Sequential Bayesian Experimental Design for Implicit Models via Mutual Information

Kleinegesse, Steven; Drovandi, Christopher; Gutmann, Michael U.

doi:10.1214/20-ba1225

Cited by 51 publications

(103 citation statements)

References 67 publications

(168 reference statements)

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“…These results show how SNPE allows fast and accurate identification of biophysical model parameters on new data, and how SNPE can be deployed for applications requiring rapid automated inference, such as high-throughput screening-assays, closed-loop paradigms (e.g. for adaptive experimental manipulations or stimulus-selection [ Kleinegesse and Gutmann, 2019 ]), or interactive software tools.…”

Section: Resultsmentioning

confidence: 99%

Training deep neural density estimators to identify mechanistic models of neural dynamics

Gonçalves

Lueckmann

Deistler

et al. 2020

eLife

144

220

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Mechanistic modeling in neuroscience aims to explain observed phenomena in terms of underlying causes. However, determining which model parameters agree with complex and stochastic neural data presents a significant challenge. We address this challenge with a machine learning tool which uses deep neural density estimators- trained using model simulations- to carry out Bayesian inference and retrieve the full space of parameters compatible with raw data or selected data features. Our method is scalable in parameters and data features, and can rapidly analyze new data after initial training. We demonstrate the power and flexibility of our approach on receptive fields, ion channels, and Hodgkin-Huxley models. We also characterize the space of circuit configurations giving rise to rhythmic activity in the crustacean stomatogastric ganglion, and use these results to derive hypotheses for underlying compensation mechanisms. Our approach will help close the gap between data-driven and theory-driven models of neural dynamics.

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Section: Resultsmentioning

confidence: 99%

Training deep neural density estimators to identify mechanistic models of neural dynamics

Gonçalves

Lueckmann

Deistler

et al. 2020

eLife

144

220

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show abstract

“…Figure 4 shows that the best combinations that maximise a balanced criterion, such as I(K 1 ; Z) + I(K 2 ; Z) − I(K 1 ; K 2 |Z), are a trade-off between the combinations of angles that maximise I(K 1 ; Z) and I(K 2 ; Z) individually. For example, when five angles are considered, the angles that maximise I(K 1 ; Z) are φ a = [66, 72, 78, 84, 90] and those that maximise I(K 2 ; Z) are φ b = [30,36,42,48,54], while the combination that maximises I(K 1 ; Z) + I(K 2 ; Z) − I(K 1 ; K 2 |Z) is [30,36,48,78,90], which has two angles from φ a and three angles from φ b . It should be noted that such a trade-off between maximising individual parameter gains is still significantly different to a uniform discretisation; 5.…”

Section: Resultsmentioning

confidence: 99%

“…Thus, a large area of future work is related to the development of efficient and robust MI and CMI estimators. Note that several approaches are being proposed by researchers to solve this problem; see for example [40][41][42][43][44][45][46]. Lastly, a thorough comparison against classical optimal design methods…”

Section: Limitations and Future Workmentioning

confidence: 99%

An Information-Theoretic Framework for Optimal Design: Analysis of Protocols for Estimating Soft Tissue Parameters in Biaxial Experiments

Aggarwal

Lombardi

Pant

2021

Axioms

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A new framework for optimal design based on the information-theoretic measures of mutual information, conditional mutual information and their combination is proposed. The framework is tested on the analysis of protocols—a combination of angles along which strain measurements can be acquired—in a biaxial experiment of soft tissues for the estimation of hyperelastic constitutive model parameters. The proposed framework considers the information gain about the parameters from the experiment as the key criterion to be maximised, which can be directly used for optimal design. Information gain is computed through k-nearest neighbour algorithms applied to the joint samples of the parameters and measurements produced by the forward and observation models. For biaxial experiments, the results show that low angles have a relatively low information content compared to high angles. The results also show that a smaller number of angles with suitably chosen combinations can result in higher information gains when compared to a larger number of angles which are poorly combined. Finally, it is shown that the proposed framework is consistent with classical approaches, particularly D-optimal design.

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“…Our work is limited to studying the effect of a fixed set of stirring actions that were selected after careful analysis in simulation. We believe an interesting avenue for future work lies in studying how such actions can be generated automatically using information-based metrics [36], [37], such as maximizing the information gain after each stir. Another interesting direction is to relax the current assumption of knowledge about the shapes and containers and including uncertainty in the estimation of the stick configuration.…”

Section: Discussionmentioning

confidence: 99%

Stir to Pour: Efficient Calibration of Liquid Properties for Pouring Actions

Tatiana

Pucci

Taylor

et al. 2020

2020 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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Humans use simple probing actions to develop intuition about the physical behavior of common objects. Such intuition is particularly useful for adaptive estimation of favorable manipulation strategies of those objects in novel contexts. For example, observing the effect of tilt on a transparent bottle containing an unknown liquid provides clues on how the liquid might be poured. It is desirable to equip general-purpose robotic systems with this capability because it is inevitable that they will encounter novel objects and scenarios. In this paper, we teach a robot to use a simple, specified probing strategystirring with a stick-to reduce spillage when pouring unknown liquids. In the probing step, we continuously observe the effects of a real robot stirring a liquid, while simultaneously tuning the parameters to a model (simulator) until the two outputs are in agreement. We obtain optimal simulation parameters, characterizing the unknown liquid, via a Bayesian Optimizer that minimizes the discrepancy between real and simulated outcomes. Then, we optimize the pouring policy conditioning on the optimal simulation parameters determined via stirring. We show that using stirring as a probing strategy result in reduced spillage for three qualitatively different liquids when executed on a UR10 Robot, compared to probing via pouring. Finally, we provide quantitative insights into the reason for stirring being a suitable calibration task for pouring -a step towards automatic discovery of probing strategies.

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Sequential Bayesian Experimental Design for Implicit Models via Mutual Information

Cited by 51 publications

References 67 publications

Training deep neural density estimators to identify mechanistic models of neural dynamics

Training deep neural density estimators to identify mechanistic models of neural dynamics

An Information-Theoretic Framework for Optimal Design: Analysis of Protocols for Estimating Soft Tissue Parameters in Biaxial Experiments

Stir to Pour: Efficient Calibration of Liquid Properties for Pouring Actions

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