ГОСТ Р 57700.6-2017 Численное моделирование физических процессов. Термины и определения в области бессеточных методов численного моделирования

Bio-Savart law

3.2.1

Boltzmann equation

3.3.1

bounce-back

3.3.12

calculated particles

3.4.8

circulation

3.2.4

collision integral

3.3.9

collision operator

3.3.9

collision process

3.3.8

computational domain

3.3.5

core size

3.2.9

core spreading method

3.2.20

Courant-Friedrichs-Lewy condition

3.1.5

cutoff function

3.2.8

diffusion velocity

3.2.15

diffusion velocity method

3.2.22

dipole domain

3.5.2

discrete radius

3.2.16

distribution function

3.3.2

double-distribution-function lattice Boltzmann model

3.3.18

dynamic particles

3.4.7

ghost particles

3.4.5

heat domain

3.5.5

kernel approximation

3.4.4

kinetic Boltzmann equation

3.3.1

lattice

3.3.3

lattice Boltzmann fluid

3.3.14

lattice Boltzmann method

3.3.7

lattice scheme

3.3.15

lattice velocity

3.3.6

LBGK model

3.3.16

meshless methods

3.1.1

mesoscopic methods

3.1.3

method of discrete vortices

3.2.18

Monte Carlo method

3.5.7

multi-speed lattice Boltzmann model

3.3.17

node

3.3.4

particle approximation

3.4.3

particle strength exchange

3.2.21

point vortex

3.2.6

point vortex dipole

3.5.3

point vorton

3.2.11

random walk method

3.2.19

relaxation time

3.3.11

remeshing

3.2.17

repulsive particles

3.4.6

smoothed particle hydrodynamics

3.1.4

smoothing function

3.4.1

smoothing kernel

3.4.1

smoothing length

3.4.2

streaming process

3.3.10

strength

3.2.4

thermodiffusion velocity

3.5.6

VDD method

3.5.1, 3.5.4

velocity field induced by the vortex

3.2.5

velocity kernel

3.2.10

virtual particles

3.4.9

viscous dipole domains method

3.5.1, 3.5.4

viscous vortex domains method

3.2.23

vortex domain

3.2.14

vortex element

3.2.3

vortex frame

3.2.13

vortex methods

3.1.2

vortex particle

3.2.7

vortex segment

3.2.12

vorticity equation

3.2.2

VVD method

3.2.23

Zou-He boundary conditions

3.3.13