Submit PySceS 0.9.9

[biosimulators-daemon]

---

id: pysces version: 0.9.9 specificationsUrl: https://raw.githubusercontent.com/biosimulators/Biosimulators_PySCeS/b2b1fa3d39e9632764aef16fa30477013b89059e/biosimulators.json specificationsPatch: version: 0.9.9 image: url: ghcr.io/biosimulators/biosimulators_pysces/pysces:0.9.9 validateImage: true commitSimulator: true

---

[biosimulators-daemon]

Thank you @biosimulators-daemon for your submission to the BioSimulators simulator validation/submission system!

The BioSimulators validator bot is validating the specifications of your simulator, validating your Docker image, and committing your simulator to the BioSimulators registry.

We will discuss any concerns with your submission in this issue.

A complete log of your simulator submission job will be available for 90 days here. The results of the validation of your tool will also be saved as a JSON file. A link to this file will be available for 90 days from the "Artifacts" section at the bottom of this page.

[biosimulators-daemon]

The specifications of your simulator is valid!

[biosimulators-daemon]

Summary of tests

• Executed 71 test cases

• Passed 49 test cases:

  • cli.CliDescribesSupportedEnvironmentVariablesInline
  • cli.CliDisplaysHelpInline
  • cli.CliDisplaysVersionInformationInline
  • combine_archive.CombineArchiveHasSedDocumentsInNestedDirectories
  • combine_archive.CombineArchiveHasSedDocumentsWithSameNamesInDifferentInNestedDirectories
  • combine_archive.WhenACombineArchiveHasAMasterFileSimulatorOnlyExecutesThisFile
  • combine_archive.WhenACombineArchiveHasNoMasterFileSimulatorExecutesAllSedDocuments
  • docker_image.DeclaresSupportedEnvironmentVariables
  • docker_image.DefaultUserIsRoot
  • docker_image.HasBioContainersLabels
  • docker_image.HasOciLabels
  • docker_image.SingularityImageExecutesSimulationsSuccessfully
  • log.SimulatorReportsTheStatusOfTheExecutionOfCombineArchives
  • log.SimulatorReportsTheStatusOfTheExecutionOfSedDocuments
  • log.SimulatorReportsTheStatusOfTheExecutionOfSedOutputs
  • log.SimulatorReportsTheStatusOfTheExecutionOfSedTasks
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Caravagna-J-Theor-Biol-2010-tumor-suppressive-oscillations
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Ciliberto-J-Cell-Biol-2003-morphogenesis-checkpoint-continuous
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Edelstein-Biol-Cybern-1996-Nicotinic-excitation
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Elowitz-Nature-2000-Repressilator
  • results_report.SimulatorGeneratesReportsOfSimulationResults
  • sedml.SimulatorCanResolveModelSourcesDefinedByUriFragments
  • sedml.SimulatorCanResolveModelSourcesDefinedByUriFragmentsAndInheritChanges
  • sedml.SimulatorProducesLinear2DPlots
  • sedml.SimulatorProducesLogarithmic2DPlots
  • sedml.SimulatorProducesMultiplePlots
  • sedml.SimulatorProducesReportsWithCuratedNumberOfDimensions
  • sedml.SimulatorSupportsAddReplaceRemoveModelElementChanges
  • sedml.SimulatorSupportsAlgorithmParameters
  • sedml.SimulatorSupportsComputeModelChanges
  • sedml.SimulatorSupportsDataGeneratorsWithDifferentShapes
  • sedml.SimulatorSupportsDataSetsWithDifferentShapes
  • sedml.SimulatorSupportsModelAttributeChanges
  • sedml.SimulatorSupportsModelsSimulationsTasksDataGeneratorsAndReports
  • sedml.SimulatorSupportsMultipleReportsPerSedDocument
  • sedml.SimulatorSupportsMultipleTasksPerSedDocument
  • sedml.SimulatorSupportsRepeatedTasksWithChanges
  • sedml.SimulatorSupportsRepeatedTasksWithFunctionalRangeVariables
  • sedml.SimulatorSupportsRepeatedTasksWithFunctionalRanges
  • sedml.SimulatorSupportsRepeatedTasksWithLinearUniformRanges
  • sedml.SimulatorSupportsRepeatedTasksWithLogarithmicUniformRanges
  • sedml.SimulatorSupportsRepeatedTasksWithMultipleSubTasks
  • sedml.SimulatorSupportsRepeatedTasksWithNestedFunctionalRanges
  • sedml.SimulatorSupportsRepeatedTasksWithNestedRepeatedTasks
  • sedml.SimulatorSupportsRepeatedTasksWithSubTasksOfMixedTypes
  • sedml.SimulatorSupportsRepeatedTasksWithVectorRanges
  • sedml.SimulatorSupportsSubstitutingAlgorithms
  • sedml.SimulatorSupportsUniformTimeCoursesWithNonZeroInitialTimes
  • sedml.SimulatorSupportsUniformTimeCoursesWithNonZeroOutputStartTimes

• Failed 0 test cases

• Skipped 22 test cases:

  • published_project.SimulatorCanExecutePublishedProject:bngl/Dolan-PLoS-Comput-Biol-2015-NHEJ
  • published_project.SimulatorCanExecutePublishedProject:bngl/test-bngl
  • published_project.SimulatorCanExecutePublishedProject:cellml/Elowitz-Nature-2000-Repressilator
  • published_project.SimulatorCanExecutePublishedProject:cellml/Lorenz-system
  • published_project.SimulatorCanExecutePublishedProject:neuroml-lems/Hodgkin-Huxley-cell-CVODE
  • published_project.SimulatorCanExecutePublishedProject:neuroml-lems/Hodgkin-Huxley-cell-Euler
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Ciliberto-J-Cell-Biol-2003-morphogenesis-checkpoint-Fehlberg
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Parmar-BMC-Syst-Biol-2017-iron-distribution
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Szymanska-J-Theor-Biol-2009-HSP-synthesis
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Tomida-EMBO-J-2003-NFAT-translocation
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Varusai-Sci-Rep-2018-mTOR-signaling-LSODA-LSODAR-SBML
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Vilar-PNAS-2002-minimal-circardian-clock
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Vilar-PNAS-2002-minimal-circardian-clock-continuous
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Vilar-PNAS-2002-minimal-circardian-clock-discrete-NRM
  • published_project.SimulatorCanExecutePublishedProject:sbml-core/Vilar-PNAS-2002-minimal-circardian-clock-discrete-SSA
  • published_project.SimulatorCanExecutePublishedProject:sbml-fbc/Escherichia-coli-core-metabolism
  • published_project.SimulatorCanExecutePublishedProject:sbml-qual/Chaouiya-BMC-Syst-Biol-2013-EGF-TNFa-signaling
  • published_project.SimulatorCanExecutePublishedProject:sbml-qual/Irons-J-Theor-Biol-2009-yeast-cell-cycle
  • published_project.SimulatorCanExecutePublishedProject:smoldyn/Lotka-Volterra
  • published_project.SimulatorCanExecutePublishedProject:xpp/Wu-Biochem-Pharmacol-2006-pituitary-GH3-cells
  • sedml.SimulatorProducesLinear3DPlots
  • sedml.SimulatorProducesLogarithmic3DPlots

[biosimulators-daemon]

Warnings

cli.CliDescribesSupportedEnvironmentVariablesInline (4.1 s)

Test that the inline help for a command-line interface describes the environment variables that the simulator supports.

Warnings:

  The inline help for a command-line interface for a simulation tool should describe the environment variables that the simulation tool supports.

  The command-line interface does not describe the following standard environment variables recognized by BioSimulators:
    - 'ALGORITHM_SUBSTITUTION_POLICY'

  If the simulation tool implements these variables, they should be described in the inline help for its command-line interface.

  Note, support for these environment variables is optional. Simulation tools are not required to support these variables.

Log:

published_project.SimulatorCanExecutePublishedProject:sbml-core/Caravagna-J-Theor-Biol-2010-tumor-suppressive-oscillations (5.1 s)

Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000019

  Warnings:

  Unexpected reports were produced:
  BIOMD0000000912_sim.sedml/Figure_1_bottom_left

  Plots were not produced:
  BIOMD0000000912_sim.sedml/plot_1

  Extra plots were produced:
  BIOMD0000000912_sim.sedml/Figure_1_bottom_left

  Log:

  
  Cannot load backend 'TkAgg' which requires the 'tk' interactive framework, as 'headless' is currently running
  
  PySCeS defaults to matplotlib's TKagg backend if not specified                      in the user configuration file, set "matplotlib_backend = <backend>" 
  
  Matplotlib interface loaded (pysces.plt.m)
  
  Pitcon routines available
  
  NLEQ2 routines available
  
  SBML support available
  
  You are using NumPy (1.21.1) with SciPy (1.6.3)
  
  /opt/conda/envs/py/lib/python3.9/site-packages/assimulo/solvers/odepack.py:710: VisibleDeprecationWarning: Creating an ndarray from ragged nested sequences (which is a list-or-tuple of lists-or-tuples-or ndarrays with different lengths or shapes) is deprecated. If you meant to do this, you must specify 'dtype=object' when creating the ndarray.
  
  N.array([[0.,0.,0.,0.,0.,0.,0.,0.,0.,0.,0.,0.,0.,0.],  # 5th order
  
  Assimulo CVode available
  
  RateChar is available
  
  No module named 'ipyparallel'
  
  PARSCANNER: Requires ipyparallel version >=4.0 (http://ipython.org).
  
  INFO: Parallel scanner not available
  
  PySCeS environment
  
  ******************
  
  pysces.model_dir = /root/Pysces/psc
  
  pysces.output_dir = /root/Pysces
  
  ***********************************************************************

• Welcome to PySCeS (0.9.9) - Python Simulator for Cellular Systems *

• http://pysces.sourceforge.net *

• Copyright(C) B.G. Olivier, J.M. Rohwer, J.-H.S. Hofmeyr, 2004-2020 *

• Triple-J Group for Molecular Cell Physiology *

• Stellenbosch University, ZA and VU University Amsterdam, NL *

• PySCeS is distributed under the PySCeS (BSD style) licence, see *

• LICENCE.txt (supplied with this release) for details *

• Please cite PySCeS with: doi:10.1093/bioinformatics/bti046 *

  ---

  /opt/conda/envs/py/lib/python3.9/site-packages/biosimulators_utils/warnings.py:31: BioSimulatorsWarning: The SED document is potentially incorrect.

  • Model BIOMD0000000912 may be invalid.

    • The model file Caravagna2010.xml may be invalid.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}compartment\; *\; Function\_for\_induction\_of\_tumor(r2,\; T,\; b,\; V)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}compartment\; *\; Function\_for\_removal\_of\_the\_tumor(a,\; T,\; g2,\; V,\; E)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}compartment\; *\; Function\_for\_activation\_and\_transfer\_of\_effector\_cells\_to\_the\_tumor\_site(p1,\; I,\; g1,\; E,\; c,\; T,\; V,\; s1)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}compartment\; *\; Function\_for\_deactivation\_and\_removal\_of\_effector\_cells\_from\_the\_site\_of\_tumor(mu2,\; E)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}compartment\; *\; Function\_for\_activation\_of\_interleukin\_2(p2,\; V,\; T,\; E,\; g3,\; s2)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}compartment\; *\; Function\_for\_deactivation\_of\_interleukin\_2(mu3,\; I)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'r2' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'b' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'a' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'g2' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'p1' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'g1' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'mu2' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'c' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'p2' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'g3' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'mu3' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'V' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 's1' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 's2' does not have a 'units' attribute.

      

  warnings.warn(termcolor.colored(message, Colors.warning.value), category)

  /opt/conda/envs/py/lib/python3.9/site-packages/biosimulators_utils/warnings.py:31: BioSimulatorsWarning: The COMBINE/OMEX archive may be invalid.

  • The SED-ML file at location ./BIOMD0000000912_sim.sedml may be invalid.

    • Model BIOMD0000000912 may be invalid.

    • The model file Caravagna2010.xml may be invalid.

      • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

        The units of the $expression\; \text{'}compartment\; *\; Function\_for\_induction\_of\_tumor(r2,\; T,\; b,\; V)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

      • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

        The units of the $expression\; \text{'}compartment\; *\; Function\_for\_removal\_of\_the\_tumor(a,\; T,\; g2,\; V,\; E)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

      • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

        The units of the $expression\; \text{'}compartment\; *\; Function\_for\_activation\_and\_transfer\_of\_effector\_cells\_to\_the\_tumor\_site(p1,\; I,\; g1,\; E,\; c,\; T,\; V,\; s1)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

      • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

        The units of the $expression\; \text{'}compartment\; *\; Function\_for\_deactivation\_and\_removal\_of\_effector\_cells\_from\_the\_site\_of\_tumor(mu2,\; E)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

      • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

        The units of the $expression\; \text{'}compartment\; *\; Function\_for\_activation\_of\_interleukin\_2(p2,\; V,\; T,\; E,\; g3,\; s2)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

      • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

        The units of the $expression\; \text{'}compartment\; *\; Function\_for\_deactivation\_of\_interleukin\_2(mu3,\; I)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 'r2' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 'b' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 'a' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 'g2' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 'p1' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 'g1' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 'mu2' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 'c' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 'p2' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 'g3' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 'mu3' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 'V' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 's1' does not have a 'units' attribute.

      • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

        The with the id 's2' does not have a 'units' attribute.

      

  warnings.warn(termcolor.colored(message, Colors.warning.value), category)

  Archive contains 1 SED-ML documents with 1 models, 1 simulations, 1 tasks, 1 reports, and 1 plots:

  BIOMD0000000912_sim.sedml:

  Tasks (1):

  BIOMD0000000912_task

  Reports (1):

  report: 4 data sets

  Plots (1):

  Figure_1_bottom_left: 3 curves

  Executing SED-ML file 0: BIOMD0000000912_sim.sedml ...

  Bundling outputs ...

  Cleaning up ...

  ============= SUMMARY =============

  Executed 1 SED documents:

  SED documents (1):

  Succeeded: 1

  Skipped: 0

  Failed: 0

  Tasks (1):

  Succeeded: 1

  Skipped: 0

  Failed: 0

  Outputs (2):

  Succeeded: 2

  Skipped: 0

  Failed: 0

  
  ### `published_project.SimulatorCanExecutePublishedProject:sbml-core/Ciliberto-J-Cell-Biol-2003-morphogenesis-checkpoint-continuous` (5.8 s)
  
  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000019

  Warnings:

  Unexpected reports were produced:
  simulation_1.sedml/Figure_3a
  simulation_1.sedml/Figure_3b
  simulation_1.sedml/Figure_3c
  simulation_1.sedml/Figure_3d

  Plots were not produced:
  simulation.sedml/Figure_3a
  simulation.sedml/Figure_3b
  simulation.sedml/Figure_3c
  simulation.sedml/Figure_3d

  Extra plots were produced:
  simulation_1.sedml/Figure_3a
  simulation_1.sedml/Figure_3b
  simulation_1.sedml/Figure_3c
  simulation_1.sedml/Figure_3d

  Log:

  
  Cannot load backend 'TkAgg' which requires the 'tk' interactive framework, as 'headless' is currently running
  
  PySCeS defaults to matplotlib's TKagg backend if not specified                      in the user configuration file, set "matplotlib_backend = <backend>" 
  
  Matplotlib interface loaded (pysces.plt.m)
  
  Pitcon routines available
  
  NLEQ2 routines available
  
  SBML support available
  
  You are using NumPy (1.21.1) with SciPy (1.6.3)
  
  /opt/conda/envs/py/lib/python3.9/site-packages/assimulo/solvers/odepack.py:710: VisibleDeprecationWarning: Creating an ndarray from ragged nested sequences (which is a list-or-tuple of lists-or-tuples-or ndarrays with different lengths or shapes) is deprecated. If you meant to do this, you must specify 'dtype=object' when creating the ndarray.
  
  N.array([[0.,0.,0.,0.,0.,0.,0.,0.,0.,0.,0.,0.,0.,0.],  # 5th order
  
  Assimulo CVode available
  
  RateChar is available
  
  No module named 'ipyparallel'
  
  PARSCANNER: Requires ipyparallel version >=4.0 (http://ipython.org).
  
  INFO: Parallel scanner not available
  
  PySCeS environment
  
  ******************
  
  pysces.model_dir = /root/Pysces/psc
  
  pysces.output_dir = /root/Pysces
  
  ***********************************************************************

• Welcome to PySCeS (0.9.9) - Python Simulator for Cellular Systems *

• http://pysces.sourceforge.net *

• Copyright(C) B.G. Olivier, J.M. Rohwer, J.-H.S. Hofmeyr, 2004-2020 *

• Triple-J Group for Molecular Cell Physiology *

• Stellenbosch University, ZA and VU University Amsterdam, NL *

• PySCeS is distributed under the PySCeS (BSD style) licence, see *

• LICENCE.txt (supplied with this release) for details *

• Please cite PySCeS with: doi:10.1093/bioinformatics/bti046 *

  ---

  /opt/conda/envs/py/lib/python3.9/site-packages/biosimulators_utils/warnings.py:31: BioSimulatorsWarning: The SED document is potentially incorrect.

  • Model Ciliberto2003_Morphogenesis may be invalid.

    • The model file BIOMD0000000297_url.xml may be invalid.

    • The value of the 'sboTerm' attribute on a is expected to be an SBO identifier (http://www.biomodels.net/SBO/). In SBML Level 2 prior to Version 4 it is expected to refer to a participant physical type (i.e., terms derived from SBO:0000236, "participant physical type"); in Versions 4 and above it is expected to refer to a material entity (i.e., terms derived from SBO:0000240, "material entity").

      Reference: L2V4 Section 5

      SBO term 'SBO:0000014' on the is not in the appropriate branch.

    • The value of the 'sboTerm' attribute on a is expected to be an SBO identifier (http://www.biomodels.net/SBO/). In SBML Level 2 prior to Version 4 it is expected to refer to a participant physical type (i.e., terms derived from SBO:0000236, "participant physical type"); in Versions 4 and above it is expected to refer to a material entity (i.e., terms derived from SBO:0000240, "material entity").

      Reference: L2V4 Section 5

      SBO term 'SBO:0000236' on the is not in the appropriate branch.

    • The value of the 'sboTerm' attribute on a is expected to be an SBO identifier (http://www.biomodels.net/SBO/). In SBML Level 2 prior to Version 4 it is expected to refer to a participant physical type (i.e., terms derived from SBO:0000236, "participant physical type"); in Versions 4 and above it is expected to refer to a material entity (i.e., terms derived from SBO:0000240, "material entity").

      Reference: L2V4 Section 5

      SBO term 'SBO:0000236' on the is not in the appropriate branch.

    • The value of the 'sboTerm' attribute on a is expected to be an SBO identifier (http://www.biomodels.net/SBO/) referring to a quantitative parameter defined in SBO (i.e., terms derived from SBO:0000002, "quantitative systems description parameter").

      Reference: L2V4 Sections 4.9.5 and 5

      SBO term 'SBO:0000336' on the is not in the appropriate branch.

    • The value of the 'sboTerm' attribute on a is expected to be an SBO identifier (http://www.biomodels.net/SBO/) referring to a quantitative parameter defined in SBO (i.e., terms derived from SBO:0000002, "quantitative systems description parameter").

      Reference: L2V4 Sections 4.9.5 and 5

      SBO term 'SBO:0000336' on the is not in the appropriate branch.

    • The value of the 'sboTerm' attribute on a is expected to be an SBO identifier (http://www.biomodels.net/SBO/) referring to a quantitative parameter defined in SBO (i.e., terms derived from SBO:0000002, "quantitative systems description parameter").

      Reference: L2V4 Sections 4.9.5 and 5

      SBO term 'SBO:0000393' on the is not in the appropriate branch.

    • The value of the 'sboTerm' attribute on a is expected to be an SBO identifier (http://www.biomodels.net/SBO/) referring to a quantitative parameter defined in SBO (i.e., terms derived from SBO:0000002, "quantitative systems description parameter").

      Reference: L2V4 Sections 4.9.5 and 5

      SBO term 'SBO:0000393' on the is not in the appropriate branch.

    • The value of the 'sboTerm' attribute on a is expected to be an SBO identifier (http://www.biomodels.net/SBO/) referring to a quantitative parameter defined in SBO (i.e., terms derived from SBO:0000002, "quantitative systems description parameter").

      Reference: L2V4 Sections 4.9.5 and 5

      SBO term 'SBO:0000393' on the is not in the appropriate branch.

    • The value of the 'sboTerm' attribute on a is expected to be an SBO identifier (http://www.biomodels.net/SBO/) referring to a quantitative parameter defined in SBO (i.e., terms derived from SBO:0000002, "quantitative systems description parameter").

      Reference: L2V4 Sections 4.9.5 and 5

      SBO term 'SBO:0000393' on the is not in the appropriate branch.

    • The value of the 'sboTerm' attribute on a is expected to be an SBO identifier (http://www.biomodels.net/SBO/) referring to a quantitative parameter defined in SBO (i.e., terms derived from SBO:0000002, "quantitative systems description parameter").

      Reference: L2V4 Sections 4.9.5 and 5

      SBO term 'SBO:0000393' on the is not in the appropriate branch.

    • The value of the 'sboTerm' attribute on a is expected to be an SBO identifier (http://www.biomodels.net/SBO/) referring to a quantitative parameter defined in SBO (i.e., terms derived from SBO:0000002, "quantitative systems description parameter").

      Reference: L2V4 Sections 4.9.5 and 5

      SBO term 'SBO:0000393' on the is not in the appropriate branch.

    • The value of the 'sboTerm' attribute on a is expected to be an SBO identifier (http://www.biomodels.net/SBO/) referring to a quantitative parameter defined in SBO (i.e., terms derived from SBO:0000002, "quantitative systems description parameter").

      Reference: L2V4 Sections 4.9.5 and 5

      SBO term 'SBO:0000393' on the is not in the appropriate branch.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kswe\_prime$ Swe1 + kswe_doubleprime Swe1M + kswe_tripleprime * PSwe1' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kmih\_prime$ Mih_ast + kmih_doubleprime Mih' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}IEtot\; -\; IE\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Cdh1tot\; -\; Cdh1\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Mih1tot\; -\; Mih1a\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Mcmtot\; -\; Mcm\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}SBFtot\; -\; SBF\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kdiss\; *\; Trim\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Trim$ (kdsic_prime Cln + kdsic_doubleprime * Clb + kdsic)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Trim$ (kdclb_doubleprime Cdh1 + kdclb_tripleprime * Cdc20a + kdclb_prime)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Trim\; *\; kswe\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kass$ Sic Clb' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}PTrim\; *\; kmih\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Clb$ (kdclb_doubleprime Cdh1 + kdclb_tripleprime * Cdc20a + kdclb_prime)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kswe\; *\; Clb\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}ksclb$ mass Jm * (eps + Mcm) / (mass + Jm)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kmih\; *\; PClb\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}SBF$ (kisbf_prime + kisbf_doubleprime Clb) / (jisbf + SBF)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}SBFin$ (kasbf_prime mass + kasbf_doubleprime * Cln) / (jasbf + SBFin)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}IE\; *\; kiie\; /\; (jiie\; +\; IE)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kaie$ IEin Clb / (jaie + IEin)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Cdc20a\; *\; kicdc20\; /\; (jicdc20\; +\; Cdc20a)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kdcdc20\; *\; Cdc20a\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kacdc20$ Cdc20 IE / (jacdc20 + Cdc20)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Cdh1$ (kicdh Clb + kicdh_prime * Cln) / (jicdh + Cdh1)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Cdh1in$ (Kacdh_prime + Kacdh_doubleprime Cdc20a) / (jacdh + Cdh1in)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}khsl1$ BUD Swe1' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}khsl1$ BUD PSwe1' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Viwee$ Swe1 Clb / (Jiwee + Swe1)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Viwee$ Swe1M Clb / (Jiwee + Swe1M)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kdswe\_prime\; *\; Swe1\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}khsl1r\; *\; Swe1M\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}khsl1r\; *\; PSwe1M\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}PSwe1\; *\; Vawee\; /\; (Jawee\; +\; PSwe1)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}PSwe1M\; *\; Vawee\; /\; (Jawee\; +\; PSwe1M)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}ksswe\; *\; SBF\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kssweC\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kdswe\_prime\; *\; PSwe1\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kdiss\; *\; PTrim\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}PTrim$ (kdclb_doubleprime Cdh1 + kdclb_tripleprime * Cdc20a + kdclb_prime)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}PTrim$ (kdsic_prime Cln + kdsic_doubleprime * Clb + kdsic)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kass$ PClb Sic' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Mih1a\; *\; Vimih\; /\; (jimih\; +\; Mih1a)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Vamih$ Mih1 Clb / (Jamih + Mih1)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Mcm\; *\; kimcm\; /\; (jimcm\; +\; Mcm)\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Mcmin$ Clb kamcm / (jamcm + Mcmin)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kdbud\; *\; BE\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}ksbud\; *\; Cln\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}Sic$ (kdsic_prime Cln + kdsic_doubleprime * Clb + kdsic)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kssic\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kdcln\; *\; Cln\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kscln\; *\; SBF\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kdswe\_prime\; *\; Swe1M\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kdcdc20\; *\; Cdc20\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kscdc20\_prime\; +\; kscdc20\_doubleprime\; *\; pow(Clb,\; 4)\; /\; (pow(jscdc20,\; 4)\; +\; pow(Clb,\; 4))\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}kdswe\_doubleprime\; *\; PSwe1M\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}PClb$ (kdclb_doubleprime Cdh1 + kdclb_tripleprime * Cdc20a + kdclb_prime)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}mu\; *\; mass\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the expression 'gt(Clb, 0.2)' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}1\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the expression 'and(lt(Clb, 0.2), gt(flag, 0))' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}0\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}0.5\; *\; mass\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the expression 'or(geq(Clb, 0.2), geq(BE, 0.6))' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}1\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the expression 'and(lt(Clb, 0.2), lt(BE, 0.6))' cannot be fully checked. Unit consistency reported as either no errors or further unit errors related to this object may not be accurate.

    • In situations where a mathematical expression contains literal numbers or parameters whose units have not been declared, it is not possible to verify accurately the consistency of the units in the expression.

      The units of the $expression\; \text{'}0\text{'}\; cannot\; be\; fully\; checked.\; Unit\; consistency\; reported\; as\; either\; no\; errors\; or\; further\; unit\; errors\; related\; to\; this\; object\; may\; not\; be\; accurate.$

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'kswe' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'kswe_prime' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'kswe_doubleprime' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'kswe_tripleprime' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'kmih' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'kmih_prime' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'Mih_ast' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'kmih_doubleprime' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be declared rather than be left undefined. Doing so improves the ability of software to check the consistency of units and helps make it easier to detect potential errors in models.

      The with the id 'Mih' does not have a 'units' attribute.

    • As a principle of best modeling practice, the units of a should be de ...

[biosimulators-daemon]

Skips

published_project.SimulatorCanExecutePublishedProject:bngl/Dolan-PLoS-Comput-Biol-2015-NHEJ (0.0 s)

Required model formats and simulation algorithms for SED tasks:

• Format: format_3972 Algorithm: KISAO_0000263

  Reason for skip:

  Case requires model formats format_3972 and simulation algorithms KISAO_0000263

  Log:

  published_project.SimulatorCanExecutePublishedProject:bngl/test-bngl (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_3972 Algorithm: KISAO_0000019

  Reason for skip:

  Case requires model formats format_3972 and simulation algorithms KISAO_0000019

  Log:

  published_project.SimulatorCanExecutePublishedProject:cellml/Elowitz-Nature-2000-Repressilator (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_3240 Algorithm: KISAO_0000019

  Reason for skip:

  Case requires model formats format_3240 and simulation algorithms KISAO_0000019

  Log:

  published_project.SimulatorCanExecutePublishedProject:cellml/Lorenz-system (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_3240 Algorithm: KISAO_0000019

  Reason for skip:

  Case requires model formats format_3240 and simulation algorithms KISAO_0000019

  Log:

  published_project.SimulatorCanExecutePublishedProject:neuroml-lems/Hodgkin-Huxley-cell-CVODE (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_9004 Algorithm: KISAO_0000019

  Reason for skip:

  Case requires model formats format_9004 and simulation algorithms KISAO_0000019

  Log:

  published_project.SimulatorCanExecutePublishedProject:neuroml-lems/Hodgkin-Huxley-cell-Euler (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_9004 Algorithm: KISAO_0000030

  Reason for skip:

  Case requires model formats format_9004 and simulation algorithms KISAO_0000030

  Log:

  published_project.SimulatorCanExecutePublishedProject:sbml-core/Ciliberto-J-Cell-Biol-2003-morphogenesis-checkpoint-Fehlberg (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000086

  Reason for skip:

  Case requires model formats format_2585 and simulation algorithms KISAO_0000086

  Log:

  published_project.SimulatorCanExecutePublishedProject:sbml-core/Parmar-BMC-Syst-Biol-2017-iron-distribution (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_000019

  Reason for skip:

  Case requires model formats format_2585 and simulation algorithms KISAO_000019

  Log:

  published_project.SimulatorCanExecutePublishedProject:sbml-core/Szymanska-J-Theor-Biol-2009-HSP-synthesis (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000496

  Reason for skip:

  Case requires model formats format_2585 and simulation algorithms KISAO_0000496

  Log:

  published_project.SimulatorCanExecutePublishedProject:sbml-core/Tomida-EMBO-J-2003-NFAT-translocation (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000560

  Reason for skip:

  Case requires model formats format_2585 and simulation algorithms KISAO_0000560

  Log:

  published_project.SimulatorCanExecutePublishedProject:sbml-core/Varusai-Sci-Rep-2018-mTOR-signaling-LSODA-LSODAR-SBML (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000560

  Reason for skip:

  Case requires model formats format_2585 and simulation algorithms KISAO_0000560

  Log:

  published_project.SimulatorCanExecutePublishedProject:sbml-core/Vilar-PNAS-2002-minimal-circardian-clock (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000019

• Format: format_2585 Algorithm: KISAO_0000027

• Format: format_2585 Algorithm: KISAO_0000030

  Reason for skip:

  Case requires model formats format_2585 and simulation algorithms KISAO_0000019, KISAO_0000027, KISAO_0000030

  Log:

  published_project.SimulatorCanExecutePublishedProject:sbml-core/Vilar-PNAS-2002-minimal-circardian-clock-continuous (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000019

• Format: format_2585 Algorithm: KISAO_0000030

  Reason for skip:

  Case requires model formats format_2585 and simulation algorithms KISAO_0000019, KISAO_0000030

  Log:

  published_project.SimulatorCanExecutePublishedProject:sbml-core/Vilar-PNAS-2002-minimal-circardian-clock-discrete-NRM (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000027

  Reason for skip:

  Case requires model formats format_2585 and simulation algorithms KISAO_0000027

  Log:

  published_project.SimulatorCanExecutePublishedProject:sbml-core/Vilar-PNAS-2002-minimal-circardian-clock-discrete-SSA (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000029

  Reason for skip:

  Case requires model formats format_2585 and simulation algorithms KISAO_0000029

  Log:

  published_project.SimulatorCanExecutePublishedProject:sbml-fbc/Escherichia-coli-core-metabolism (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000437

  Reason for skip:

  Case requires model formats format_2585 and simulation algorithms KISAO_0000437

  Log:

  published_project.SimulatorCanExecutePublishedProject:sbml-qual/Chaouiya-BMC-Syst-Biol-2013-EGF-TNFa-signaling (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000449

  Reason for skip:

  Case requires model formats format_2585 and simulation algorithms KISAO_0000449

  Log:

  published_project.SimulatorCanExecutePublishedProject:sbml-qual/Irons-J-Theor-Biol-2009-yeast-cell-cycle (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_2585 Algorithm: KISAO_0000449

  Reason for skip:

  Case requires model formats format_2585 and simulation algorithms KISAO_0000449

  Log:

  published_project.SimulatorCanExecutePublishedProject:smoldyn/Lotka-Volterra (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_9001 Algorithm: KISAO_0000057

  Reason for skip:

  Case requires model formats format_9001 and simulation algorithms KISAO_0000057

  Log:

  published_project.SimulatorCanExecutePublishedProject:xpp/Wu-Biochem-Pharmacol-2006-pituitary-GH3-cells (0.0 s)

  Required model formats and simulation algorithms for SED tasks:

• Format: format_9010 Algorithm: KISAO_0000019

  Reason for skip:

  Case requires model formats format_9010 and simulation algorithms KISAO_0000019

  Log:

  sedml.SimulatorProducesLinear3DPlots (0.1 s)

  Test that a simulator produces linear 3D plots

  Reason for skip:

  No curated COMBINE/OMEX archives are available to generate archives for testing

  Log:

  sedml.SimulatorProducesLogarithmic3DPlots (0.1 s)

  Test that a simulator produces logarithmic 3D plots

  Reason for skip:

  No curated COMBINE/OMEX archives are available to generate archives for testing

  Log:

[biosimulators-daemon]

The image for your simulator is valid!

[biosimulators-daemon]

Your submission was committed to the BioSimulators registry. Thank you!

Future submissions of subsequent versions of pysces to the BioSimulators registry will be automatically validated. These submissions will not require manual review by the BioSimulators Team.