Multicriteria Optimization Model to Generate on‐DEM Optimal Channel Networks

The theory of optimal channel networks (OCNs) explains the existence of self‐similarities in river networks by multiple optimality principles, namely, (i) the minimum energy expenditure in any link, (ii) the equal energy expenditure per unit area of channel anywhere, and (iii) the minimum total ener...

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Vydáno v:Water resources research Ročník 54; číslo 8; s. 5727 - 5740
Hlavní autoři: Bizzi, Simone, Cominola, Andrea, Mason, Emanuele, Castelletti, Andrea, Paik, Kyungrock
Médium: Journal Article
Jazyk:angličtina
Vydáno: Washington John Wiley & Sons, Inc 01.08.2018
Wiley
Témata:
algorithms
Area
basins
Basis functions
Computer simulation
Concavity
digital elevation model
Digital Elevation Models
Dimensions
Elevation
Energy
Energy expenditure
Equalization
Evolution
Evolutionary algorithms
Exploration
Formulations
Frameworks
Landscape
landscape evolution
Mathematical analysis
Modelling
Multiple criterion
Multiple objective analysis
Networks
optimal channel network
optimization
Optimization models
Organizations
Outlets
profile concavity
Profiles
Radial basis function
River channels
River networks
Rivers
Scaling
Scaling laws
self‐similarity
Software development tools
Theories
Three dimensional models
variance
water
Water flow
ISSN:0043-1397, 1944-7973
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Shrnutí:The theory of optimal channel networks (OCNs) explains the existence of self‐similarities in river networks by multiple optimality principles, namely, (i) the minimum energy expenditure in any link, (ii) the equal energy expenditure per unit area of channel anywhere, and (iii) the minimum total energy expenditure (TEE). These principles have been used to generate OCNs from 2‐D networks. The existing notion of OCN considers the concavity of river longitudinal profiles as a priori condition. Attempts to generate OCNs starting from a random 3‐D digital elevation model (DEM) and minimizing solely TEE have failed to reproduce concave profiles. Yet alternative approaches can be devised from the three optimality principles, for instance, focusing on the local energy expenditure (LEE). In this paper, we propose a Multiobjective modeling framework for Riverscape Exploration (MoRE) via simultaneous optimization of multiple OCN criteria. MoRE adopts a multiobjective evolutionary algorithm and radial basis functions to efficiently guide DEM elevation variations required to shape 3‐D OCNs. By minimizing both TEE and the variance in LEE, MoRE successfully reproduces realistic on‐DEM, OCN‐based riverscapes, for the first time. Simulated networks possess scaling laws of upstream area and length and river longitudinal profile resembling those of real river networks. The profile concavity of generated on‐DEM OCNs emerges as a consequence of the minimization of TEE constrained to the equalization of LEE. Minimizing TEE under this condition generates networks that possess specific patterns of LEE, where the scaling of slope with basin area resembles the patterns observed in real river networks. Plain Language Summary In nature, river networks self‐organize their branches so that the energy spent by the water flow to reach the outlet is kept to a minimum. This physical process can be expressed mathematically with diverse formulations, which inspired a theory called Optimal Channel Network. Several studies applied Optimal Channel Network theory to reproduce two‐dimensional features of channel networks, that is, how river branches develop and organize within the network. Yet these studies were not able to reproduce realistic river networks in three dimensions, for instance, starting from a random digital elevation model. In this paper, we propose the first modeling framework able to generate artificial river networks from random digital elevation model that resemble those observed in nature for their 3‐D characteristics, in terms of 2‐D organization of the river network branches, as well as longitudinal profile of the river elevations. This work contributes to enrich our understanding about the mechanisms guiding the development and evolution of river networks in nature and provides a software tool that can be used for future research on real‐world 3‐D river landscapes. Key Points On‐DEM optimal channel networks are generated via a multiobjective framework adopting multiple optimality principles The generated on‐DEM optimal channel networks possess the topological features and concavity of real river networks Trade‐offs exist between topographic and topological efficiencies along the search for OCNs
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ISSN:0043-1397
1944-7973
DOI:10.1029/2018WR022977