O’BRIEN, Alexander Michael (2025). Advanced Real-Time Control and Optimisation of Mixed-Culture Beer Fermentation. Doctoral, Sheffield Hallam University. [Thesis]
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O'Brien_2026_PhD_AdvancedReal-TimeControl.pdf - Accepted Version
Restricted to Repository staff only until 9 July 2027.
Available under License Creative Commons Attribution Non-commercial No Derivatives.
O'Brien_2026_PhD_AdvancedReal-TimeControl.pdf - Accepted Version
Restricted to Repository staff only until 9 July 2027.
Available under License Creative Commons Attribution Non-commercial No Derivatives.
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Abstract
Following the first isolation of an individual yeast strain in 1883, monoculture
fermentation emerged as the primary method for fermenting nearly all beer produced
today. However, evolving consumer preferences have spurred the craft beer
movement, resulting in a considerable increase in beer diversity. Unfortunately,
traditional process control methods used to ferment consistent monoculture beers
are inadequate to address the complexities of producing craft and mixed-culture
fermented beers.
This thesis addresses this challenge by first replicating well-established
mechanistic models for monoculture beer fermentation in order to establish a
baseline for acceptable performance. Building upon this foundation, a data-driven
understanding of both monoculture and mixed-culture beer fermentation processes
is subsequently developed. Finally, an LSTM-based plant model is utilised
within a model predictive control (MPC) framework for fermentation temperature
scheduling.
The work in this thesis draws significantly upon data. Therefore, significant
efforts have been made to produce a dataset comprising monoculture and
mixed-culture beer fermentation processes in pilot and small-scale fermentors.
Furthermore, a monoculture fermentation dataset provided by Sennos, composed
of real-world commercial-scale monitoring within craft breweries, has been used to
support this research.
Visualisation leveraging data processing methods has been used to develop
an understanding of real-world beer fermentation processes. The replication and
parameter tuning of a first-principles mechanistic model provides a standard against
which to assess the novel approaches proposed in this thesis. Advanced empirical
models trained using the datasets have demonstrated robust performance across a
vast fermentation configuration space and accurate forecasting capabilities.
Overall, this thesis provides robust models for monoculture beer fermentation
process prediction and inferential measurement with a particular focus on serving
the needs of the craft beer sector. Furthermore, the development of a mixed-culture
beer fermentation dataset and associated predictive modelling efforts provides a
proof of concept for further study.
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