By the same authors

Synthetizing hydrodynamic turbulence from noise: formalism and applications to plankton dynamics

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Standard

Synthetizing hydrodynamic turbulence from noise : formalism and applications to plankton dynamics. / Sagues, F ; Reigada, R ; Sancho, J M ; Hillary, R M ; Bees, M A .

UNSOLVED PROBLEMS OF NOISE AND FLUCTUATIONS. ed. / SM Bezrukov. MELVILLE : AMER INST PHYSICS, 2003. p. 531-538.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Harvard

Sagues, F, Reigada, R, Sancho, JM, Hillary, RM & Bees, MA 2003, Synthetizing hydrodynamic turbulence from noise: formalism and applications to plankton dynamics. in SM Bezrukov (ed.), UNSOLVED PROBLEMS OF NOISE AND FLUCTUATIONS. AMER INST PHYSICS, MELVILLE, pp. 531-538, 3rd International Conference on Unsolved Problems of Noise and Fluctuations in Physics, Biology and High Technology, BETHESDA, 3/09/02.

APA

Sagues, F., Reigada, R., Sancho, J. M., Hillary, R. M., & Bees, M. A. (2003). Synthetizing hydrodynamic turbulence from noise: formalism and applications to plankton dynamics. In SM. Bezrukov (Ed.), UNSOLVED PROBLEMS OF NOISE AND FLUCTUATIONS (pp. 531-538). AMER INST PHYSICS.

Vancouver

Sagues F, Reigada R, Sancho JM, Hillary RM, Bees MA. Synthetizing hydrodynamic turbulence from noise: formalism and applications to plankton dynamics. In Bezrukov SM, editor, UNSOLVED PROBLEMS OF NOISE AND FLUCTUATIONS. MELVILLE: AMER INST PHYSICS. 2003. p. 531-538

Author

Sagues, F ; Reigada, R ; Sancho, J M ; Hillary, R M ; Bees, M A . / Synthetizing hydrodynamic turbulence from noise : formalism and applications to plankton dynamics. UNSOLVED PROBLEMS OF NOISE AND FLUCTUATIONS. editor / SM Bezrukov. MELVILLE : AMER INST PHYSICS, 2003. pp. 531-538

Bibtex - Download

@inproceedings{4325caaf8237494798830fe433ba28bb,
title = "Synthetizing hydrodynamic turbulence from noise: formalism and applications to plankton dynamics",
abstract = "We present an analytical scheme, easily implemented numerically, to generate synthetic Gaussian 2D turbulent flows by using linear stochastic partial differential equations, where the noise term acts as a random force of well-prescribed statistics. This methodology leads to a divergence-free, isotropic, stationary and homogeneous velocity field, whose characteristic parameters are well reproduced, in particular the kinematic viscosity and energy spectrum. This practical approach to tailor a turbulent flow is justified by its versatility when analizing different physical processes occurring in advectely mixed systems. Here, we focuss on an application to study the dynamics of Planktonic populations in the ocean.",
author = "F Sagues and R Reigada and Sancho, {J M} and Hillary, {R M} and Bees, {M A}",
year = "2003",
language = "English",
isbn = "0-7354-0127-6",
pages = "531--538",
editor = "SM Bezrukov",
booktitle = "UNSOLVED PROBLEMS OF NOISE AND FLUCTUATIONS",
publisher = "AMER INST PHYSICS",
note = "3rd International Conference on Unsolved Problems of Noise and Fluctuations in Physics, Biology and High Technology ; Conference date: 03-09-2002 Through 06-09-2002",

}

RIS (suitable for import to EndNote) - Download

TY - GEN

T1 - Synthetizing hydrodynamic turbulence from noise

T2 - 3rd International Conference on Unsolved Problems of Noise and Fluctuations in Physics, Biology and High Technology

AU - Sagues, F

AU - Reigada, R

AU - Sancho, J M

AU - Hillary, R M

AU - Bees, M A

PY - 2003

Y1 - 2003

N2 - We present an analytical scheme, easily implemented numerically, to generate synthetic Gaussian 2D turbulent flows by using linear stochastic partial differential equations, where the noise term acts as a random force of well-prescribed statistics. This methodology leads to a divergence-free, isotropic, stationary and homogeneous velocity field, whose characteristic parameters are well reproduced, in particular the kinematic viscosity and energy spectrum. This practical approach to tailor a turbulent flow is justified by its versatility when analizing different physical processes occurring in advectely mixed systems. Here, we focuss on an application to study the dynamics of Planktonic populations in the ocean.

AB - We present an analytical scheme, easily implemented numerically, to generate synthetic Gaussian 2D turbulent flows by using linear stochastic partial differential equations, where the noise term acts as a random force of well-prescribed statistics. This methodology leads to a divergence-free, isotropic, stationary and homogeneous velocity field, whose characteristic parameters are well reproduced, in particular the kinematic viscosity and energy spectrum. This practical approach to tailor a turbulent flow is justified by its versatility when analizing different physical processes occurring in advectely mixed systems. Here, we focuss on an application to study the dynamics of Planktonic populations in the ocean.

M3 - Conference contribution

SN - 0-7354-0127-6

SP - 531

EP - 538

BT - UNSOLVED PROBLEMS OF NOISE AND FLUCTUATIONS

A2 - Bezrukov, SM

PB - AMER INST PHYSICS

CY - MELVILLE

Y2 - 3 September 2002 through 6 September 2002

ER -