• Language: en

METHOD_OPTIONS

Type: dict_record

method options for sim_script

Example:-

METHOD_OPTIONS:
    py_module: sim
    rand_seed: 12345
    float_format: default

py_module

Type: one_of(sim)

Python module required to process this script file

Example:-

py_module: sim

rand_seed

Type: int / auto

Option to set seed to make run result reproducible -e.g. when debugging.

Example:-

rand_seed: 12345

float_format

Type: str

Format string for numerical output

Example:-

float_format: default

PARALLEL

Type: one_of_record

one of many possible servers

Example:-

PARALLEL:
    SINGLE: {}

SINGLE

Type: dict_record

single process server spec.

Example:-

SINGLE: {}

MPI_WORKERS

Type: dict_record

MPI local server spec.

Example:-

MPI_WORKERS:
    n_workers: auto

n_workers

Type: int / auto

Number of workers to use on this machine, defaults to number of processors, but could be more or fewer.

Example:-

n_workers: auto

DESCRIPTION

Type: dict_record

Description fields for script.

Example:-

DESCRIPTION:
    name: example
    title: A PKPD model
    author: A.N. Other
    abstract: |
    keywords: []

name

Type: str

Unique name used to distinguish script

Example:-

name: example

title

Type: str

A longer text string that could serve as a title

Example:-

title: A PKPD model

author

Type: str

Author of the model

Example:-

author: A.N. Other

abstract

Type: verbatim

Abstract paragraph describing model

Example:-

abstract: |

keywords

Type: list

Keywords list used to categorise models.

Example:-

keywords: []

FILE_PATHS

Type: dict_record

file paths

Example:-

FILE_PATHS:
    input_data_file: input.csv
    extra_data_file: none
    output_folder: auto
    temp_folder: auto
    log_folder: auto
    output_file_ext: ['svg']
    delete_old_files_flag: False
    solutions:
        pop: ./path_to_final_pop_solution.pyml
        indiv: ./path_to_final_indiv_solution.pyml

input_data_file

Type: input_file

path to input comma separated value file in popy data format

Example:-

input_data_file: input.csv

extra_data_file

Type: input_file / none

path to extra comma separated value file in popy data format

Example:-

extra_data_file: none

output_folder

Type: output_folder / auto

Output folder - results of computation stored here

Example:-

output_folder: auto

temp_folder

Type: output_folder / auto

Temp folder - temporary files stored here

Example:-

temp_folder: auto

log_folder

Type: output_folder / auto

Log folder - log files stored here

Example:-

log_folder: auto

output_file_ext

Type: list_of(pdf,png,svg)

Output file extension - determines graphical output file format.

Example:-

output_file_ext: ['svg']

delete_old_files_flag

Type: bool

Option to delete any existing files before running.

Example:-

delete_old_files_flag: False

solutions

Type: dict

Solutions to compare

Example:-

solutions:
    pop: ./path_to_final_pop_solution.pyml
    indiv: ./path_to_final_indiv_solution.pyml

DATA_FIELDS

Type: dict_record

data fields for popy.dat.fields object

Example:-

DATA_FIELDS:
    type_field: TYPE
    id_field: ID
    time_field: TIME

type_field

Type: str

Field name in data file that contains row type info, e.g. obs/dose etc

Example:-

type_field: TYPE

id_field

Type: str

Field name in data file that contains identity string for each data row e.g. obs/dose etc

Example:-

id_field: ID

time_field

Type: str

Field name in data file that contains time or event for each data row

Example:-

time_field: TIME

PREPROCESS

Type: verbatim

Code that preprocesses the input data. Use this to filter rows and create derived covariates.

Example:-

PREPROCESS: |

STATES

Type: verbatim

Optional section for setting initial values of s[X] variables can also set slabel[X] text labels.

Example:-

STATES: |

DERIVATIVES

Type: verbatim

Define how the covariates and effects determine flows between compartments.

Example:-

DERIVATIVES: |
    # s[DEPOT,CENTRAL,PERI] = @dep_two_cmp_cl{dose:@bolus{amt:c[AMT]}}
    d[DEPOT] = @bolus{amt:c[AMT]} - m[KA]*s[DEPOT]
    d[CENTRAL] = m[KA]*s[DEPOT] - s[CENTRAL]*m[CL]/m[V1] - s[CENTRAL]*m[Q]/m[V1]  + s[PERI]*m[Q]/m[V2]
    d[PERI] = s[CENTRAL]*m[Q]/m[V1] - s[PERI]*m[Q]/m[V2]

PREDICTIONS

Type: verbatim

Define the final predicted m[X] variables to be output by the compartment model system.

Example:-

PREDICTIONS: |
    p[DV_CENTRAL] = s[CENTRAL]/m[V1]
    var = m[ANOISE]**2 + m[PNOISE]**2 * p[DV_CENTRAL]**2
    c[DV_CENTRAL] ~ norm(p[DV_CENTRAL], var)

POSTPROCESS

Type: verbatim

Code that postprocesses the output data. Use this to filter rows and create derived covariates, after the main data curves have been generated.

Example:-

POSTPROCESS: |

ODE_SOLVER

Type: one_of_record

one of many possible solvers

Example:-

ODE_SOLVER:
    SCIPY_ODEINT:
        atol: 1e-06
        rtol: 1e-06
        max_nsteps: 10000000
        use_supersections: True
        use_jacobian: False
        use_sens: False
        use_tcrit: False

NO_SOLVER

Type: dict_record

Null method for blank derivatives.

Example:-

NO_SOLVER: {}

ANALYTIC

Type: dict_record

Analytic method for solving ODE

Example:-

ANALYTIC:
    use_supersections: auto
    use_sens: True

use_supersections

Type: bool / auto

Option to combine sections into supersections, which can make PoPy run faster, however with discontinuous ODE params you may need to turn this off (closer to nonmem approach).

Example:-

use_supersections: auto

use_sens

Type: bool

Option to use sensitivity equations in ode solver.

Example:-

use_sens: True

SCIPY_ODEINT

Type: dict_record

odeint solver record

Example:-

SCIPY_ODEINT:
    atol: 1e-06
    rtol: 1e-06
    max_nsteps: 10000000
    use_supersections: auto
    use_jacobian: False
    use_sens: True
    use_tcrit: False

atol

Type: float

Absolute tolerance of ode solver.

Example:-

atol: 1e-06

rtol

Type: float

Relative tolerance of ode solver.

Example:-

rtol: 1e-06

max_nsteps

Type: int

Maximum number of steps allowed in ode solver.

Example:-

max_nsteps: 10000000

use_supersections

Type: bool / auto

Option to combine sections into supersections, which can make PoPy run faster, however with discontinuous ODE params you may need to turn this off (closer to nonmem approach).

Example:-

use_supersections: auto

use_jacobian

Type: bool

Option to use jacobian in ode solver.

Example:-

use_jacobian: False

use_sens

Type: bool

Option to use sensitivity equations in ode solver.

Example:-

use_sens: True

use_tcrit

Type: bool

Option to set lsoda tcrit to start and end of subsection. Note this is an experimental option.

Example:-

use_tcrit: False

CPPODE

Type: dict_record

C++ version of original cvode c library.

Example:-

CPPODE:
    atol: 1e-06
    rtol: 1e-06
    max_nsteps: 10000000
    use_supersections: auto
    use_sens: True

atol

Type: float

Absolute tolerance of ode solver.

Example:-

atol: 1e-06

rtol

Type: float

Relative tolerance of ode solver.

Example:-

rtol: 1e-06

max_nsteps

Type: int

Maximum number of steps allowed in ode solver.

Example:-

max_nsteps: 10000000

use_supersections

Type: bool / auto

Option to combine sections into supersections, which can make PoPy run faster, however with discontinuous ODE params you may need to turn this off (closer to nonmem approach).

Example:-

use_supersections: auto

use_sens

Type: bool

Option to use sensitivity equations in ode solver.

Example:-

use_sens: True

CPPLSODA

Type: dict_record

C++ version of original cvode c library.

Example:-

CPPLSODA:
    atol: 1e-06
    rtol: 1e-06
    max_nsteps: 10000000
    use_supersections: auto
    use_sens: True
    hmin: 1e-12

atol

Type: float

Absolute tolerance of ode solver.

Example:-

atol: 1e-06

rtol

Type: float

Relative tolerance of ode solver.

Example:-

rtol: 1e-06

max_nsteps

Type: int

Maximum number of steps allowed in ode solver.

Example:-

max_nsteps: 10000000

use_supersections

Type: bool / auto

Option to combine sections into supersections, which can make PoPy run faster, however with discontinuous ODE params you may need to turn this off (closer to nonmem approach).

Example:-

use_supersections: auto

use_sens

Type: bool

Option to use sensitivity equations in ode solver.

Example:-

use_sens: True

hmin

Type: float

Minimum step size of ode solver.

Example:-

hmin: 1e-12

OUTPUT_OPTIONS

Type: dict_record

Output options for sim_script

Example:-

OUTPUT_OPTIONS:
    sim_time_step: -1.0

sim_time_step

Type: float

Size of time step when creating smooth curve predictions note setting this to a negative value, results in simulated predictions for each individual ONLY at time points in the original data set.

Example:-

sim_time_step: -1.0

OUTPUT_SCRIPTS

Type: dict_record

scripts to output for further processing

Example:-

OUTPUT_SCRIPTS:
    GRPH:
        output_mode: none
        grph_list: ['SPAG_GRPH']
        x_var: TIME
        x_axis_label: TIME
        y_var_list: ['DV_CENTRAL_sim', 'DV_CENTRAL']
        y_var_src_list: ['sim', 'orig']
        y_var_label_list: ['Drug conc. (units)', 'Drug conc. (units)']
        split_field: none
        share_axes: False
        y_scale: linear

GRPH

Type: dict_record

Options to pass to plt_grph_script.

Example:-

GRPH:
    output_mode: none
    grph_list: ['SPAG_GRPH']
    x_var: TIME
    x_axis_label: TIME
    y_var_list: ['DV_CENTRAL_sim', 'DV_CENTRAL']
    y_var_src_list: ['sim', 'orig']
    y_var_label_list: ['Drug conc. (units)', 'Drug conc. (units)']
    split_field: none
    share_axes: False
    y_scale: linear

output_mode

Type: one_of(none,create,run)

Output options.

Example:-

output_mode: none

grph_list

Type: list(str)

List of graph types to generate in popy_grph script.

Example:-

grph_list: ['SPAG_GRPH']

x_var

Type: str

x axis variable name.

Example:-

x_var: TIME

x_axis_label

Type: str

x axis label

Example:-

x_axis_label: TIME

y_var_list

Type: list(str)

List of y variable names to be plotted on graph.

Example:-

y_var_list: ['DV_CENTRAL_sim', 'DV_CENTRAL']

y_var_src_list

Type: list(str)

Source of data has to be either sim or orig

Example:-

y_var_src_list: ['sim', 'orig']

y_var_label_list

Type: list(str)

List of y variable labels to be plotted on graph.

Example:-

y_var_label_list: ['Drug conc. (units)', 'Drug conc. (units)']

split_field

Type: str

field in c[X] data use each value to split data.

Example:-

split_field: none

share_axes

Type: bool

Option to share axes between individuals when plotting graphical data

Example:-

share_axes: False

y_scale

Type: one_of(linear,log)

y axis scale - can be either ‘linear’ or ‘log’.

Example:-

y_scale: linear
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