Abstract
Multiple datasets of two consecutive vintages of replicated grape and wines from six different deficit irrigation regimes are characterized and compared. The process consists of four temporal-ordered signature phases: harvest field data, juice composition, wine composition before bottling and bottled wine. A new computing paradigm and an integrative inferential platform are developed for discovering phase-to-phase pattern geometries for such characterization and comparison purposes. Each phase is manifested by a distinct set of features, which are measurable upon phase-specific entities subject to the common set of irrigation regimes. Throughout the four phases, this compilation of data from irrigation regimes with subsamples is termed a space of media-nodes, on which measurements of phase-specific features were recoded. All of these collectively constitute a bipartite network of data, which is then normalized and binary coded. For these serial bipartite networks, we first quantify patterns that characterize individual phases by means of a new computing paradigm called “Data Mechanics”. This computational technique extracts a coupling geometry which captures and reveals interacting dependence among and between media-nodes and feature-nodes in forms of hierarchical block sub-matrices. As one of the principal discoveries, the holistic year-factor persistently surfaces as the most inferential factor in classifying all media-nodes throughout all phases. This could be deemed either surprising in its over-arching dominance or obvious based on popular belief. We formulate and test pattern-based hypotheses that confirm such fundamental patterns. We also attempt to elucidate the driving force underlying the phase-evolution in winemaking via a newly developed partial coupling geometry, which is designed to integrate two coupling geometries. Such partial coupling geometries are confirmed to bear causal and predictive implications. All pattern inferences are performed with respect to a profile of energy distributions sampled from network bootstrapping ensembles conforming to block-structures specified by corresponding hypotheses.
Highlights
Winemaking can be traced back many thousands of years of human history as a complex process that is intricately intertwined with agriculture and civilizations around the world [1, 2]
Based on the series of coupling geometries, we first discover two somehow surprising factors that persistently appear on all four computed coupling geometries throughout all phases: one is on the axis of water regimes, the other one is on the axis of biochemical features
One might intuitively assume that such block patterns in Juice are causal patterns for patterns observed in corresponding coupling geometries of the two wine phases
Summary
Winemaking can be traced back many thousands of years of human history as a complex process that is intricately intertwined with agriculture and civilizations around the world [1, 2]. The number of mythologies and pseudo-scientific discoveries are manifold and supplemented by a multitude of reports and analyses of specific wines. Remarkably few systemic and interdisciplinary studies are directed towards the elucidation of definitive global findings. As winemaking continuously evolves alongside human culture, it is perpetually desirable to add new insights based on state-of-the-art technologies. Data-computing and -mining are signature techniques in our current era of Information Technology. In this interdisciplinary study, we attempt to elucidate new perspectives into the winemaking based on new integrative pattern computations and inferences
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