QUIC-URB and QUIC-fire extension to complex terrain: Development of a terrain-following coordinate system. (January 2023)
- Record Type:
- Journal Article
- Title:
- QUIC-URB and QUIC-fire extension to complex terrain: Development of a terrain-following coordinate system. (January 2023)
- Main Title:
- QUIC-URB and QUIC-fire extension to complex terrain: Development of a terrain-following coordinate system
- Authors:
- Robinson, David
Brambilla, Sara
Brown, Michael J.
Conry, Patrick
Quaife, Bryan
Linn, Rod R. - Abstract:
- Abstract: Ensemble-based approaches to prescribed fire planning cannot be supported by CFD-based models like FIRETEC and WFDS because they are too computationally expensive and cannot leverage LES approaches like CAWFE and WRF-SFIRE because too coarse of resolution. QUIC-Fire was developed to fill this gap but it cannot currently address complex terrain, typical for instance of the Western United States. In this paper, we describe the extension of the diagnostic wind model QUIC-URB, the wind engine of QUIC-Fire, to a terrain-following coordinate system. In particular, the paper presents the mathematical derivation of the wind solver leading to a linear system of equations that are solved through the successive over-relaxation method. The model is validated against a standard test used in previous works (the Askervein Hill) and against a new dataset from measurements in the Socorro Mountains, New Mexico. The terrain-following implementation captured the correct phenomenology for the isolated Askervein Hill, with a wind speed up at the top of the hill. The model agreed well with measurements on the upwind side of the peak, but overestimated speed-up on the downwind side of the hill. This is due to the inability of the model to generate flow separation and wake-eddy dynamics. On a common laptop, the divergence-free wind field was obtained in 6 s, making the solver appealing for coupled fire–atmosphere simulations. The Socorro Mountain was highly complex, with many cliff faces,Abstract: Ensemble-based approaches to prescribed fire planning cannot be supported by CFD-based models like FIRETEC and WFDS because they are too computationally expensive and cannot leverage LES approaches like CAWFE and WRF-SFIRE because too coarse of resolution. QUIC-Fire was developed to fill this gap but it cannot currently address complex terrain, typical for instance of the Western United States. In this paper, we describe the extension of the diagnostic wind model QUIC-URB, the wind engine of QUIC-Fire, to a terrain-following coordinate system. In particular, the paper presents the mathematical derivation of the wind solver leading to a linear system of equations that are solved through the successive over-relaxation method. The model is validated against a standard test used in previous works (the Askervein Hill) and against a new dataset from measurements in the Socorro Mountains, New Mexico. The terrain-following implementation captured the correct phenomenology for the isolated Askervein Hill, with a wind speed up at the top of the hill. The model agreed well with measurements on the upwind side of the peak, but overestimated speed-up on the downwind side of the hill. This is due to the inability of the model to generate flow separation and wake-eddy dynamics. On a common laptop, the divergence-free wind field was obtained in 6 s, making the solver appealing for coupled fire–atmosphere simulations. The Socorro Mountain was highly complex, with many cliff faces, peaks, and valleys. Although the model captures the magnitude and direction of inlet and outlet areas of the domain, it performs rather poorly in the valley region and in the regions near the steep cliffs. Hence, the model shows good agreement with data in areas of open sloped terrain but lacks in areas where flow separation and thermally driven effects may be present (neither effect was addressed in this work). Results highlight that future work should focus on the implementation of parameterizations of wake-eddies, similar to QUIC-URB's building parameterizations, and on thermodynamic-driven flow. Highlights: Outline of transformation of wind solver to terrain-following coordinates producing to produce terrain-influenced winds. Fast solver shows strong agreement with Askervein Hill wind measurement data. … (more)
- Is Part Of:
- Environmental modelling & software. Volume 159(2023)
- Journal:
- Environmental modelling & software
- Issue:
- Volume 159(2023)
- Issue Display:
- Volume 159, Issue 2023 (2023)
- Year:
- 2023
- Volume:
- 159
- Issue:
- 2023
- Issue Sort Value:
- 2023-0159-2023-0000
- Page Start:
- Page End:
- Publication Date:
- 2023-01
- Subjects:
- Complex terrain flow -- Terrain-following wind solver -- Diagnostic wind model -- Prescribed fire winds scales -- Fast-running wind solver
Environmental monitoring -- Computer programs -- Periodicals
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Environnement -- Surveillance -- Logiciels -- Périodiques
Écologie -- Simulation, Méthodes de -- Périodiques
Simulation par ordinateur -- Périodiques
Logiciels -- Périodiques
Computer software
Digital computer simulation
Ecology -- Computer simulation
Environmental monitoring -- Computer programs
Periodicals
Electronic journals
363.70015118 - Journal URLs:
- http://www.sciencedirect.com/science/journal/13648152 ↗
http://www.elsevier.com/journals ↗ - DOI:
- 10.1016/j.envsoft.2022.105579 ↗
- Languages:
- English
- ISSNs:
- 1364-8152
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- Legaldeposit
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