Jacob A Zavatone-Veth, Paul Masset, William L Tong, Joseph D Zak, Venkatesh N Murthy, Cengiz Pehlevan
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However, these models have not captured the unique anatomy and physiology of the olfactory bulb, nor have they shown that sensing can be achieved within the 100-millisecond timescale of a single sniff. Here, we propose a rate-based Poisson compressed sensing circuit model for the olfactory bulb. This model maps onto the neuron classes of the olfactory bulb, and recapitulates salient features of their connectivity and physiology. For circuit sizes comparable to the human olfactory bulb, we show that this model can accurately detect tens of odors within the timescale of a single sniff. We also show that this model can perform Bayesian posterior sampling for accurate uncertainty estimation. Fast inference is possible only if the geometry of the neural code is chosen to match receptor properties, yielding a distributed neural code that is not axis-aligned to individual odor identities. 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Neural Circuits for Fast Poisson Compressed Sensing in the Olfactory Bulb.
Within a single sniff, the mammalian olfactory system can decode the identity and concentration of odorants wafted on turbulent plumes of air. Yet, it must do so given access only to the noisy, dimensionally-reduced representation of the odor world provided by olfactory receptor neurons. As a result, the olfactory system must solve a compressed sensing problem, relying on the fact that only a handful of the millions of possible odorants are present in a given scene. Inspired by this principle, past works have proposed normative compressed sensing models for olfactory decoding. However, these models have not captured the unique anatomy and physiology of the olfactory bulb, nor have they shown that sensing can be achieved within the 100-millisecond timescale of a single sniff. Here, we propose a rate-based Poisson compressed sensing circuit model for the olfactory bulb. This model maps onto the neuron classes of the olfactory bulb, and recapitulates salient features of their connectivity and physiology. For circuit sizes comparable to the human olfactory bulb, we show that this model can accurately detect tens of odors within the timescale of a single sniff. We also show that this model can perform Bayesian posterior sampling for accurate uncertainty estimation. Fast inference is possible only if the geometry of the neural code is chosen to match receptor properties, yielding a distributed neural code that is not axis-aligned to individual odor identities. Our results illustrate how normative modeling can help us map function onto specific neural circuits to generate new hypotheses.
期刊介绍:
Rationale The importance to study and understand Islam and contemporary Muslim life from a socio-scientific perspective seems more relevant than ever. Currently, there is no specific journal that offers a platform for discussion on contemporary aspects of Islam and Muslims. Indeed, the historical, political and comparative approach to Islam has been preferred over social scientific research and themes. Contemporary Islam: Dynamics of Muslim Life aims to fill this gap by providing an active forum for the discussion of new ideas, fieldwork experiences, challenging views, and methodological and theoretical approaches to Muslim life. The journal is not a forum for normative reflections in Islamic theology or jurisprudence but approaches Islam as a lived tradition in today’s global societies. Topical and interdisciplinary Contemporary Islam: Dynamics of Muslim Life focuses on topical issues and takes an interdisciplinary approach that benefits from a cross-cultural perspective: articles will explore the relationship between Islam and its contemporary cultural, material, gender, economic, political, and religious expressions from different socio-scientific perspectives, such as anthropology, sociology, education, politics, international relations, ethnomusicology, arts, film studies, economics, human rights, international law, diaspora minority studies, demography, and ethics. Focus The journal provides insights into the contemporary dynamics of Muslim life by focusing on questions concerning ordinary aspects of everyday life of Muslims as well as more systemic concerns. The journal focuses on what Muslims actually do rather than what one reading or another of the texts suggest that they should do and therefore seeks papers on the lived experiences of Muslims in both Muslim minority and Muslim majority contexts. Contemporary Islam: Dynamics of Muslim Life regards Islam as a modern religion in today’s global societies. The journal is committed to publishing scholarship grounded in empirical research and comparison of relevance to the understanding of broader intellectual, social, legal, and political developments in contemporary Muslim societies.Articles making more general theoretical or comparative contributions are preferred over those narrowly focused on a single society. Papers based on single country or case must also speak to issues relevant to the study of Islam and Muslim culture/society beyond the country in question. To this end, reviewers are selected in such a way to help authors address audiences outside their niche within Islamic studies. Readership and Editorial Board As the first socio-scientific journal to focus on Muslim life, Contemporary Islam: Dynamics of Muslim Life will be of interest to scholars and students in various academic fields related to Islam and Muslim live across multiple cultures. The editorial board reflects the multidisciplinary and multi-national approach of the journal.Please read our Editorial Policies carefully before you submit your paper to this journal https://www.springer.com/gp/editorial-policies
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