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e2helixboxer.py is used to select rectangular 2D projections of helices from a micrograph, and extract overlapping particles from the boxed helices. e2helixboxer.py is used to select rectangular 2D projections of helices from a micrograph, and extract overlapping particles from the boxed helices. The boxing must be done in GUI mode, but extracting particles from boxed regions may be done from the GUI or from the command line.

{{attachment:e2helixboxer_diagram.png}}
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The left window is the helix viewer, the middle is the micrograph viewer, and the right is the main window.
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The main window shows a list of open micrographs and how many helices you have boxed in each one. (Actually, only one micrograph is loaded in memory at a time, but this allows for quick switching between particles.) Any micrographs you specified after the "--gui" option will be listed.
||||<tablewidth="471px" tableheight="212px"style="text-align: center;">Box Editing ||
||Draw box ||Left click and drag ||
||Move box ||Left click near box center and drag ||
||Move one box endpoint ||Left click near box end and drag ||
||Delete box ||Hold shift and left click inside box ||




After you have boxed the helices in a micrograph, you can go to "File->Save" to save the coordinates and image data of the helices and the particles you extract from them.

{{attachment:e2helixboxer_write_dialog.png}}

A. Write Helices checkbox:

 . Helices are the rectangles that you boxed. You can save their

 . 1. Coordinates to text file using the EMAN1 file format, but with a default *.txt file extension.
 . {{{
x1-w/2 y1-w/2 w w -1
x2-w/2 y2-w/2 w w -2
...
}}}

 . where (x1, y1) and (x2, y2) are the coordinates on the micrograph for the helical axis endpoints, and w is the width of the helix boxes.

 . 2. Helix image data to image files

B. Write Particles checkbox:

 . 1. Overlap: Distance in pixels that two adjacent particles overlap along the line connecting their centroids. Default: 90% of particle length

 . 2. Length: Distance between the centroids of two adjacent particles. Default: same as helix width

 . 3. Width: Width of particles in pixels. Default: same as helix width

 . 4. Write particle coordinates: For each helix, save the coordinates for the midpoint of each particle in that helix.

 . 5. Write Particle images: Save the image data for each particle in each helix. All the particles in a helix will go in a stack file if the file type supports stacks.

  . a. Normalize edge-mean: Apply the "normalize.edgemean" processor to each particle before saving.

  . b. Use unrotated particle: The particles will squares with horizontal and vertical sides. The length of a side of the square will be the maximum of the chosen particle width and particle height. The distance between the centroids of two adjacent particles will still equal the particle length, and the overlap will be measured along that line joining their midpoints.

{{attachment:e2helixboxer_unrotated_ptcl_diagram.png}}
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In command-line mode, you can only work with one micrograph at a time. Before using it, helices must be boxed in the GUI mode or imported from a formatted text file. In either case, the helix-box coordinates will be saved in the EMAN2 database.

Note: As in the EMAN2 convention, data is saved automatically in a database in the current working directory as you use the program. To access this data again, start programs in this same directory the next time.

{{{
e2helixboxer.py <options (not --gui)> <micrograph>
}}}

=== Importing Helix Coordinates ===

If you have coordinates for the helices that are not saved in the EMAN2 embedded database, perhaps because you did the boxing in another program, you must first import them to the embedded database before you can use e2helixboxer to generate particle sets.

 --db-add-hcoords=DB_ADD_HCOORDS:: Adds helix coordinates to the database from the specified file (in EMAN1 *.box format)
{{{
x1-w/2 y1-w/2 w w -1
x2-w/2 y2-w/2 w w -2
...
}}}

 --db-set-hcoords=DB_SET_HCOORDS:: Replaces the helix coordinates in the database with the coordinates from the specified file (in EMAN1 *.box format)

 -w HELIX_WIDTH, --helix-width=HELIX_WIDTH:: Helix width in pixels. Overrides the width in coordinates file.

Examples:
{{{
e2helixboxer.py --db-add-hcoords=coordinates.txt --helix-width=210 micrograph_03.hdf
e2helixboxer.py --db-set-hcoords=newcoordinates.txt -w 200
}}}


=== Exporting Helix Data ===
If you want to work with the helices in programs not included with EMAN2, you may want to save the helix coordinates or helix image data.

 -X HELIX_COORDS, --helix-coords=HELIX_COORDS:: Save coordinates for helices to the file specified, which will have the EMAN1 *.box format.
{{{
x1-w/2 y1-w/2 w w -1
x2-w/2 y2-w/2 w w -2
...
}}}

 -x HELIX_IMAGES, --helix-images=HELIX_IMAGES:: Save images of the helices. The file name specified will have helix numbers added to it.

 -w HELIX_WIDTH, --helix-width=HELIX_WIDTH:: Helix width in pixels
 
Examples:
{{{
e2helixboxer.py --helix-coords=hcoords.txt --helix-images=micrograph2_helices.hdf -w 215 micrograph2.mrc
e2helixboxer.py -X hcoords.txt -x helix.hdf --helix-width=210 micrograph.mrc
}}}

=== Exporting Particle Data ===
Once helices have been boxed using the e2helixboxer.py GUI, or boxed with another program and the coordinates imported, the next step is to save particle data. This can be done with the "Save" dialog in the GUI or with command-line options. See the GUI documentation above for how particles are generated and what the parameters mean. Particle coordinates can be saved to a special text file, but usually, you will save particle image stacks, which will be used to create class averages.

==== Particle Output Files ====

 -P PTCL_COORDS, --ptcl-coords=PTCL_COORDS:: Save coordinates of the centers of particles to the specified formatted text file

 -p PTCL_IMAGES, --ptcl-images=PTCL_IMAGES:: Save images of the particles. The file name specified will have helix numbers (and particle numbers if the file type does not support image stacks) added to it.

==== Particle generation parameters ====

 --ptcl-overlap=PTCL_OVERLAP:: Particle overlap in pixels

 --ptcl-length=PTCL_LENGTH:: Particle length in pixels

 --ptcl-width=PTCL_WIDTH:: Particle width in pixels

 --ptcl-not-rotated:: Particles are oriented as on the micrograph. They are square with length max(ptcl_length, ptcl_width).

 --ptcl-norm-edge-mean:: Apply the normalize.edgemean processor to each particle.

 --gridding:: Use a gridding method for rotation operations on particles. Requires particles to be square.
 
==== Particle Saving Examples ====

 * Saving rotated particles.
{{{
e2helixboxer.py --ptcl-images=micrograph32_particles.hdf --ptcl-length=100 --ptcl-overlap=90 micrograph32.mrc
e2helixboxer.py --gridding -p micrograph32_particles --ptcl-length=120 --ptcl-width=120 --ptcl-overlap=90 micrograph32.mrc
}}}
If some or all of the parameters, --ptcl-length, --ptcl-width, --ptcl-overlap are not specified, default values are chosen in this order.
 1. If particle width is not specified, it is set to be the same as helix width.
 2. If particle length is not specified, it is set to be the same as particle width.
 3. If particle overlap is not specified, it is set to be 90% of particle length.
Note that if the --gridding option is chosen, particles must be square.

 * Saving unrotated particles (to be rotated later with other software)
{{{
e2helixboxer.py --ptcl-not-rotated --ptcl-image=micrograph32_particles.hdf --ptcl-width=100 --ptcl-overlap=90 micrograph32.mrc
}}}
Unrotated particles are always square.
 1. If particle length and width are specified, the sides of the particles are set to the maximum of the two.
 2. If neither particle length nor particle width are specified, the sides of the particle are set to the width of the helix.
 3. If one of particle length and particle width are specified, the sides of the particles are set to that value.
 2. If

e2helixboxer.py: Overview

e2helixboxer.py is used to select rectangular 2D projections of helices from a micrograph, and extract overlapping particles from the boxed helices. The boxing must be done in GUI mode, but extracting particles from boxed regions may be done from the GUI or from the command line.

e2helixboxer_diagram.png

GUI mode

To start the program's graphic user interface, use the "--gui" option. You can follow this with a micrograph filename, a list of micrograph filenames, or nothing.

$ e2helixboxer.py --gui <micrograph1> <micrograph2> <...>

$ e2helixboxer.py --gui
$ e2helixboxer.py --gui 101.mrc
$ e2helixboxer.py --gui *.mrc micrograph.hdf *.img abc.dm3

The left window is the helix viewer, the middle is the micrograph viewer, and the right is the main window.

e2helixboxer.png

The main window shows a list of open micrographs and how many helices you have boxed in each one. (Actually, only one micrograph is loaded in memory at a time, but this allows for quick switching between particles.) Any micrographs you specified after the "--gui" option will be listed.

Box Editing

Draw box

Left click and drag

Move box

Left click near box center and drag

Move one box endpoint

Left click near box end and drag

Delete box

Hold shift and left click inside box

After you have boxed the helices in a micrograph, you can go to "File->Save" to save the coordinates and image data of the helices and the particles you extract from them.

e2helixboxer_write_dialog.png

A. Write Helices checkbox:

  • Helices are the rectangles that you boxed. You can save their
  • 1. Coordinates to text file using the EMAN1 file format, but with a default *.txt file extension.
  • x1-w/2           y1-w/2           w           w           -1
    x2-w/2           y2-w/2           w           w           -2
    ...
  • where (x1, y1) and (x2, y2) are the coordinates on the micrograph for the helical axis endpoints, and w is the width of the helix boxes.
  • 2. Helix image data to image files

B. Write Particles checkbox:

  • 1. Overlap: Distance in pixels that two adjacent particles overlap along the line connecting their centroids. Default: 90% of particle length
  • 2. Length: Distance between the centroids of two adjacent particles. Default: same as helix width
  • 3. Width: Width of particles in pixels. Default: same as helix width
  • 4. Write particle coordinates: For each helix, save the coordinates for the midpoint of each particle in that helix.
  • 5. Write Particle images: Save the image data for each particle in each helix. All the particles in a helix will go in a stack file if the file type supports stacks.
    • a. Normalize edge-mean: Apply the "normalize.edgemean" processor to each particle before saving.
    • b. Use unrotated particle: The particles will squares with horizontal and vertical sides. The length of a side of the square will be the maximum of the chosen particle width and particle height. The distance between the centroids of two adjacent particles will still equal the particle length, and the overlap will be measured along that line joining their midpoints.

e2helixboxer_unrotated_ptcl_diagram.png

Command-line mode

In command-line mode, you can only work with one micrograph at a time. Before using it, helices must be boxed in the GUI mode or imported from a formatted text file. In either case, the helix-box coordinates will be saved in the EMAN2 database.

Note: As in the EMAN2 convention, data is saved automatically in a database in the current working directory as you use the program. To access this data again, start programs in this same directory the next time.

e2helixboxer.py <options (not --gui)> <micrograph>

Importing Helix Coordinates

If you have coordinates for the helices that are not saved in the EMAN2 embedded database, perhaps because you did the boxing in another program, you must first import them to the embedded database before you can use e2helixboxer to generate particle sets.

--db-add-hcoords=DB_ADD_HCOORDS
Adds helix coordinates to the database from the specified file (in EMAN1 *.box format)

x1-w/2           y1-w/2           w           w           -1
x2-w/2           y2-w/2           w           w           -2
...
--db-set-hcoords=DB_SET_HCOORDS
Replaces the helix coordinates in the database with the coordinates from the specified file (in EMAN1 *.box format)
-w HELIX_WIDTH, --helix-width=HELIX_WIDTH
Helix width in pixels. Overrides the width in coordinates file.

Examples:

e2helixboxer.py --db-add-hcoords=coordinates.txt --helix-width=210 micrograph_03.hdf
e2helixboxer.py --db-set-hcoords=newcoordinates.txt -w 200

Exporting Helix Data

If you want to work with the helices in programs not included with EMAN2, you may want to save the helix coordinates or helix image data.

-X HELIX_COORDS, --helix-coords=HELIX_COORDS
Save coordinates for helices to the file specified, which will have the EMAN1 *.box format.

x1-w/2           y1-w/2           w           w           -1
x2-w/2           y2-w/2           w           w           -2
...
-x HELIX_IMAGES, --helix-images=HELIX_IMAGES
Save images of the helices. The file name specified will have helix numbers added to it.
-w HELIX_WIDTH, --helix-width=HELIX_WIDTH
Helix width in pixels

Examples:

e2helixboxer.py --helix-coords=hcoords.txt --helix-images=micrograph2_helices.hdf -w 215 micrograph2.mrc
e2helixboxer.py -X hcoords.txt -x helix.hdf --helix-width=210 micrograph.mrc

Exporting Particle Data

Once helices have been boxed using the e2helixboxer.py GUI, or boxed with another program and the coordinates imported, the next step is to save particle data. This can be done with the "Save" dialog in the GUI or with command-line options. See the GUI documentation above for how particles are generated and what the parameters mean. Particle coordinates can be saved to a special text file, but usually, you will save particle image stacks, which will be used to create class averages.

Particle Output Files

-P PTCL_COORDS, --ptcl-coords=PTCL_COORDS
Save coordinates of the centers of particles to the specified formatted text file
-p PTCL_IMAGES, --ptcl-images=PTCL_IMAGES
Save images of the particles. The file name specified will have helix numbers (and particle numbers if the file type does not support image stacks) added to it.

Particle generation parameters

--ptcl-overlap=PTCL_OVERLAP
Particle overlap in pixels
--ptcl-length=PTCL_LENGTH
Particle length in pixels
--ptcl-width=PTCL_WIDTH
Particle width in pixels
--ptcl-not-rotated
Particles are oriented as on the micrograph. They are square with length max(ptcl_length, ptcl_width).
--ptcl-norm-edge-mean
Apply the normalize.edgemean processor to each particle.
--gridding
Use a gridding method for rotation operations on particles. Requires particles to be square.

Particle Saving Examples

  • Saving rotated particles.

e2helixboxer.py --ptcl-images=micrograph32_particles.hdf --ptcl-length=100 --ptcl-overlap=90 micrograph32.mrc 
e2helixboxer.py --gridding -p micrograph32_particles --ptcl-length=120 --ptcl-width=120 --ptcl-overlap=90 micrograph32.mrc

If some or all of the parameters, --ptcl-length, --ptcl-width, --ptcl-overlap are not specified, default values are chosen in this order.

  1. If particle width is not specified, it is set to be the same as helix width.
  2. If particle length is not specified, it is set to be the same as particle width.
  3. If particle overlap is not specified, it is set to be 90% of particle length.

Note that if the --gridding option is chosen, particles must be square.

  • Saving unrotated particles (to be rotated later with other software)

e2helixboxer.py --ptcl-not-rotated --ptcl-image=micrograph32_particles.hdf --ptcl-width=100 --ptcl-overlap=90 micrograph32.mrc

Unrotated particles are always square.

  1. If particle length and width are specified, the sides of the particles are set to the maximum of the two.
  2. If neither particle length nor particle width are specified, the sides of the particle are set to the width of the helix.
  3. If one of particle length and particle width are specified, the sides of the particles are set to that value.
  4. If

EMAN2/Programs/e2helixboxer (last edited 2011-10-13 22:12:20 by RossColeman)