Deep computational neurophenomenology: a methodological framework for investigating the how of experience.
Lars Sandved-smith, Juan Diego Bogotá, Jakob Hohwy, Julian Kiverstein, Antoine Lutz
Neuroscience of consciousness January 1, 2025 Peer reviewed DOI: 10.1093/nc/niaf016 via PubMed
Summary
The paper discusses how Bayesian mechanics, particularly deep parametric active inference, can create beneficial connections between subjective experiences and their physiological counterparts in neuroscience. It emphasizes the importance of integrating first-person insights from participants to enhance scientific understanding of consciousness. By shifting focus from what is experienced to how experiences occur, the authors propose a 'meta-Bayesian' framework that bridges phenomenological and physiological aspects, underscoring the role of trained reflective awareness in neurophenomenological studies.
Study at a glance
| Key finding | The integration of first-person insights into scientific protocols enhances understanding of consciousness by linking phenomenological descriptions with physiological instantiations. |
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Abstract
The context for our paper comes from the neurophenomenology (NPh) research programme initiated by Francisco Varela at the end of the 1990s. Varela's working hypothesis was that, to be successful, a consciousness research programme must progress by relating first-person phenomenological accounts of the structure of experience and their third-person counterparts in neuroscience through "mutual constraints". Leveraging Bayesian mechanics, in particular deep parametric active inference, we demonstrate the potential for epistemically advantageous mutual constraints between phenomenological, computational, behavioural, and physiological vocabularies. Specifically, the dual information geometry of Bayesian mechanics serves to establish, under certain conditions, generative passage between lived experience and its physiological instantiation. This paper argues for the epistemological necessity of such a passage and the inclusion of trained reflective awareness in neurophenomenological empirical approaches. In particular, it showcases incremental explanatory gains for the scientist that arise from incorporating the participants' epistemic insights, shifting the focus from the contents of experience (i.e. what a subject experiences in a given experimental set-up) to the how of experience (i.e. the activities of consciousness that allow for a meaningful world to appear to us as such in lived experience). The explanatory power of the resulting 'meta-Bayesian' framework, deep computational NPh, arises from the disciplined circulation between first and third-person perspectives enabled by the formalism of deep parametric active inference, where parametric depth refers to a property of generative models that can form beliefs about the parameters of their own modelling process. Hence, this computational formalism contributes to understanding consciousness by bridging phenomenological descriptions and physiological instantiations, whilst also highlighting the significance of trained first-person investigation in experimental protocols.