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A number of techniques are now established for non-invasive mapping
of responses to sensory and cognitive stimulation of the human
brain. These provide exciting opportunities for vision scientists
to record the activity of brain areas involved in visual processes.
The technologies, which include functional magnetic resonance
imaging (fMRI) and magnetoencephalograms (MEG), are based on different
physical principles, but have in common the need to be performed
within an electrically shielded environment. This means that most
of the vision researcher's customary equipment should not be placed
close to the imaging system: stimuli cannot be displayed on a
CRT-based monitor and responses cannot be recorded using standard
analogue or digital electronics.
Presenting Stimuli
Visual stimulation using computer graphics and CRT-based displays
is incompatible with the sensitive environments required by functional
imaging techniques.
- The display and driver electronics generate excessive quantities
of radiation that interfere with the signals being collected
- The output from the CRT (a magnetically deflected system)
is affected by the high magnetic fields needed for operating
an MRI scanner
- Magnetic fields extend beyond the confines of the usual screened
rooms and prevent the useful operation of CRTs even outside
them
Using Projectors
A simple solution to the stimulus presentation problem is to
use a projector: the stimulus is projected on to a screen located
near the subject, typically at one end of a scanner. The subject,
who is normally recumbent and therefore looking up, can view the
screen with the help of a mirror mounted on the head coil. The
projector can be used either inside or outside the shielded room.
An ideal solution places it inline with a back-projection screen
to alleviate spatial distortion (the keystone correction electronically
implemented by the projector introduces other non-desirable artefacts).
There are two types of portable projector technology: those that
use liquid crystal panels as the light modulating elements and
those that use 'digital' micro mirrors. Both technologies rely
on electrical rather than magnetic phenomena for their operation.
Micro mirror-based portable projectors generate colour using sequential
frames and a colour wheel rather than a set of fixed dichroic
filters. This solution can create synchronisation problems so
currently we suggest using LCD-based projectors.
LCD projectors
Modern LCD projectors contain a single high-intensity discharge
lamp and three LCD spatial light modulators. The light is split
into three coloured components, modulated by the LCD panels and
then recombined optically before being launched via the projection
lens onto the screen. The light source is essentially a well-controlled
static device that adds no temporal components to the image. However,
regular calibration of the light source is necessary to accommodate
changes in luminance and colour temperature over time.
From a vision science perspective, the LCD spatial light modulators
and their controlling circuitry provide the interesting properties
of the device.
- Each LCD panel has an intrinsic resolution; the surface comprises
a fixed array of elements with a defined spacing. Current resolutions
range from 0.5 to 0.75 million pixels and each of the pixels
can be updated at about 60 Hz.
- The internal electronics digitise the analogue signal, then
compress and interpolate the data spatially and temporally to
produce a data stream that it can display. If the frame rate
of the input signal is too high, the projector will drop frames
to provide the correct average rate. This causes problems for
dynamic stimuli, particularly if the objects are moving in space.
- It is important to run a projector in its native mode, that
is at a spatial resolution equal to the native resolution and
at a frame rate within its direct capability.
- The intervention of the signal processing circuits in the
video chain imposes a substantial delay between the arrival
of the video input and the appearance of the light on the screen.
This can be as much as 15 ms and makes the use of projectors
in image stabilisation schemes more difficult.
- If it is necessary to know exactly when the stimulus onset
occurs then the delay time must either be characterised (which
is easy to do provided the display is locked to the source)
or a small photocell system devised to feedback the light output
directly into a data acquisition system.
The diagram above shows how the light output from an area on
a projector screen near the centre varies with time when the patch
is illuminated for two frames before being turned off. This can
be compared to the light from a CRT when driven by the same video
signal. The additional time delay imposed by the projector's electronics
is also clearly visible.
| Feature |
CRT |
Projector
1 |
Comment |
| Size of image |
<21 inches |
>21 inches |
Back projection is desirable to
eliminate keystone distortion |
| Size of device |
Large and heavy
(35 kg) |
Small and portable
(3 kg) |
But projectors require a screen
too |
Spatial
resolution
(pixels) |
1280*1024 |
800*600 |
Larger projector resolution available
at high cost |
| Geometry |
OK |
Excellent |
|
| Temporal
resolution |
160 Hz |
60 Hz |
Projectors are unsuitable for
fast dynamic stimuli |
| Maximum
luminance |
150 cd.m-2 |
700 cd.m-2 |
Projector luminance depends on
image size |
Dark light
(minimum luminance) |
0 |
2 cd.m-2 |
Dark light limits the contrast
available on projectors |
| Gamma |
2.2 |
1 - 2.5 |
Projector gamma is applied electronically
and may be removable |
| Light emission characteristics |
1 ms pulses repeated at the frame
rate |
Pulses of the frame duration at
the frame rate |
A static image on a projector
has no pulsatile quality |
| Delay time from video
input to light output |
0 |
Maybe as much as one frame |
This delay limits the ability
to stabilise an image on the retina |
1 based on Epson EMP500
Temporal Synchronisation & Triggering
Projectors are compatible with many video sources but this does
not mean that all combinations are suitable for vision research.
For maximum display accuracy and ease of control we advise driving
projectors with a Visual Stimulus Generator like the ViSaGe.
Unlike other sources of video data, the ViSaGe
provides accurate timing control, automatic gamma correction and
experimental versatility.
If you are using an additional data acquisition system for recording
eye movements or evoked responses, it is easy to take a
digital trigger signal generated by the VSG and record this
on a spare channel to provide a time marker synchronised to the
stimulus onset. The recorded data can subsequently be correlated
offline with scanner images after the experiment.
In all vision science applications it is important to ensure
that the stimulus presented by the display device really has the
required profile and also remains the same from trial to trial.
Projector bulbs have finite lifetimes (about 2000 hours) and during
this period it is reasonable to expect significant changes in
colour and luminance. Cambridge Research Systems offers several
calibration tools: the OptiCAL
photometer, the ColorCAL
colorimeter and the SpectroCAL vision science meter. Both solutions are fully integrated
with our Visual Stimulus Generators and can be used to automatically
generate the required lookup tables and colour coordinates. Using
either of these devices is fast and makes display calibration
simple.
Generating Stimuli
Visual stimuli can be generated by writing a computer program
in a low-level language and then presented using a standard graphics
card. While this approach is very powerful, it does require an
intimate understanding of graphics technology to synchronise the
display.
The VSG Software
Library for the ViSaGe
offers a much easier approach and includes a suite of stimulus
demonstrations specifically designed for functional imaging applications.
These cover many of the common paradigms, including stimuli for
retinotopic mapping. All aspects of these stimuli can be defined
from simple on screen controls, so often no further programming
will be needed. If more complex stimuli are required, full source
code for the demonstration programs is provided to illustrate
how to use the VSG
Software Library and transparently handle procedures like:
- Driving the projector in its native mode
- Activating colour and luminance calibration
- Synchronising the stimulus and display
- Generating trigger and marker information
Example Visual Stimuli
Retinotopic Mapping - this stimulus enables
mapping of both angle and eccentricity. Used with cortical flattening
software (for example: Dale AM, Fiscl B, Serano MI (1999)
Cortical surface-based analysis. NeuroImage 9:179-194),
the cortical representation of retinotopic space can be determined.
This enables visual areas responding to specific stimuli to be
located (Engals SA, Glover GH, Wandell BA (1997) Retinotopic
organisation in Human Visual Cortex and the Spatial Precision
of Functional MRI. Cerabral Cortex 7:181-192). The VSG
Software Library includes a stimulus demonstration, which
shows how to implement retinotopic mapping using the ViSaGe.
Motion - both first- and second-order motion
stimuli are available. Choose from radial or linear luminance
encoded motion. Second order-motion stimuli are encoded purely
by contrast or colour changes in a field of dynamic random noise
(Smith AT, et al (1998) The Processing of First- and Second-Order
motion in human visual cortex assessed by functional magnetic
resonance imaging. J of Neuroscience 18(10): 3816-3830).
Colour & Contrast - isoluminant grating,
chequerboard and windmill stimuli.
Picture Display - the ViSaGe
can be used to display photographic images as well as mathematical
stimuli. Common graphics file formats like Windows bitmap (BMP)
can easily be imported. The VSG
Software Library includes a dedicated image file demonstration
utility. This uses an optimised memory buffer to ensure accurate
timing and provides an external trigger facility to synchronise
data collection apparatus.
Recording Eye Movements
In fMRI, the distribution of BOLD (blood oxygen level dependent)
responses depend on the type of eye movement performed, so to
reliably classify brain areas it is important to carefully measure
the actual eye movements. Eye movements are either spontaneous
in nature or they are visually guided. The latter fall into two
general classes: saccadic eye movements which are ballistic and
direct the fovea to a target or location of interest, and pursuit
eye movements which are smooth continuous tracking movements,
when the eyes follow a moving target.
MR-Eyetracker
Some conventional eye-trackers are not fast enough to distinguish
different types of movement and most incorporate ferrous materials
and electronics that are incompatible with magnetic environments.
The MR-Eyetracker is a contact-free solution that is easy to operate
and is designed specifically for use in fMRI: it uses fibre optics
and has high spatial and temporal resolution easily capable of
discriminating saccades and pursuit.
Measurement Technique
Fibre optic cables guide infra-red light from a source located
outside the scanner into the head coil and onto the eye of the
subject. The light is reflected by the eye along the edge of the
iris and is transferred back to infra-red sensitive diodes (limbus
reflection). These photodiodes are coupled to an amplifier, which
provides independent estimates of the horizontal and vertical
positions in one eye. The system works with a daylight suppression
technique, to prohibit interference from ambient light.
The fibre optic cables are encased in black malleable plastic
for easy handling and their long length prevents the MR-Eyetracker
Control Unit from interfering with the magnetic field. The ends
of the cables are mounted into a custom eyepiece that is attached
directly to the head coil. Just a few centimetres of additional
space are required to mount the eyepiece, since it is designed
to be lowered into the window of the head coil.
A mirror and mounting plate are also available for the head coil
so that the subject can view a stimulus projected on to a screen
located near the scanner.
Calibrating the Eye Position
Calibration of the MR-Eyetracker is a simple process that takes
less than five minutes.
- The subject looks at a fixation point on the screen while
the experimenter centres a red/green bar displayed at the bottom
of the pupil and adjusts the zero-offset
- Subsequent measurements are made with a stimulus displayed
at known horizontal and vertical angles
The fixation and stimulus can be generated with a visual stimulus
generator like the ViSaGe
and the vsgEyetrace
software, or any other computer graphics system.
Capturing and Analysing Data
A two-channel data acquisition system is required to capture
the separate horizontal and vertical eye position signals. An
application such as National Instrument's LabVIEW,
or a user-provided program can be used to display and process
the signal. Alternatively, the vsgEyetrace
software for the ViSaGe
provides an integrated data acquisition and visual stimulator
solution for common ocular-motor tasks. The scanner should be
programmed to provide a TTL-compatible pulse at the beginning
of each volume acquisition to synchronize both the stimulation
and the acquisition programs. This is required to later classify
the brain areas based on the processed eye position signals.
Example Data
In this example, the subject fixated at a point (FP) in the centre
of the display (position 0/0). After one second the FP disappeared
and a target (T) was turned on at position x/y, for 1.5 s duration.
The subject performed a saccade from FP to T.
The stimulus was generated using a ViSaGe
and back projected using an LCD projector onto a transluminent
screen.
MR-Eyetracker Specification
|
Spatial Resolution
- Minimum 0.2°
- Typical < 0.1°
|
Analog Output
- BNC Connectors
- Horizontal ± 5 V
- Vertical ± 5 V
|
|
Range
- Horizontal ± 20°
- Vertical ± 10°
|
Illumination
- Infrared LEDs < 0.2 mW @ 880 nm
|
|
Linearity [1]
- Horizontal 2 %
- Vertical 3 %
|
Physical
- Dimensions 305 mm x 155 mm x 155 mm (Control Unit)
- Mass 3.4 kg (Control Unit and PSU)
|
|
Bandwidth |
Power Requirements
- 230 V / 50 Hz
- 120 V / 60 Hz
|
|
Delay |
[1] - over operating range |
Further Information
The MR-Eyetracker was developed by H.Kimmig, M.W. Greenlee, F.Huethe
and T.Mergner at the Department
of Neurology, University of Freiburg, Germany.
An earlier version of the system is described in: Kimmig,
H., Greenlee, M. W., Huethe, F., & Mergner, T. (1999). MR-Eyetracker:
A new method for eye movement recording in functional magnetic
resonance imaging (fMRI). Experimental Brain Research, 126; 443-449.
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