UDF

  • UDF is a text file. One can browse and edit it using a text editor, but it.can be more easily handled with "Gourmet". See the manuals below for general information on UDF.
    • English: &ref(): File not found: "udf_spec_eng.pdf" at page "UdfFile";
    • Japanese: &ref(): File not found: "UDF_Spec_jpn.pdf" at page "UdfFile";
  • In the case of UDF used for KAPSEL, one must first choose the type of problem you want to simulate by selecting "constitutive_eq" from list below.
    • Navier_Stokes: (sedimentation, diffusion, coagulation)
    • Shear_Navier_Stokes: (rheology, chain in shear flow)
    • Electrolyte: (electrophoresis)

used for KAPSEL (input.udf)

constitutive_eq: type: {Navier_Stokes, Shear_Navier_Stokes, Electrolyte}

Navier_Stokes

  • DX:
  • RHO:
  • ETA:
  • kBT:
  • alpha_v:
  • alpha_o:

Shear_Navier_Stokes

  • DX:
  • RHO:
  • ETA:
  • kBT:
  • alpha_v:
  • alpha_o:
  • External_field: type: {DC, AC}:
DC
  • shear_rate:
AC
  • shear_rate:

Electrolyte

  • DX:
  • RHO:
  • ETA:
  • kBT:
  • Dielectric_cst:
  • INIT_profile:
  • Add_salt: type: {salt, saltfree}:
salt
  • Valency_positive_ion:
  • Valency_negative_ion:
  • Onsager_coeff_positive_ion:
  • Onsager_coeff_negative_ion:
  • Debye_length:
saltfree
  • Valency_counterion:
  • Onsager_coeff_counterion:
  • Electric_field: type: {ON, OFF}:
    • ON: type: {DC, AC}:
    DC
    • Ex
    • Ey
    • Ez
    AC
    • Ex
    • Ey
    • Ez
    • Frequency

object_type: type: {spherical_particle, chain}

spherical_particle

  • Particle_spec[]
    • Particle_spec[0]
      • Particle_number
      • MASS_RATIO
      • Surface_charge

chain

  • Chain_spec[]
    • Chain_spec[0]
      • Beads_number
      • Chain_number
      • MASS_RATIO
      • Surface_charge

A_XI:

A:

gravity:

  • G:
  • G_direction: {-X, -Y, -Z}

EPSILON:

LJ_powers: {12:6, 24:12, 36:18}

mesh

  • NPX:
  • NPY:
  • NPZ:

time_increment: type: {auto, manual}

auto

  • factor

manual

  • delta_t

switch

  • ROTATION: {ON, OFF}
  • HYDRO_int: {Correct, free draining, squeeze-lubrication and drain}
  • Stokes: {with advection, w/o advection}
  • LJ_truncate: {ON, OFF, NONE}
  • INIT_distribution: type: {uniform_random, random_walk, FCC, BCC, user_specify}
random_walk
  • iteration
user_specify
  • Particles[]
    • Particles[0] 
      - R
  - x: 
  - y: 
  - z: 
- v
  - x: 
  - y: 
  - z:
FIX_CELL
  • x: {ON, OFF}
  • y: {ON, OFF}
  • z: {ON, OFF}

boundary_condition: type: {z_dirichlet, full_periodic}

z_dirichlet

  • wall_velocity_x:
  • wall_velocity_y:
  • wall_velocity_z:

output

  • GTS:
  • Num_snap:
  • AVS: {ON, OFF}
ON
  • Out_dir:
  • Out_name:
  • File_Type: {BINARY, ASCII}
  • UDF: {ON, OFF}

E:

t:

Particles[]

  • Particles[] 
    - R
  - x: 
  - y: 
  - z: 
- v
 - x: 
 - y: 
 - z:

resume

  • Calculation: {NEW, CONTINUE}