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| My name is Jason Vertrees and I'm a postdoc in computational biology. Currently, I study proteins through mathematical models & machine learning. My previous work was in theoretical biophysics. | | My name is Jason Vertrees and I'm an independent consultant working with DeLano Scientific to promote PyMOL. My previous work was in theoretical biophysics and machine learning to predict properties of proteins. |
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| Also, I am the owner and of the PyMOLWiki website. | | Also, I am the owner of the PyMOLWiki website. I started it to help the PyMOL community store and organize information regarding PyMOL. |
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| If you are interested in Biophysical, Structural or Compuational Biology, check out [http://www.bscb.utmb.edu/ BSCB@UTMB] -- my old school. | | If you are interested in Biophysical, Structural or Compuational Biology, check out [http://www.bscb.utmb.edu/ BSCB@UTMB] -- my old school. |
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| | | -- '''Jason Vertrees, PhD <br/> |
| '''Jason Vertrees, PhD | | ''Jason dot Vertrees (_at-) gmail dot com'' |
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| ''jv(_at-)cs_dot_dartmouth(dot2)edu'' | |
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| [http://www.cs.dartmouth.edu/~jv/ My Page]
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| = My ~/.pymolrc = | | = My ~/.pymolrc = |
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| set ray_opaque_background,0 | | set ray_opaque_background,0 |
| set defer_builds_mode, 3 | | set defer_builds_mode, 3 |
| | set async_builds, 1 |
| </source> | | </source> |
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| == To Do == | | == To Do == |
| * texture_fonts, 1 -- for speed
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| * pseudo-atoms; you can label them. RightClick->New->PAtom->and then label it; move the atom (and the label goes w/it). You can also move the label by itself
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| * movie_panel
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| * mset - clears the movie
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| * Movie->UpdateMovie | | * Movie->UpdateMovie |
| * Scene->Buttons (shows buttons for each scene)
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| * Scene->Optmize (before saving scenes; use before optimizing) | | * Scene->Optmize (before saving scenes; use before optimizing) |
| * Scene->Cache (cache's surface data) | | * Scene->Cache (cache's surface data) |
| * A good way to make movies seems to be:
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| ** madd
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| ** prepare a scene; turn on scene buttons
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| ** Fn+CTRL+down-arrow # adds the scene;
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| ** madd 1 x90
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| ** mview store, -1
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| * repeat
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| * when done do mview reinterpolate
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| * play the movie
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| * matrix_mode
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| * dot_solvent | | * dot_solvent |
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| = Movie Making =
| | New motions |
| While PyMOL's capability to produce static images is quite powerful, there are some stories that are better told through movies, than static images alone. This little page will provide the necessary ideas, links, code and examples for making movies in PyMOL.
| | * Enter alone will store+reinterpolate |
| | | * Shift-Enter will just store & clears the reinterpolation |
| == Your First Movie ==
| | * CTRL-Enter will store but not reinterpolate |
| Movies can be very simple, for example, animating an NMR ensemble:
| |
| <source lang="python">
| |
| # Your first movie.
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| fetch 1nmr
| |
| mplay
| |
| | |
| # to stop the movie when you're ready
| |
| # type 'mstop'.
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| </source>
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|
| What PyMOL did here was to [[fetch]] the file from the PDB and load it into an object with 20 states. Somewhere between then and issuing [[mplay]] PyMOL created 20 frames for your object and assigned one state to each frame. This created the animated effect as we scroll through the frames.
| | New Scenes |
| | * setups the scenes first |
| | * then just goto the frame you want and hit enter and the current will be stored with it |
| | * or you can right-click on the movie_panel and store with scene |
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| | * purge kills the matrix info for the object |
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| == Terminology ==
| |
| Imagine a complex movie for a moment, a movie that has camera motions, objects moving independently or in concert with other objects, changing colors and representations. To handle camera motions PyMOL must know at all times where the camera is located and what it's pointed toward (as well as clipping planes). For objects to move around or be rotated without regard to the camera (the objects themselves rotate/translate, not just the camera), PyMOL has to store the coordinates and matrices for these objects, too. Changing colors and representations for each object must somehow also be stored. So, as you can see this is a multidimensional problem: at each time point in your movie, PyMOL must remember positions and representations, as well as make it easy for you to transition between them (interpolation).
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| Despite these complexities, PyMOL tries to enable movie making for even novice users. Let's start by defining a few PyMOL concepts—states, frames and scenes.
| | New movie stuff |
| | * CTRL-LEFTCLK + DRAG RIGHT = add frame/states |
| | * CTRL-LEFTCLK + DRAG LEFT = erase frame/states |
| | * Rt clk on object |
| | ** Shift+Middle = drag |
| | ** shift+Left = rotate |
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| |
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| === Basic Movie Terminology === | | = Cool Movies = |
| '''object'''
| | * [[File:Traj_movie.mpg]] — MD Trajectory made awesome with PyMOL; 5 MB mpg file. |
| ::An object is any PyMOL-object loaded into PyMOL, like atoms, molecules, complexes, etc. When you load an PDB from disk/net it is loaded into PyMOL as an object. | | * [[File:Long_movie_ray.mpg]] — long movie, shows dimerization, roams around the active site, 6 MB. |
| :: [[:Category:Objects|All pages regarding objects]]
| | * [[File:Motions_movie.mpg]] — a simple movie with motions. |
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| '''selection'''
| | = tRNA hairball = |
| :: A selection is a specifically chosen set of atoms, molecules, complexes etc. in PyMOL. A selection is not an object, it's a subset of stuff from a (collection of) object(s). Selections can be named and when named have are distinguished from objects by having parentheses around their names. For example, ''foo'' would be an object and ''(foo)'' would be some selection. When you pick an atom (and get the default '''(sele)''' selection) or issue the ever-popular [[Select]]ion command, you get a selection.
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| :: [[:Category:Selections|All pages regarding selections]]
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| | |
| '''states'''
| |
| :: A state is a particular conformation (set of coordinates) for a given object. For example an NMR ensemble could contain the same molecule, but in 20 different states. PyMOL can make movies from states. States '''do not store representations''' in PyMOL (eg. cartoons vs. sticks).
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| :: See also [[:Category:States|All pages regarding states]]
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| | |
| '''scenes'''
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| '''interpolation'''
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| :: A scene is the staged representations of objects and the orientation of the camera.
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| :: See also [[:Category:Scenes|All pages regarding scenes]]
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| | |
| '''frames'''
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| :: A frame can be thought of as a single frame in a movie reel. A frame stores state information and scene information.
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| :: See also [[:Category:Frames|All pages regarding frames]]
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| | |
| '''Movie Panel'''
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| :: The movie panel is a frame indicator strip at the bottom of the screen. It shows a little icon for which frame you're currently on, and whether or not the camera has been set for that frame.
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| :: See [[movie_panel]] for more information.
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| | |
| == What is a Movie? == | |
| Now the we have the appropriate terminology to talk about movies in PyMOL, we can discuss what a movie really is. A movie in PyMOL is a series of frames stitched together in some way so as to create the desired animation. Once a movie is made in PyMOL, we have a few options for exporting it to other formats like png arrays or MPEG moves.
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| | |
| == Movie Making Commands ==
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| This tutorial assumes you have some basic knowledge about how to use PyMOL (eg. mousing, choosing and setting your representations, etc). If you're not yet at this level, please check out [[:Category:Tutorials|the Tutorial Category]] of pages (most notably the beginner tutorials).
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| | |
| I think it's help to think of the movie as a set of frames, like in a movie reel, so let's start there. (Each command below links to the command's PyMOL wiki page, so feel free to click through for more info.)
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| | |
| === [[frame]]===
| |
| This command tells PyMOL to set the current frame to whichever you desire. To use it, just issue the command, <source lang="python">frame X</source> where '''X''' is some integer number indicating the frame you want to go to. If you issue a frame number greater than the number of frames, PyMOL sets the frame to the highest-numbered frame you have (similarly for negative numbers or numbers smaller than the minimum numbered frame).
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| | |
| Let's try a quick example with [[frame]],
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| <source lang="python"> | | <source lang="python"> |
| # create an empty 90 frame movie
| | reinit |
| mset 1 x90
| | unset movie_auto_interpolate |
| # turn on the movie panel (bottom of screen) | | # position molecule & view |
| set movie_panel, on
| | fetch 1yfg, trna, async=0 |
| # goto frame one
| | orient |
| frame 1
| | rotate z, 60, trna |
| # try some intermediate frames; notice the blue indicator in the movie panel
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| frame 10
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| frame 50
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| frame 90
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| # try going beyond the end and see what PyMOL does
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| frame -1
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| frame 100
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| # play through the empty movie
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| mplay
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| # stop the movie
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| mstop
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| </source>
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|
| | python |
| | for x in range(6): |
| | n = "trna_%s" % x |
| | cmd.create( n, "trna", 1, 1) |
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| === [[States|set state]] ===
| | cmd.disable("trna") |
| Again, states are particular stored conformations of objects. Here we use PyMOL to set and get the states, and see how PyMOL mapped them to our earlier movie example.
| | cmd.translate( [0, -60, 0], "trna" ) |
| | | cmd.origin("trna") |
| This command has a similar idea of [[frame]], but works a little differently. Instead of typing,
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| <source lang="python">
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| # invalid command
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| state 40
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| </source>
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| in PyMOL we [[set]] the [[States|state]]:
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| <source lang="python">
| |
| # how to set a state in PyMOL
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| set state, stateNo, objectName
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|
| |
|
| # for example
| | for x in range(6): |
| # set state to 40
| | n = "trna_%s" % x |
| set state, 40
| | cmd.rotate( "z", 60. * x, n) |
| | | cmd.show_as("cartoon", n) |
| # also, get state
| | cmd.origin("trna") |
| get state
| | cmd.zoom() |
| </source>
| |
| | |
| ==== States & Frames (optional reading) ====
| |
| As an example, look at the code from the "first movie":
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| <source lang="python">
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| fetch 1nmr
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| mplay
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| # issue mstop, to stop the movie
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| </source>
| |
| | |
| We can do a couple things now, let's try counting the number of states and frames PyMOL now knows about:
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| <source lang="python">
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| # how many frames does PyMOL know about?
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| count_frames
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| | |
| # what about states?
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| count_states
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| </source>
| |
| | |
| and now let's see how PyMOL mapped frames to states. Using the above commands and a little Python, let's see how PyMOL mapped the frames to states:
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| <source lang="python">
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| python
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| for x in range(1,cmd.count_frames()+1):
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| cmd.frame(x) | |
| print "Frame => %s; and State => %s" % ( str(x), str(cmd.get('state'))) | |
| python end | | python end |
| </source>
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| which should show a 1-1 mapping of states to frames.
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|
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| === [[mset]] ===
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| [[mset]] is a very powerful command. This command tells PyMOL how to assign states to frames. So, now you see why it's necessary to clearly distinguish between and use the two. Let's learn how to use [[mset]].
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|
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| The syntax for [[mset]] can be a little tricky at first. I would write the syntax as:
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| <source lang="python">
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| mset stateSpec frameSpec
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| </source>
| |
| which assigns the states in '''stateSpec''' to the frames in '''frameSpec'''., where '''stateSpec''' is any mset-valid state specification. PyMOl supports to patterns for '''stateSpec'''. You can do simply supply a number eg
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| <source lang="python">
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| mset 1
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| </source>
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| or you can specify a range of states—like 1 through 55 as
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| <source lang="python">
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| # setting states 1 through 55
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| # caution: notice the space: 1 -55, not 1-55 (this is a PyMOL parser caveat)
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| mset 1 -55
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| </source>
| |
| Simple enough. Now for '''frameSpec''' you can specify a single frame number like so or you can specify ''how many frames PyMOL should use to map to your specified states'' with the '''xNumber''' command. This will make sense with an example
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| <source lang="python">
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| # Recall: mset stateSpec frameSpec
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| # so we are setting STATE 1 across a span of 90 frames
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| mset 1 x90
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|
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| # Recall: mset stateSpec frameSpec
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| # so we are setting states 1..120 to the next 120 frames
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| mset 1 -120 x120
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| </source>
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|
| |
| NB: Actually the syntax is a little more complicated than this as PyMOL's mset command has the ability to remember in which frame the prior specification left the movie. So, you can sort of chain the specifications. Type ''help mset'' in PyMOL for more info or see [[mset]].
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| === [[mview]] ===
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| The [[mview]] command can be intimidating, but all we need to know about it at present is that it can store the (1) camera position or (2) a given object position. The idea is to essentially make 'way points' in your movie and have PyMOL interpolate the in-between positions/coordinates, etc. For example, if I wanted to make a 100-frame movie of a zoom into an object, I could store and manually set 100 camera positions, or I could do the starting position and the final position and ask PyMOL to just interpolate that over 100 frames. The latter idea is obviously much simpler. So simple in fact, let's make a super-quick movie that does exactly what I just mentioned—100 frames of a slow zoom into some object. Start with a fresh PyMOL session ([[reinitialize]]) and then copy/paste the following:
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| <source lang="python" line=1>
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| # let's initialize the movie to 100 frames, all of state 1
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| # it's ONLY state 1, because we're only moving the camera around, not
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| # changing structure coordinates of the leucine:
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| mset 1 x100
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|
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|
| # show a leucine
| | mset 1x360 |
| frag leu
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|
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| # position the residue
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| orient
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|
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| # let's store the current camera position
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| mview store
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|
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| # now set our way point to be frame 100
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| frame 100
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|
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| # now let's zoom into some atom on the fragment
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| zoom ID 10
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|
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| # now save this view at frame 100
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| mview store
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|
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| # last thing is to tell PyMOL to interpolate the 100 frame zoom
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| # so we don't have to do those 100 snapshots:
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| mview reinterpolate
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|
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| # voila, you have a movie. To watch it go back to frame 1 and play it
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| frame 1
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| mplay
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|
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| # mstop when you're ready
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| </source>
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|
| |
| 'But, hold on!' you might say. Why is it so herky-jerky? We have smooth zooming but then a snap and back to frame one! Well, we never gave PyMOL any number of frames to interpolate the change from frame 100 back to frame 1 (since it wraps). If we wanted an a '''zoom in''' that was equally as fast as the '''zoom out''' we would simply '''replace line #16''' with
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| <source lang="python">
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| # now set our way point to be frame 100
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| frame 100
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| </source>
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| but, if we wanted a slow, zoom in and a ''fast'' zoom out we could do
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| <source lang="python">
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| # now set our way point to be frame 100
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| frame 80
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| </source>
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| instead which would only give PyMOL 20 frames with which to zoom us out. Try it!
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|
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| ==== Very Basic Mview Syntax ====
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| ''This is a simple overview, see [[mview]] for complete details.''
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|
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| Using [[mview]] as you can see from above is pretty simple. The very basic syntax is:
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| <source lang="python">
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| # store the camera OR some object given by objName (if it's supplied)
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| mview store[, object=objName]
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|
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| # reinterpolate (link together the positions) for the saved camera or object
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| mview reinterpolate[, object=objName]
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| </source>
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| If you leave off the '''object=objName''' then you're storing the '''camera information only'''—and so none of your objects will be moving anywhere—just the camera. If you include an object name, then it stores that object's position information in the current frame. The '''mview store''' tells PyMOL to store the camera or objects coordinates, while the '''mview reinterpolate''' command tells PyMOL to link together the saved positions for the camera or the selected object in a smooth, cool way.
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|
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| == Simple Movie Examples ==
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| We now the ability to make some pretty simple, but cool movies. So, let's try a few.
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|
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| === Multiple Zooming ===
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| Let's try making a movie where we zoom into each ligand that's not water. In order to make this movie, I had to find a protein with suitable ligands, so you can do the same for your own protein. Just replace the hard-coded residue numbers.
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|
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| '''Goal:''' Make a movie that zoom into the three ligands, stays on that ligand for 2 seconds, then moves to the next. I also want smooth zoom out at the end. Don't let the length of this movie script throw you off, you've seen all of the movie commands and the initial commands are just loading the and making it look good.
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| <source lang="python">
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| # setup PyMOL for the movie
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| reinitialize
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| set matrix_mode, 1
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| set movie_panel, 1
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|
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| # load the PDB, make selections for the ligands and
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| # make the protein look snazzy.
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| #load /spc/pdb/2jep.pdb
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| fetch 2jep, asyn=0
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| remove resn HOH
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| orient
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| select l1, c. A and i. 1397
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| select l2, c. A and i. 1396
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| select l3, c. B and i. 1396
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| as cartoon
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| color grey
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| show sticks, het
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| color magnesium, het
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|
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| # At 30 FPS this is then a 16 second movie.
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| # We look at the structure for 2 seconds, zoom in to each ligand
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| # and look at it for another 2 seconds, then, zoom out and look again
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| # at everything for another 2 seconds.
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|
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| # initialize the 480 frame movie
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| mset 1 x480
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|
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| # zoom all ('scene #1')
| |
| frame 1 | | frame 1 |
| mview store
| | orient vis |
| # stay here for 2 seconds
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| frame 60
| |
| mview store | | mview store |
|
| |
|
| # zoom on ligand 1 ('scene #2')
| | rots = [ [0., 1., 0.], [-1.4, 1., 0], [-1.4, -1., 0.], [0., 1., 0.], [-1.4, 1., 0.], [1.4, 1., 0.] ] |
| frame 120
| | ang = [120,240,360] |
| zoom l1
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| mview store
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| # stay here for 2 seconds
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| frame 180
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| mview store
| |
| | |
| # zoom on ligand 2 ('scene #3')
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| frame 240
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| zoom l2
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| mview store
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| # stay for 2 seconds
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| frame 300
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| mview store
| |
| | |
| # zoom to ligand 3 ('scene #4')
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| frame 360
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| zoom l3
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| mview store
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| # stay for 2 seconds
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| frame 420
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| mview store
| |
| | |
| # zoom out ('back to scene #1')
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| frame 480
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| zoom
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| mview store
| |
| | |
| # interpolate the frames
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| mview reinterpolate
| |
| | |
| # play the awesome movie!
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| mplay
| |
| | |
| # stop when you want
| |
| # mstop
| |
| </source>
| |
| | |
|
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|
| | python |
| | #for f in [120,240,360]: |
| | for f in range(len(ang)): |
| | cmd.frame(ang[f]) |
| | for t in range(6): |
| | cmd.rotate(rots[t], 120, object="trna_%s" % t) |
| | python end |
| | mview interpolate, object=trna_*, power=1 |
|
| |
|
| === Animating an Alignment ===
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| <source lang="python">
| |
| # setup PyMOL for the movie
| |
| reinitialize
| |
| set matrix_mode, 1
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| set movie_panel, 1
| |
|
| |
| # load the PDBs
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| fetch 1cll 1ggz, async=0
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|
| |
| # orient the scene
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| as cartoon
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| orient
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|
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| # make 100-frame movie
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| mset 1 x100
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| # goto frame 1
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| frame 1
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|
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| # store the camera position and object
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| # positions in frame 1
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| mview store
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| mview store, object=1cll
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| mview store, object=1ggz
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|
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| # goto frame 90
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| frame 90
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| # align the two proteins
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| super 1cll, 1ggz
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| # we rezoom to center the camera on the
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| # two aligned proteins
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| zoom
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| # store the camera positions
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| mview store
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| # store the new object position(s)
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| mview store, object=1cll
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| mview store, object=1ggz
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|
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| # have PyMOL stitch together the scenes.
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| mview reinterpolate
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| mview reinterpolate, object=1cll
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| mview reinterpolate, object=1ggz
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|
| |
| # rewind
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| frame 1
| |
| # get some popcorn! :-)
| |
| mplay
| |
| </source>
| |
|
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| === BB Inspector ===
| |
| This movie will walk down the alpha carbons inspecting each one for 1/3 of a second. :-) What would be cool would be to calculate the difference vector from i. n+1 to i. n and then walk that path. Anyhow, here you go:
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|
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| <source lang="python">
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| # usual setup
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| reinitialize
| |
| set matrix_mode, 1
| |
| set movie_panel, 1
| |
|
| |
| # fetch 1CLL to work on; this will only work on 1cll
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| # or any other protein with 144 AAs starting at resi 4.
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| fetch 1cll, async=0
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| as lines, n. C+O+N+CA
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| color marine
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| zoom i. 4+5
| |
|
| |
| # 10 frames per AA
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| mset 1 x1440
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| mview store
| |
|
| |
| # this code maps the zooming of
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| # one AA and it's neighbor to 10 frames
| |
| python | | python |
| for x in range(0,144): | | #for f in [120,240,360]: |
| cmd.zoom( "n. CA and i. " + str(x) + "+" + str(x+1)) | | for f in range(len(ang)): |
| cmd.frame((10*x)+1) | | cmd.frame(ang[f]) |
| cmd.mview("store") | | cmd.turn('y', 120) |
| | cmd.mview(action="store") |
| python end | | python end |
|
| |
|
| # goto the end and interpolate all the frames
| | mview interpolate, power=1 |
| frame 288
| |
| mview store
| |
| mview reinterpolate
| |
| | |
| # I know, it's not smooth & cool like the other ones
| |
| mplay
| |
| </source>
| |
| | |
| == Putting It All Together ==
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| Now that we understand the basic PyMOL commands for movie making, we build a few ideas--which have already been hinted at--that lead to the final goal: allowing you to generate PyMOL movies to tell the stories you want to tell. We start simple and build up the complexity. Here's an outline of the ideas:
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| * '''camera motions'''—just moving the camera around your scene
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| * '''object motions'''—keeping the camera still, but moving the objects around the scene
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| * '''camera & object motions '''—moving both the camera and objects around
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| * '''representations'''—changing representations in a movie (eg. sticks to cartoons to surface; hiding/showing, etc.)
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| * '''motions & representations '''—adding all the motions and representations together
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| * '''extras'''—pseudoatom labels; scene messages, etc.
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| * '''final example movies'''—some examples combining the above knowledge
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| If you've read through most the above article on movie making, then these sections should be more of a review. There are some tricks in here that might be worth reading, however.
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| Many of the movie scripts below assume that you have readied PyMOL for movie generation. To do that use the following code:
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| <source lang="python">
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| reinitialize
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| set matrix_mode, 1
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| set movie_panel, 1
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| set scene_buttons, 1
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| set cache_frames, 1
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| config_mouse three_button_motions, 1
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| # initialize a 100 frame movie
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| mset 1 x100
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| </source>
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| ===Camera Motions===
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| One of our first movies above was a very simple zoom on an atom in an amino acid. The first 'scene' was the entire amino acid and the 2nd 'scene' was the zoomed in atom. We just connected the two scenes and asked PyMOL to make the transition between the two smooth. This is the idea of camera motions in PyMOL. (You may not know that when you click on a protein and rotate it or drag it in PyMOL you're actually moving the camera, not the protein.)
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| Assuming you had readied PyMOL to make your movie to get a camera motion you do the following:
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| * '''save the camera's first position information''': Once you have the protein/object aligned and shown in the representation of your choice, set the '''camera''' position information
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| <source lang="python">
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| # goto the first frame
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| frame 1
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| # store the CAMERA positions ONLY
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| mview store
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| </source>
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| * '''save the cameras second position information''': Now using the mouse (or scripted commands) move the camera to its new position--say zooming in on an important ligand or catalytic residue. Once that's done, tell PyMOL to store the new camera position in this frame:
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| <source lang="python">
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| # goto the first frame
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| frame 88
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| # store the CAMERA positions ONLY
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| mview store
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| # now link the two stored camera positions together:
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| mview reinterpolate
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| # play your movie
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| mplay
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| </source>
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| Hints:
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| * '''mview reinterpolate, power=1" will turn off the smoothed starting and stopping of camera motions between the scenes. The smoothing gives a nicer feel to transitions. Try both, see which you prefer.
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| * check out mview's other options--like 'wrap'
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| * using the three_button_motions option, you can pretty much make the entire movie w/your mouse: All->M->Store is the same as, ''mview store'', and All->M->Reinterpolate is the same as ''mview reinterpolate''.
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| ==== Camera Motions Movie Example ====
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| This idea should be pretty sound at this point, but examples rock, so here's another. The pattern is:
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| * frame XYZ
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| * script the view
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| * mview store
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| <source lang="python">
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| # setup PyMOL for movies
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| reinitialize
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| set matrix_mode, 1
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| set movie_panel, 1
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| set scene_buttons, 1
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| set cache_frames, 1
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| config_mouse three_button_motions, 1
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| fetch 1te1, async=0
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| extract AA, c. A
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| extract BB, c. B
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| color marine, AA
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| color grey, BB
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| as surface, BB
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| as cartoon, AA
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| mset 1 x620
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| orient
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| wizard message, "Can you see the blue protein inhibiting the gray protein?"
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| frame 1
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| mview store
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| frame 30
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| mview store
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| ### cut below here and paste into script ###
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| set_view (\
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| 0.307660401, 0.011366921, 0.951428533,\
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| 0.930296898, -0.213488042, -0.298277378,\
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| 0.199727684, 0.976880252, -0.076255992,\
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| 0.000000000, 0.000000000, -196.781448364,\
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| 27.129878998, 68.309677124, 51.827075958,\
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| 155.143981934, 238.418914795, -20.000000000 )
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| ### cut above here and paste into script ###
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| # slowly show the inhibition
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| frame 120
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| mview store
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| # wait 3 seconds
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| frame 180
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| mview store
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| # define the inhib as the binding loop
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| select inhib, AA and i. 148-155
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| select (none)
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| # slowly zoom in
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| frame 300
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| zoom inhib
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| mview store
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| # stop a second
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| frame 330
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| mview store
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| # look around the binding pocket
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| frame 390
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| turn y, 150
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| mview store
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| # wrap back more quickly...
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| frame 420
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| turn y, -150
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| mview store
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| # one more gratuitous view
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| frame 500
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| ### cut below here and paste into script ###
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| set_view (\
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| 0.943371952, 0.309539229, -0.119302809,\
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| -0.044248745, -0.239008784, -0.970008850,\
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| -0.328769624, 0.920357347, -0.211777285,\
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| 0.000000000, 0.000000000, -30.773454666,\
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| 35.418403625, 72.805625916, 52.437019348,\
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| 20.233829498, 41.313076019, -20.000000000 )
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| ### cut above here and paste into script ###
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| mview store
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| frame 560
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| mview store
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| mview reinterpolate
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| mplay
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| </source>
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| ===Object Motions===
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| Now that we're experts at moving the PyMOL camera around, let's start moving objects around while keeping the camera steady. To do this '''you must have matrix_mode set to 1''', otherwise PyMOL won't save your object's repositioning.
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| Let's use the same proteins as from the above inhibitor example. This time, let's try to get a simple movie that shows one of the proteins and then have the other one fly in to do the inhibiting.
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| <source lang="python">
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| # setup PyMOL for movies
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| reinitialize
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| set matrix_mode, 1
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| set movie_panel, 1
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| set scene_buttons, 1
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| set cache_frames, 1
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| config_mouse three_button_motions, 1
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| # download the complex and setup it up
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| fetch 1te1, async=0
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| extract AA, c. A
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| extract BB, c. B
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| color marine, AA
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| color grey, BB
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| as surface, BB
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| as cartoon, AA
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| # intialize the movie
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| mset 1 x620
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| # orient the scene
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| set_view (\
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| 0.423117876, 0.061672822, 0.903973043,\
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| 0.789699256, -0.514252067, -0.334546506,\
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| 0.444237947, 0.855418444, -0.266292989,\
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| 0.000107866, -0.000027858, -196.784057617,\
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| 28.171787262, 70.919288635, 52.095287323,\
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| 155.143981934, 238.418914795, -20.000000000 )
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| # move the inhibitor off the screeen
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| translate [0,0,100], object=AA
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|
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| # first movie scene
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| frame 1 | | frame 1 |
| wizard message, "Let's watch the binder float it, while the camera doesn't move."
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| mview store, object=AA
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| mview store, object=BB
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|
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| # 2 second pause for the user to catch up
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| frame 60
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| mview store, object=AA
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| mview store, object=BB
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|
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| frame 300
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| # slide the inhibitor in from over the camera. :-)
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| translate [0,0,-100], object=AA
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| mview store, object=AA
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| mview interpolate, object=AA
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|
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| # store & wait 2 seconds...
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| frame 360
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| mview store, object=AA
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| mview store, object=BB
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| mview reinterpolate, object=AA
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| mview reinterpolate, object=BB
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|
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| # 'explode' apart
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| frame 380
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| translate [-70, 70, 70], object=AA
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| translate [70, -70, -70], object=BB
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| mview store, object=AA
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| mview store, object=BB
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| mview reinterpolate, object=AA
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| mview reinterpolate, object=BB
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|
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|
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|
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| mplay | | mplay |
| </source> | | </source> |
|
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| ===Camera & Object Motions===
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|
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| ===Representations===
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|
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| ===Motions & Representations ===
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|
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| === Extras ===
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|
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| == Exporting your Movie ==
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|
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|
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|
| = See Also = | | = See Also = |