Difference between revisions of "The Magrathea Manual: Building Coordinated Agent Models"
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| key||show-label | | key||show-label | ||
|- | |- | ||
| − | | format||show-label [1 | + | | format|| show-label [1 or 0] |
|- | |- | ||
| description||Boolean to determine if label should be shown. | | description||Boolean to determine if label should be shown. | ||
| Line 254: | Line 254: | ||
| example||shape Cube 1.0 2.0 3.5 | | example||shape Cube 1.0 2.0 3.5 | ||
|} | |} | ||
| + | |||
| + | Notes: | ||
| + | |||
| + | Two shapes may be used to draw a molecule, a sphere or a cube. | ||
| + | |||
| + | If a Sphere is chosen, at least one additional float value must be given to specify the radius of the sphere. A second, optional float value may be given to specify the “effective radius” of the molecule. “Effective radius” is used to maintain distances between “molecules” that act as compartment markers. Compartment markers are used in place of representing all of the molecules that are really present in a membrane. They can be thought of as representing a single molecule at the center of a circular collection of molecules where the radius of the circle is the “effective radius”. Compartment markers will maintain a distance from one another equivalent to (er1 + er2) where er1 and er2 are the effective radii of compartment markers 1 and 2. Other molecules (non compartment markers) will maintain a distance from compartment markers of (r1 + r2) where r1 and r2 are the radii of the compartment marker and the molecule respectively. A second float value must be specified after the shape key in order for the molecule to behave as a compartment marker. | ||
| + | |||
| + | {|border="1" cellpadding="2" | ||
| + | | align="center" style="background:yellow" colspan="2"|'''draw-as-point''' | ||
| + | |- | ||
| + | | key||draw-as-point | ||
| + | |- | ||
| + | | format||draw-as-point [1 or 0] | ||
| + | |- | ||
| + | | description||A Boolean flag indicating that the molecule is to be drawn as a point. | ||
| + | |- | ||
| + | | required||no | ||
| + | |- | ||
| + | | default value||draw-as-point 0 | ||
| + | |- | ||
| + | | example||draw-as-point 1 | ||
| + | |} | ||
| + | Notes: If draw–as-point is set to 1 (TRUE) then the molecule will appear in the simulation as a point. The radius and effective radius will still be as specified in the shape line. This flag is used to speed up the simulation by reducing the amount of required rendering. It may also be used to hide molecule types that are not of interest to the user. Values other than 1 are interpreted as 0 (FALSE). | ||
Revision as of 10:43, 9 March 2009
Contents
Making models
The model.txt file
Magrathea opens a file called “model.txt” at the beginning of a simulation. Information is read from the file to populate the simulation with molecules and coordinators. The properties of different types of molecules and coordinators are specified in the model.txt file along with the number and positions of all of the starting molecules and coordinators. The sections below describe the format of the model.txt file.
A simple example
An example model.txt file is shown below in Figure 1.
The model.txt file is a text file and must be called “model.txt”. Lines beginning with # are comments and are ignored. Blank lines are ignored. Any text in the file after the line
EOF
will be ignored.
There are two types of sections in a model file. A section used to describe a type of molecule and create instances of that molecule type at the beginning of the simulation begins with the line:
[moleculeType]
and ends with the line
[/moleculeType]
A section that is used to describe a coordinator type and create instances of that coordinator at the beginning of the simulation begins with the line:
[coordinatorType]
and ends with the line
[/coordinatorType]
An example model.txt file for Magrathea
########### #ab complex ########### [moleculeType] id 1 label a color .81 .60 .21 shape Sphere 1 neighborhood-size 5 coordinator 1 3 instantiate 10 random spherical volume 10 30 10 10 [/moleculeType] [moleculeType] id 2 label b color 0.67 0.08 0.37 shape Sphere 1 neighborhood-size 5 coordinator 1 3 instantiate 4 random spherical volume 10 15 10 10 [/moleculeType] [coordinatorType] id 3 label a-b-complex shape Cube 1 1 1 molecule 1 1 molecule 2 1 [/coordinatorType] EOF
Key-value format
Each line in these two sections types encodes a separate piece of information as a key-value pair. So, for instance, members of the first molecule type are labeled “a” as indicated by the line
label a
In this line “label” is the key and “a” is the value. Keys and their values are separated by white-spaces. There may be several values specified for a given key. The key is always the first block of text on a line. A brief description of the example model.txt file
The above example model file, specifies a simulation that has two molecule types and one coordinator type.
Each molecule of type “1” has a label of “a”, has some specified color, is drawn as a sphere, can detect neighboring molecules within a 5 unit radius and can be coordinated by some coordinator type 3 on channel 1. These ideas are encoded by the lines
id 1 label a color .81 .60 .21 shape Sphere 1 neighborhood-size 5 coordinator 1 3
The simulation begins with 10 instances of this molecule type distributed randomly throughout some specified spherical volume. This is encoded by the line:
instantiate 10 random spherical volume 10 30 10 10
The second molecule type has a label of “b”, is also drawn as a sphere with a different color. The simulation begins with only four instances of this molecule type that are also distributed in a spherical volume at a separate location in the simulation. Both molecules a and b can be coordinated by coordinator type 3 on channel 1 (as specified in the line):
coordinator 1 3
for both molecule a and b.
There is only one type of coordinator in this simulation. It has an id of 3 and is labeled “a-b-complex”. The simulation does not begin with any instances of this coordinator type. Instead, an instance of this coordinator type will be created once an instance of molecule “a” and an instance of molecule “b” diffuse within one another’s “neighborhood distance” during the simulation. The coordinator will then appear between the two molecules as a cube. The coordinator has two molecule type members (each with a stoichiometry of 1) as indicated by the lines:
molecule 1 1 molecule 2 1
Once the two molecules become a part of this coordinator, they will move towards the coordinator (at some position between where the two molecules started) and remain there.
A screen shot of the resulting simulation is shown below in the Figure below. The remainder of this section of the manual shows exactly how molecule and coordinator types can be specified.
Screen shot of a simulation resulting from the example model.txt file
Insert screen shot here
Describing molecule types
An example molecule type description is given below in Figure 3. Each of the key-value entry lines are described in a separate section below. For each key-value pair, a format is given. Square brackets indicate types of values that must are to be inserted into the line by the user (i.e., either a float (like 0.1), an integer (like 200) or a string value (like myComplex).
An example molecule type description
[moleculeType] id 1 label molecule_a color .81 .60 .21 shape Sphere 1 draw-as-point 0 opacity 1 show-neighbor-lines 0 neighborhood-size 5 dynamic-neighborhood-sizing 0 feature 234 Tyr234 feature-state 234 0 unphosphorylated feature-state 234 1 phosphorylated coordinator 1 3 resident-compartment-type 4 instantiate 10 random spherical volume 10 30 10 10 [/moleculeType]
Molecule parameters
| id | |
| key | id |
| format | id [integer] |
| description | A unique identifier for this molecule type |
| required | yes |
| default value | not applicable |
| example | id 1 |
Notes: id is usually the first key-value pair specified for a moleculeType. This id is used to refer to this molecule type in other key-value pairs of the model file.
| label | |
| key | label |
| format | label [string] |
| description | A label for the molecule type. |
| required | no |
| default value | molecule |
| example | label molecule_a |
Notes: The label line allows the user to give a name to all molecules of this molecule type. The name will not appear during the simulation unless show-label is set to TRUE (see below). Including spaces in a molecule type name will truncate the name at the space.
| show-label | |
| key | show-label |
| format | show-label [1 or 0] |
| description | Boolean to determine if label should be shown. |
| required | no |
| default value | 0 |
| example | show-label 1 |
Notes: See label (above). All other values besides “1” will be interpreted as FALSE.
| color | |
| key | color |
| format | color [0…1] [0…1] [0…1] |
| description | A description of the color used to draw this molecule type. |
| required | no |
| default value | some randomly chosen color |
| example | color .81 .60 .21 |
Notes: A color may be specified by the user for drawing molecules of this molecule type.
| shape | |
| key | shape |
| format | shape Sphere [float] [float] |
| or | |
| shape Cube [float] [float] [float] | |
| description | A description of the shape used to draw this molecule type. |
| required | no |
| default value | Sphere 1.0 |
| example | shape Sphere 0.5 |
| example | shape Sphere 0.5 2 |
| example | shape Cube 1.0 2.0 3.5 |
Notes:
Two shapes may be used to draw a molecule, a sphere or a cube.
If a Sphere is chosen, at least one additional float value must be given to specify the radius of the sphere. A second, optional float value may be given to specify the “effective radius” of the molecule. “Effective radius” is used to maintain distances between “molecules” that act as compartment markers. Compartment markers are used in place of representing all of the molecules that are really present in a membrane. They can be thought of as representing a single molecule at the center of a circular collection of molecules where the radius of the circle is the “effective radius”. Compartment markers will maintain a distance from one another equivalent to (er1 + er2) where er1 and er2 are the effective radii of compartment markers 1 and 2. Other molecules (non compartment markers) will maintain a distance from compartment markers of (r1 + r2) where r1 and r2 are the radii of the compartment marker and the molecule respectively. A second float value must be specified after the shape key in order for the molecule to behave as a compartment marker.
| draw-as-point | |
| key | draw-as-point |
| format | draw-as-point [1 or 0] |
| description | A Boolean flag indicating that the molecule is to be drawn as a point. |
| required | no |
| default value | draw-as-point 0 |
| example | draw-as-point 1 |
Notes: If draw–as-point is set to 1 (TRUE) then the molecule will appear in the simulation as a point. The radius and effective radius will still be as specified in the shape line. This flag is used to speed up the simulation by reducing the amount of required rendering. It may also be used to hide molecule types that are not of interest to the user. Values other than 1 are interpreted as 0 (FALSE).
