Hydroinformatics techniques in eco-environmental modelling and management
Authored by Qiuwen Chen, Hong Li, Yenory Morales-Chaves, Arthur E Mynett
Date Published: 2006
DOI: 10.2166/hydro.2006.011
Sponsors:
Honour Power Foundation (HPF)
Platforms:
Weka
Model Documentation:
Other Narrative
Flow charts
Mathematical description
Model Code URLs:
Model code not found
Abstract
The high complexity of aquatic ecosystems and the multiple processes
involved, make the development of ecohydraulics and eco-environmental
models a challenging subject. Conventionally, computer-based models use
a mathematical formulation for the processes involved which are then
solved by numerical methods. These models are often derived based on the
assumption of spatial homogeneity and conservation principles of mass, momentum and energy. Development of these models often demands a clear
understanding of the processes involved. However, the above assumptions
are easily violated when spatial heterogeneity, individual species
behaviour and local interactions play a significant role in the system
dynamics. In particular for eco-environmental systems, knowledge on
local interactions that determine the overall system behaviour is not
always available. Although the rapid advances of data-driven techniques
have recently made great contributions to water-environment related
research, data on ecosystems are often quite limited, which restricts
the application of data mining methods to eco-environmental system
modelling. In addition, no modelling - also not black-box modelling -
can be undertaken without having at least some understanding of the
basic processes and mechanisms involved. It is always advisable to start
exploring any dataset using conventional statistical techniques, as
elaborated in this paper for a case study on Western Xiamen Bay, China.
Neural network trimming was then used to establish the dominant factors;
it was shown that a relatively simple ANN model was quite capable of
capturing the essential features, provided the right input parameters
are chosen. Examples of integrated approaches to ecohydraulics modelling
coupling formulations with cellular automata and physical equations with
fuzzy rules are presented for applications on eutrophication modelling
of Taihu Lake in China, competitive growths and colonization of two
underwater macrophytes in Lake Veluwe in The Netherlands, and
forecasting of algal blooms in the Dutch coastal waters on the North
Sea. A mussel dynamics model developed for the Upper Mississippi River
in the USA demonstrates the feasibility of individual based modelling in
ecosystem dynamics. Numerical models are quite capable of simulating the
abiotic aquatic environment, including complicated fluid flow and
transport mechanisms. However, when it comes to simulating the biotic
and ecosystem dynamics, the interaction of individual species with their
environment, as well as the interactions amongst species, has to be
taken into account. The future of ecohydraulics and eco-environmental
modelling thus seems to lie in the integration of different paradigms
and techniques, which is the core content of the hydroinformatics
discipline.
Tags
population
Quality
Cellular-automata
Rivers
Spatial-distribution
Fresh-water mussels
Blue-green-algae
Mississippi
Bivalves
Fauna