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- Title
Understanding the Information Content in the Hierarchy of Model Development Decisions: Learning From Data.
- Authors
Gharari, Shervan; Gupta, Hoshin V.; Clark, Martyn P.; Hrachowitz, Markus; Fenicia, Fabrizio; Matgen, Patrick; Savenije, Hubert H. G.
- Abstract
Process‐based hydrological models seek to represent the dominant hydrological processes in a catchment. However, due to unavoidable incompleteness of knowledge, the construction of "fidelius" process‐based models depends largely on expert judgment. We present a systematic approach that treats models as hierarchical assemblages of hypotheses (conservation principles, system architecture, process parameterization equations, and parameter specification), which enables investigating how the hierarchy of model development decisions impacts model fidelity. Each model development step provides information that progressively changes our uncertainty (increases, decreases, or alters) regarding the input‐state‐output behavior of the system. Following the principle of maximum entropy, we introduce the concept of "minimally restrictive process parameterization equations—MR‐PPEs," which enables us to enhance the flexibility with which system processes can be represented, and to thereby investigate the important role that the system architectural hypothesis (discretization of the system into subsystem elements) plays in determining model behavior. We illustrate and explore these concepts with synthetic and real‐data studies, using models constructed from simple generic buckets as building blocks, thereby paving the way for more‐detailed investigations using sophisticated process‐based hydrological models. We also discuss how proposed MR‐PPEs can bridge the gap between current process‐based modeling and machine learning. Finally, we suggest the need for model calibration to evolve from a search over "parameter spaces" to a search over "function spaces." Plain Language Summary: Modelers make many decisions in their quest to formulate a working model. It is important to evaluate the impact of each modeling decision, and to assess the extent to which different decisions improve the representation of the actual system. Building upon past work, we present a framework that enables an improved assessment of individual modeling decisions. Specifically, we suggest that modelers should pay more attention to the hierarchical structure of model building decisions, and to the impact that each such decision can have on the fidelity of resulting process representation. Key Points: We present a strategy for characterizing and quantifying the information added at each model building stepModel building steps are interdependent in a hierarchical mannerWe call for the focus of model calibration to shift from "parameter spaces" to "function spaces"
- Subjects
MAXIMUM entropy method; FUNCTION spaces; MAXIMUM principles (Mathematics); SPACE; MACHINE learning
- Publication
Water Resources Research, 2021, Vol 57, Issue 6, p1
- ISSN
0043-1397
- Publication type
Article
- DOI
10.1029/2020WR027948