= Review continuous files =
''Authors: Francois Tadel, Elizabeth Bock, Sylvain Baillet''

<<TableOfContents(2,2)>>

== Access the raw file ==
The basic  tutorials you read before explain how to  import recordings in the  database:  this operation creates a copy of all  the data in Matlab .mat  files in the  Brainstorm database folders. You  could process  continuous recordings in  the same way, but the .mat  format has this  limitation that the entire  file has to be read even  when you want to  access just a portion of it. Long recordings usually  cannot fit in  memory and have to be split in small blocks of a few  seconds, which  makes it very difficult to review and  process.

Brainstorm   offers the possibility to visualize continuous MEG/EEG recordings in  any  of the supported file formats without having to fully "import"  them. A  link to the native file is created in the database, which can  be then  manipulated almost like the "imported" recording blocks. Only  the  description of the file is saved in the database, and when  displaying it  the values are read directly from the native file.

In  addition, an interface allows to edit the time markers that are saved   in the file. Those markers can then be used to import the recordings in   the database (ie. to do the segmentation of the continuous recordings  in  epochs/trials). Then the imported epochs/trials (hard copies in .mat   format) can be pre-processed and averaged.

 * Select the exploration mode: "Functional data (sorted by subject)"<<BR>><<BR>> {{attachment:view_functional.gif}}
 * Right-click  on the subject node, and select: "Review raw file". Select the "MEG:  CTF" file type, and pick the ds folder in "/sample_raw/Data".
  . {{http://neuroimage.usc.edu/brainstorm/Tutorials/TutRawViewer?action=AttachFile&do=get&target=menuReview.gif|menuReview.gif|class="attachment"}}
 * Then  you're asked if you want to "Refine the registration with the head  points". This operation improves the initial MRI/MEG registration by  fitting the head points digitized before the MEG acquisition on the  scalp surface with an ICP algorithm. Answer yes. Even if the result is  not perfect, it usually improves the positioning of the head in the MEG  helmet. The grey surface represents the head extracted from the MRI, the  yellow surface represents the inside of the MEG helmet, and the green  dots are the head shape points digitized with the Polhemus device; the  goal is to align the green points on the grey surface.
  . {{http://neuroimage.usc.edu/brainstorm/Tutorials/TutRawViewer?action=AttachFile&do=get&target=refine.gif|refine.gif|class="attachment"}} {{http://neuroimage.usc.edu/brainstorm/Tutorials/TutRawViewer?action=AttachFile&do=get&target=refineBefore.gif|refineBefore.gif|class="attachment"}} {{http://neuroimage.usc.edu/brainstorm/Tutorials/TutRawViewer?action=AttachFile&do=get&target=refineAfter.gif|refineAfter.gif|class="attachment"}}
 * Two new files appeared in the database explorer:
  . {{http://neuroimage.usc.edu/brainstorm/Tutorials/TutRawViewer?action=AttachFile&do=get&target=linkInTree.gif|linkInTree.gif|class="attachment"}}
  * The  channel file contains the definition of the sensors, exactly as when  importing the files in the database with the "Import MEG/EEG" menu. It  is saved in the folder ''(Common files)'', because the subject was  created using the option "Yes, use one channel file per subject".  Therefore, the same channel file will be used for all the folders of  Subject01.
  * The  node named "Link to raw file" contains all the information that was read  from the continuous file (file format, time vector, sampling frequency,  events, bad channels, path to the original file, etc.), but no  recordings. The MEG and EEG values recorded will be read directly from  the native file.

== Review the recordings ==

=== Open the file ===
Right-click on the data file > MEG (all) > Display time series.

{{http://neuroimage.usc.edu/brainstorm/Tutorials/TutRawViewer?action=AttachFile&do=get&target=displayTsMenu.gif|displayTsMenu.gif|class="attachment"}}

You can see new information in the tab "Record" and a figure showing the recordings.

{{http://neuroimage.usc.edu/brainstorm/Tutorials/TutRawViewer?action=AttachFile&do=get&target=rawPanel.gif|rawPanel.gif|class="attachment"}}

=== Navigate in time ===
As described  in the basic tutorials, you can set the current time by using either  the time panel (buttons and text field), or the figure (click on the  white or grey areas of the figure). But you can notice that only a few  seconds are visible in the figure, while the time panel (top left of the  previous figure), indicates that we have 360s of recordings. Only a  small block of the continuous file has been loaded in memory. This small  time window can be configured with the tab '''Record/Page settings''', with the text boxes '''Start''' and '''Duration'''.

The  time series figure is similar to the ones that were presented in the  previous tutorials, with a few new elements. The navigation bar at the  bottom represents the time of the entire raw file, where the events are  also represented by dots. The ''''<<<'''' and ''''>>>''''  buttons are the same as the ones in the time panel, and jump to the  previous/next segment in the file. Clicking on the bar or dragging the  red cursor change the current time window as well.

=== Sensor selection ===
Let's switch  to a nicer representation of the recordings time series: click on the  "Display mode" button in the toolbar of the Record tab.

{{http://neuroimage.usc.edu/brainstorm/Tutorials/TutRawViewer?action=AttachFile&do=get&target=tsColumn.gif|tsColumn.gif|class="attachment"}}

Now  the traces are displayed in columns, but all the channels are displayed  in the same figure, which makes it unreadable. Select a subset of  channels by right-clicking on the figure > '''Montages''', with the drop-down menu in the Record tab or with a keyboard shortcut ('''Shift+A, B, C'''...).  Default groups of sensors are available for some MEG systems, but you  can also create your own groups of sensors with the menu "Edit  montages".

{{http://neuroimage.usc.edu/brainstorm/Tutorials/TutRawViewer?action=AttachFile&do=get&target=tsChannelSelection.gif|tsChannelSelection.gif|class="attachment"}}

=== Amplitude scale ===
In this display mode, the amplitude scale is represented on the right of the figure. You can adjust this vertical scale:

 * Use the buttons "'''^'''" and "'''v'''"  on the right side of the figure. The shortcuts for those buttons are  indicated in the tooltips (leave the mouse for a short while over a  button)
 * Hold the '''Shift key''' and move the mouse wheel, or use the keys "'''+'''" and "'''-'''".
 * Use the button "'''...'''" on the right side of the figure ("Set scale manually") to set the scale to a precise level.

When  scrolling in time to a different page, the amplitude scale is by  default kept. You can change this behavior to re-evaluate automatically  an optimal scale each time you change the current time window. This  option is called "Auto-scale amplitude" and is disabled by default. To  activate it: click on the "'''AS'''" button on the right of the figure, or check the menu "'''Display > Auto-scale amplitude'''" in the Record tab.

=== Display options ===
 . {{http://neuroimage.usc.edu/brainstorm/Tutorials/TutRawViewer?action=AttachFile&do=get&target=displayOptions.gif|displayOptions.gif|class="attachment"}}

 * '''Remove DC offset''':  Button [DC] in the Record tab. When selected, for each channel, the  average value over the  entire current time window is subtracted from  the channel values. This means that if you change the length of  the  time window, the value that is removed from each channel may change.  It  doesn't make much sense to disable this option for unprocessed MEG  recordings.

 * '''Apply CTF compensation''':  Button [CTF] in the Record tab. Enable/disable the CTF noise correction   based on the reference sensors, when it is not already applied in the   file. In the current file, the CTF 3rd order gradient compensation is   already applied, therefore this option is not available.
 * '''Flip +/-''': Button in the right part of the time series figure. Exchange the direction of the Y axis, useful mostly for clinical EEG.
 * '''Set scale manually''': Button [...] in the figure. Forces a defined amplitude scaling.
 * '''Auto-scale amplitude''':  Button [AS] in the figure. When  selected, the vertical scale is  adapted to the maximum value over the time window when the time window  changes. When  not selected: the vertical scales keeps its last value  when you jump to  another part of the file.

=== Online filter ===
With  the  Filter tab, you can apply a band-pass  filter to the recordings, or  remove a set of specific frequencies  (example: the 50Hz or 60Hz power  lines contamination and their harmonics). The filters are applied only  to the time window that is currently loaded; hence if the segment is too  short for the required filters, the results could be inaccurate.

The option "'''Mirror signal before filtering'''"  triples artificially the length of the signal with a mirror symmetry on  each side, to avoid the strong edge effects that those filters can  generate. Those online filters are not very accurate, they just provide a  quick estimate for visualization only, the results are not saved  anywhere. To filter properly the continuous files, please use the  Process1 tab.

After  testing the high-pass, low-pass and notch filters, uncheck them. If not  you will probably forget about them, and they will stay on until you  restart Brainstorm.

{{http://neuroimage.usc.edu/brainstorm/Tutorials/TutRawViewer?action=AttachFile&do=get&target=onlineFilter.gif|onlineFilter.gif|class="attachment"}}



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