Hall Effect

Author

Cappelli, Andrea and Rodriguez, Ivan D.

Subjects
High Energy Physics - Theory, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We derive semiclassical ground state solutions that correspond to the quantum Hall states earlier found in the Maxwell-Chern-Simons matrix theory. They realize the Jain composite-fermion construction and their density is piecewise constant as that of phenomenological wave functions. These results support the matrix theory as a possible effective theory of the fractional Hall effect. A crucial role is played by the constraint limiting the degeneracy of matrix states: we find its explicit gauge invariant form and clarify its physical interpretation., Comment: 39 pages, 12 figures

Published
2007
Full Text
View/download PDF

26. Jain States in a Matrix Theory of the Quantum Hall Effect

Author

Cappelli, Andrea and Rodriguez, Ivan D.

Subjects
High Energy Physics - Theory, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The U(N) Maxwell-Chern-Simons matrix gauge theory is proposed as an extension of Susskind's noncommutative approach. The theory describes D0-branes, nonrelativistic particles with matrix coordinates and gauge symmetry, that realize a matrix generalization of the quantum Hall effect. Matrix ground states obtained by suitable projections of higher Landau levels are found to be in one-to-one correspondence with the expected Laughlin and Jain hierarchical states. The Jain composite-fermion construction follows by gauge invariance via the Gauss law constraint. In the limit of commuting, ``normal'' matrices the theory reduces to eigenvalue coordinates that describe realistic electrons with Calogero interaction. The Maxwell-Chern-Simons matrix theory improves earlier noncommutative approaches and could provide another effective theory of the fractional Hall effect., Comment: 35 pages, 3 figures

Published
2006
Full Text
View/download PDF

29. FOND Planning with Explicit Fairness Assumptions

Author

Rodriguez, Ivan D., Bonet, Blai, Sardina, Sebastian, Geffner, Hector, Rodriguez, Ivan D., Bonet, Blai, Sardina, Sebastian, and Geffner, Hector

Abstract

We consider the problem of reaching a propositional goal condition in fully-observable non deterministic (FOND) planning under a general class of fairness assumptions that are given explicitly. The fairness assumptions are of the form A/B and say that state trajectories that contain infinite occurrences of an action a from A in a state s and finite occurrence of actions from B, must also contain infinite occurrences of action a in s followed by each one of its possible outcomes. The infinite trajectories that violate this condition are deemed as unfair, and the solutions are policies for which all the fair trajectories reach a goal state. We show that strong and strong-cyclic FOND planning, as well as QNP planning, a planning model introduced recently for generalized planning, are all special cases of FOND planning with fairness assumptions of this form which can also be combined. FOND+ planning, as this form of planning is called, combines the syntax of FOND planning with some of the versatility of LTL for expressing fairness constraints. A sound and complete FOND+ planner is implemented by reducing FOND+ planning to answer set programs, and its performance is evaluated in comparison with FOND and QNP planners, and LTL synthesis tools. Two other FOND+ planners are introduced as well which are more scalable but are not complete., Funding Agencies|ERC Advanced Grant [885107]; EU [952215]; Knut and Alice Wallenberg (KAW) Foundation under the WASP program

Published
2022
Full Text
View/download PDF

36. Learning Unstable Dynamics with One Minute of Data: A Differentiation-based Gaussian Process Approach

Author

Jimenez Rodriguez, Ivan D., Rosolia, Ugo, Ames, Aaron D., Yue, Yisong, Jimenez Rodriguez, Ivan D., Rosolia, Ugo, Ames, Aaron D., and Yue, Yisong

Abstract

We present a straightforward and efficient way to estimate dynamics models for unstable robotic systems. Specifically, we show how to exploit the differentiability of Gaussian processes to create a state-dependent linearized approximation of the true continuous dynamics. Our approach is compatible with most Gaussian process approaches for system identification, and can learn an accurate model using modest amounts of training data. We validate our approach by iteratively learning the system dynamics of an unstable system such as a 9-D segway (using only one minute of data) and we show that the resulting controller is robust to unmodelled dynamics and disturbances, while state-of-the-art control methods based on nominal models can fail under small perturbations.

Published
2021

37. Learning to Control an Unstable System with One Minute of Data: Leveraging Gaussian Process Differentiation in Predictive Control

Author

Jimenez Rodriguez, Ivan D., Rosolia, Ugo, Ames, Aaron D., Yue, Yisong, Jimenez Rodriguez, Ivan D., Rosolia, Ugo, Ames, Aaron D., and Yue, Yisong

Abstract

We present a straightforward and efficient way to control unstable robotic systems using an estimated dynamics model. Specifically, we show how to exploit the differentiability of Gaussian Processes to create a state-dependent linearized approximation of the true continuous dynamics that can be integrated with model predictive control. Our approach is compatible with most Gaussian process approaches for system identification, and can learn an accurate model using modest amounts of training data. We validate our approach by learning the dynamics of an unstable system such as a segway with a 7-D state space and 2-D input space (using only one minute of data), and we show that the resulting controller is robust to unmodelled dynamics and disturbances, while state-of-the-art control methods based on nominal models can fail under small perturbations. Code is open sourced at https://github.com/learning-and-control/core.

Published
2021

45. Evaluation of ranks of real space and particle entanglement spectra for large systems

Author

Rodriguez, Ivan D., Simon, Steven H., Slingerland, Joost, Rodriguez, Ivan D., Simon, Steven H., and Slingerland, Joost

Abstract

We devise a way to calculate the dimensions of symmetry sectors appearing in the Particle Entan- glement Spectrum (PES) and Real Space Entanglement Spectrum (RSES) of multi-particle systems from their real space wave functions. We first note that these ranks in the entanglement spectra equal the dimensions of spaces of wave functions with a number of particles fixed. This also yields equality of the multiplicities in the PES and the RSES. Our technique allows numerical calculations for much larger systems than were previously feasible. For somewhat smaller systems, we can find approximate entanglement energies as well as multiplicities. We illustrate the method with results on the RSES and PES multiplicities for integer quantum Hall states, Laughlin and Jain composite fermion states and for the Moore-Read state at filling v = 5 2 , for system sizes up to 70 particles.

Published
2012

46. Quasiparticles and excitons for the Pfaffian quantum Hall state

Author

Rodriguez, Ivan D., Sterdyniak, A., Hermanns, M., Slingerland, Joost, Rodriguez, Ivan D., Sterdyniak, A., Hermanns, M., and Slingerland, Joost

Abstract

We propose trial wave functions for quasiparticle and exciton excitations of the Moore-Read Pfaffian fractional quantum Hall states, both for bosons and for fermions, and study these numerically. Our construction of trial wave functions employs a picture of the bosonic Moore-Read state as a symmetrized double layer composite fermion state. We obtain the number of independent angular momentum multiplets of quasiparticle and exciton trial states for systems of up to 20 electrons. We find that the counting for quasielectrons at large angular momentum on the sphere matches that expected from the CFT which describes the Moore-Read state's boundary theory. In particular, the counting for quasielectrons is the same as for quasiholes, in accordance with the idea that the CFT describing both sides of the FQH plateau should be the same. We also show that our trial wave functions have good overlaps with exact wave functions obtained using various interactions, including second Landau level Coulomb interactions and the 3-body delta interaction for which the Pfaffian states and their quasiholes are exact ground states. We discuss how these results relate to recent work by Sreejith et al. on a similar set of trial wave functions for excitations over the Pfaffian state as well as to earlier work by Hansson et al., which has produced trial wave functions for quasiparticles based on conformal field theory methods and by Bernevig and Haldane, which produced trial wave functions based on clustering properties and 'squeezing'.

Published
2012

47. Edge excitations of the Chern Simons matrix theory for the FQHE

Author

Rodriguez, Ivan D. and Rodriguez, Ivan D.

Abstract

We study the edge excitations of the Chern Simons matrix theory, describing the Laughlin fluids for filling fraction n = 1k, with k an integer. Based on the semiclassical solutions of the theory, we are able to identify the bulk and edge degrees of freedom. In this way we can freeze the bulk of the theory, to the semiclassical values, obtaining an effective theory governing the boundary excitations of the Chern Simons matrix theory. Finally, we show that this effective theory is equal to the chiral boson theory on the circle.

Published
2009

48. Entanglement entropy of integer Quantum Hall states

Author

Rodriguez, Ivan D., Sierra, German, Rodriguez, Ivan D., and Sierra, German

Abstract

We compute the entanglement entropy, in the real space, of the ground state of the integer Quantum Hall states for three different domains embedded in the cylinder, the disk and the sphere. We establish the validity of the area law with a vanishing value of the topological entanglement entropy. The entropy per unit length of the perimeter depends on the filling fraction, but it is independent of the geometry.

Published
2009

Catalog

Books, media, physical & digital resources
See catalog results