U.S. patent application number 15/996624 was filed with the patent office on 2018-09-27 for scanning beam display system.
The applicant listed for this patent is Prysm, Inc.. Invention is credited to Roger A. Hajjar, Victor A. Ruskovoloshin.
Application Number | 20180278898 15/996624 |
Document ID | / |
Family ID | 55070683 |
Filed Date | 2018-09-27 |
United States Patent
Application |
20180278898 |
Kind Code |
A1 |
Hajjar; Roger A. ; et
al. |
September 27, 2018 |
Scanning Beam Display System
Abstract
A scanning beam display system includes an optical module, an
image control module, and a display screen on which optical beams
are scanned. The optical module includes a vertical adjuster placed
in the optical paths of the beams to control and adjust positions
of the optical beams along a generally vertical direction on the
display screen, and a control unit configured to receive control
instructions for the vertical adjuster and to control the vertical
adjuster to be at one of a predetermined number of orientations to
place the scanning optical beams at a corresponding distinct
position on the display screen. The control unit is further
configured to apply an adjustment offset to each orientation of the
vertical adjuster such that each immediately vertically adjacent
pair of beam footprints projected on the display screen resulting
from the plurality of positions have a vertical overlap that is
larger than a first threshold.
Inventors: |
Hajjar; Roger A.; (San Jose,
CA) ; Ruskovoloshin; Victor A.; (Dublin, CA) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Prysm, Inc. |
San Jose |
CA |
US |
|
|
Family ID: |
55070683 |
Appl. No.: |
15/996624 |
Filed: |
June 4, 2018 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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14583023 |
Dec 24, 2014 |
9998717 |
|
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15996624 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
G09G 2340/0464 20130101;
G09G 2310/0235 20130101; G09G 2360/14 20130101; G09G 2320/0209
20130101; G02B 26/101 20130101; G09G 2300/023 20130101; G09G 1/20
20130101; G09G 2310/0205 20130101; H04N 9/3132 20130101; G02B
26/123 20130101; G09G 2300/0452 20130101; G09G 2340/0478 20130101;
G02B 26/12 20130101; G09G 1/143 20130101; G09G 3/002 20130101; G09G
2300/026 20130101; G09G 2310/0227 20130101; G09G 2320/0233
20130101; G09G 2340/0471 20130101; G09G 2320/0242 20130101; H04N
9/3129 20130101 |
International
Class: |
H04N 9/31 20060101
H04N009/31; G02B 26/12 20060101 G02B026/12; G09G 1/14 20060101
G09G001/14; G09G 1/20 20060101 G09G001/20; G09G 3/00 20060101
G09G003/00; G02B 26/10 20060101 G02B026/10 |
Claims
1-21. (canceled)
22. A scanning beam display system, comprising: an optical module;
an image control module that is configured to receive image
information and convey corresponding pixel information to the
optical module, the optical module being configured to produce a
plurality of optical beams that are modulated based on the pixel
information to thereby convey images to be displayed, wherein each
of the optical beams convey pixel information; and a display screen
configured to receive the optical beams and to display images
conveyed by the optical beams as the optical beams are scanned in a
generally horizontal direction across the display screen, wherein
the optical module comprises: a vertical adjuster placed in optical
paths of the optical beams to control and adjust positions of the
optical beams along a generally vertical direction on the display
screen, and a control unit configured to receive control
instructions for the vertical adjuster and to control an
orientation of the vertical adjuster to be reoriented between a
plurality of default orientations that place the optical beams
being scanned at a plurality of corresponding default positions
along the vertical direction on the display screen, wherein the
control unit is further configured to apply adjustment offsets that
alter the vertical adjuster's orientations away from the default
orientations such that the optical beams are horizontally scanned
at a plurality of adjusted positions along the vertical direction
on the display screen and such that each immediately vertically
adjacent pair of beam footprints projected on the display screen
have a vertical overlap that is larger than a first threshold.
23. The system of claim 22, wherein the optical module further
comprises a polygon scanner positioned in the optical paths of the
optical beams and comprising a rotation axis around which the
polygon scanner rotates to scan the optical beams horizontally
across the display screen, the polygon scanner including a
plurality of polygon facets that are each sized to simultaneously
receive the optical beams and each tilted with respect to the
rotation axis at different facet tilt angles, respectively, to scan
the optical beams horizontally at different vertical positions on
the display screen, respectively.
24. The system of claim 23, wherein the vertical adjuster reorients
to a different orientation after each complete rotation of the
polygon scanner.
25. The system of claim 22, wherein a total number of default
orientations is two or three.
26. The system of claim 22, wherein a total number of default
orientations is such that the vertical adjuster, by switching
between the predetermined number of orientations, causes the beam
footprints to be projected on the display screen over time such
that there are no gaps in the vertical direction between
immediately vertically adjacent pairs of beam footprints.
27. The scanning of claim 22, wherein the default orientations of
the vertical adjuster are separated by equidistant angles.
28. The system of claim 22, wherein the pixel information
associated with each orientation of the vertical adjuster for a
vertically continuous group of beam footprints is different.
29. The system of claim 22, wherein the pixel information
associated with two of the orientations of the vertical adjuster
for a vertically continuous group of beam footprints are same.
30. The system of claim 22, wherein the pixel information
associated with one of the orientations of the vertical adjuster
for a vertically continuous group of beam footprints is
interpolated from the pixel information associated with two other
orientations of the vertical adjuster for the vertically continuous
group of beam footprints.
31. The system of claim 22, wherein the control unit is configured
to increase or decrease an optical energy associated with each beam
footprint to limit non-uniformity in screen brightness.
32. The system of claim 22, further comprising a memory configured
to store beam footprint information of a beam footprint formed by
each of the optical beams on the display screen, the beam footprint
information including beam height data and position data of the
beam footprint, wherein the control unit is configured to receive
control instructions that are determined based on the stored beam
footprint information.
33. The system of claim 32, wherein the memory is configured to
receive beam footprint information from a beam footprint
determination unit.
34. The system of claim 33, wherein the optical module includes the
beam footprint determination unit.
35. A scanning beam display array, comprising two or more scanning
beam display systems as in claim 22 that are arranged adjacent to
each other, wherein the orientations and associated adjustment
offsets of each of the corresponding vertical adjusters are
synchronized.
Description
CROSS-REFERENCE TO RELATED APPLICATION
[0001] This application is a continuation of U.S. application Ser.
No. 14/583,023, filed Dec. 24, 2014, the contents of which are
incorporated by reference herein.
TECHNICAL FIELD
[0002] This application generally relates to display systems that
scan one or more optical beams onto a screen to display images.
BACKGROUND
[0003] Display systems can be configured as scanning-beam display
systems which scan one or more optical beams that are modulated
over time to carry optical pulses as the beam moves over a screen
in a raster scanning pattern to form images on a screen. Each
scanning beam has a small beam footprint that is less than or equal
to a subpixel on the screen and the beam footprint scans the
subpixel and is modulated in optical power or intensity in the time
domain to carry images. Raster scanning of such a modulated beam on
the screen converts images carried by the sequential optical pulses
into spatial patterns as images on the screen.
SUMMARY
[0004] According to one aspect, a scanning beam display system
includes an optical module, an image control module that is
configured to receive image information and convey corresponding
pixel information to the optical module, where the optical module
being configured to produce a plurality of optical beams that are
modulated based on the pixel information to thereby convey images
to be displayed, and a display screen configured to receive the
plurality of optical beams to display images conveyed by the
optical beams, where the plurality of optical beams are scanned in
a generally horizontal direction across the display screen. Each of
the optical beams convey pixel information. The optical module
includes a vertical adjuster placed in the optical paths of the
optical beams to control and adjust positions of the optical beams
along a generally vertical direction on the display screen, and a
control unit configured to receive control instructions for the
vertical adjuster and to control the vertical adjuster to be at one
of a predetermined number of orientations to place the scanning
optical beams at a corresponding distinct position along the
vertical direction on the display screen, where the control unit
causes the vertical adjuster to reorient periodically to another of
the orientations. The control unit is further configured to apply
an adjustment offset associated with each orientation of the
vertical adjuster such that each immediately vertically adjacent
pair of beam footprints projected on the display screen resulting
from the plurality of positions have a vertical overlap that is
larger than a first threshold.
[0005] Implementations of this aspect may include one or more of
the following features. For example, the control unit may be
further configured to decrease an optical energy associated with
each beam footprint such that the resulting vertical overlap of
each immediately vertically adjacent pair of beam footprints is
less than a second threshold. The second threshold may be a maximum
allowable size associated with the vertical overlap between any two
immediately vertically adjacent beam footprints. The second
threshold may be a maximum allowable intensity of the vertical
overlap between any two immediately vertically adjacent beam
footprints. Decreasing the optical energy may reduce a height of
the corresponding beam footprint. The optical module may further
include a polygon scanner positioned in the optical paths of the
optical beams and comprising a rotation axis around which the
polygon scanner rotates to scan the optical beams horizontally
across the display screen. The polygon scanner may include a
plurality of polygon facets that are each sized to simultaneously
receive the optical beams and each tilted with respect to the
rotation axis at different facet tilt angles, respectively, to scan
the optical beams horizontally at different vertical positions on
the display screen, respectively. The vertical adjuster may
reorient to a different orientation after each complete rotation of
the polygon scanner. The vertical adjuster, by switching between
the predetermined number of orientations, may cause the beam
footprints to be projected on the display screen over time such
that there are no gaps in the vertical direction between
immediately vertically adjacent pairs of beam footprints. The
predetermined number of orientations may be three or more. The
orientations of the vertical adjuster may be separated by
equidistant angles. The orientations of the vertical adjuster may
be separated by non-equidistant angles. The pixel information
associated with each orientation of the vertical adjuster for a
vertically continuous group of beam footprints may be different.
The pixel information associated with two of the orientations of
the vertical adjuster for a vertically continuous group of beam
footprints may be same. The pixel information associated with one
of the orientations of the vertical adjuster for a vertically
continuous group of beam footprints may be interpolated from the
pixel information associated with two other orientations of the
vertical adjuster for the vertically continuous group of beam
footprints. The control unit may be configured to increase or
decrease an optical energy associated with each beam footprint to
limit non-uniformity in screen brightness.
[0006] The scanning beam display system according to this aspect
may further include a memory configured to store beam footprint
information of a beam footprint formed by each of the optical beams
on the display screen, where the beam footprint information
including beam height data and position data of the beam footprint,
and where the control unit is configured to receive control
instructions that are determined based on the stored beam footprint
information. The memory may be configured to receive beam footprint
information from a beam footprint determination unit. The optical
module may include the beam footprint determination unit.
[0007] A scanning beam display array may include two or more
scanning beam display systems according to this aspect, where the
two or more scanning beam display systems may be arranged adjacent
to each other, and where the orientations and associated adjustment
offsets of each of the corresponding vertical adjusters may be
synchronized.
[0008] According to another aspect, a scanning beam display array
may include two or more scanning beam display systems according to
this aspect, where the two or more scanning beam display systems
may be arranged adjacent to each other, and where the orientations
and associated adjustment offsets of each of the corresponding
vertical adjusters may be synchronized. According to another
aspect, a scanning beam display system may include an optical
module, an image control module that is configured to receive image
information and convey corresponding pixel information to the
optical module, where the optical module is configured to produce a
plurality of optical beams that are modulated based on the pixel
information to thereby convey images to be displayed, and a display
screen configured to receive the plurality of optical beams to
display images conveyed by the optical beams, where the plurality
of optical beams being scanned in a first direction across the
display screen. Each of the optical beams conveys pixel
information. The optical module includes an adjuster placed in the
optical paths of the optical beams to control and adjust positions
of the optical beams along a second direction on the display
screen, where the second direction is transverse to the first
direction, and a control unit configured to receive control
instructions for the adjuster and to control the adjuster to be at
one of a predetermined number of orientations to place the scanning
optical beams at a corresponding distinct position along the second
direction on the display screen, where the control unit causes the
adjuster to reorient periodically to another of the orientations.
The control unit is further configured to apply an adjustment
offset associated with each orientation of the adjuster such that
each pair of beam footprints that are projected on the display
screen resulting from the plurality of positions and are
immediately adjacent to each other along the second direction have
an overlap along the second direction that is larger than a first
threshold.
[0009] Implementations of this aspect may include one or more of
the following features. For example, the adjuster may be configured
to adjust positions of the optical beams along the second direction
that is orthogonal to the first direction.
DESCRIPTION OF DRAWINGS
[0010] FIG. 1 illustrates an example scanning beam display
system.
[0011] FIG. 2 illustrates an example scanning pattern for filling
the screen produced by using a polygon scanner to scan multiple
laser beams and using a vertical adjuster to interlace three
fields.
[0012] FIG. 3 illustrates an example scanning beam display system
having a screen having fluorescent stripes.
[0013] FIG. 4A illustrates a side cross-section view of the
fluorescent screen in FIG. 3.
[0014] FIG. 4B illustrates a close-up view of the fluorescent
screen in FIG. 4A along the direction B-B.
[0015] FIG. 5 illustrates an example implementation of a laser
module from the system in FIG. 3.
[0016] FIG. 6 illustrates an example implementation of filling the
display screen by interlacing two fields.
[0017] FIG. 7 illustrates a series of beam footprints projected
over time in two adjacent scan lines from FIG. 6.
[0018] FIG. 8 illustrates an example implementation of filling the
display screen by interlacing three fields.
[0019] FIG. 9 illustrates a series of beam footprints projected
over time in three adjacent scan lines from FIG. 8.
[0020] FIG. 10 illustrates an example anomaly in the series of beam
footprints in FIG. 9.
[0021] FIG. 11 illustrates another example anomaly in the series of
beam footprints in FIG. 9.
[0022] FIG. 12 illustrates an example bow distortion on the display
screen.
[0023] FIG. 13 illustrates an example of measured distortions on
the display screen.
[0024] FIG. 14 illustrates a series of beam footprints projected
over time in three adjacent scan lines, where the beam footprints
converge along the scanning direction to create bright spots in
overlapping regions.
[0025] FIG. 15 illustrates the series of bean footprints from FIG.
14 following an exemplary optical energy reduction in the affected
beams to reduce the bright spots.
[0026] FIGS. 16A-C illustrate example optical beam profiles.
[0027] FIGS. 17A-D illustrate example assignments of pixel values
across multiple image fields over time.
[0028] FIGS. 18A and B illustrate example assignments of pixel
values across multiple image fields over time based on 8 refreshes
per video frame.
[0029] Like reference symbols in the various drawings indicate like
elements.
DETAILED DESCRIPTION
[0030] Display systems that scan one or more optical beams onto a
screen to display images can be implemented in various
configurations. For example, in some implementations, the screen
may be a passive screen that does not emit light and directly uses
the light of the one or more scanning optical beams to form the
images by, e.g., reflecting, transmitting, diffusing or scattering
the light of the one or more scanning optical beams. In a rear
projection mode with red, blue and green beams carrying images
respectively in red, green and blue colors, the passive screen
receives the red, green and blue beams from one side and diffuses,
transmits or scatters the received light to produce colored images
for viewing on the other side of the screen.
[0031] In other implementations, the screen of such a display
system may be a light-emitting screen. Light-emitting materials can
be included in such a screen to absorb the light of the one or more
scanning optical beams and to emit new light that forms the images.
The light of the one or more scanning optical beams is not directly
used in forming the images seen by a viewer. For example, the
screen can be a light-emitting screen that emits visible light in
colors by converting excitation energy applied to the screen into
the emitted visible light, e.g., via absorption of excitation
light. The emitted visible light forms the images to a viewer. The
screen can be implemented to include multiple screen layers, one or
more of which have light-emitting components that convert the
excitation energy into the emitted visible light that forms the
images.
[0032] In the above as well as in other implementations, various
optical components, such as optical scanning modules that perform
the raster scanning of the one or more optical beams and optical
lenses, are typically provided in the optical paths of the one or
more optical beams before reaching the screen. Under an ideal
operating condition, the raster scanning pattern formed by scanning
the one or more optical beams on the screen should be spatially
uniform and free of distortions to produce the desired images. For
example, the raster scanning pattern for a flat rectangular shaped
wide screen (e.g., with an aspect ratio of 16:9 in many HDTV
systems) should be parallel horizontal scanning lines with even
spacing along the vertical direction at all locations where the
beam spot size on the screen should be a constant independent of
the one or more beam positions on the screen. However, various
optical distortions can occur in the optical paths to distort the
raster scanning pattern on the screen. For example, the presence of
optical scanning modules, optical lenses, and other optical
components in the optical paths of the one or more optical beams
often cause optical distortions. As a result of such distortions,
the quality of the displayed images may be degraded.
[0033] One measure of the image quality is the uniformity of the
image brightness across the screen. Human eyes are sensitive to
variations of brightness. Therefore, optical distortions that lead
to non-uniform image brightness across the screen are significant
technical issues in high-quality display systems. Unintended
spatial variations in beam spot size and line spacing between
adjacent scanning lines on the screen are examples of contributing
causes for non-uniform image brightness across the screen.
[0034] Specific examples of scanning beam display systems based on
light-emitting screens are described below to illustrate the local
dimming techniques. The techniques can also be applied to scanning
beam display systems based on passive screens.
[0035] Scanning beam display systems based on light-emitting
screens use screens with light-emitting materials such as
fluorescent materials to emit light under optical excitation to
produce images. A light-emitting screen can include a pattern of
light-emitting regions that emit light for forming images and
non-light-emitting regions that are spaces void of light-emitting
materials between the light-emitting regions. The designs of the
light-emitting regions and non-light-emitting regions can be in
various configurations, e.g., one or more arrays of parallel
light-emitting stripes, one or more arrays of isolated
light-emitting island-like regions or pixel regions, or other
design patterns. The geometries of the light-emitting regions can
be various shapes and sizes, e.g., squares, rectangles or stripes.
Examples described below use a light-emitting screen that has
parallel light-emitting stripes separated by non-light-emitting
lines located between the light-emitting stripes. Each
light-emitting stripe can include a light-emitting material such as
a phosphor-containing material that either forms a contiguous
stripe line or is distributed in separated regions along the
stripe.
[0036] In one implementation, for example, three different color
phosphors or phosphor combinations that are optically excitable by
the laser beam to respectively produce light in red, green, and
blue colors suitable for forming color images may be formed on the
screen as pixel dots or repetitive red, green and blue phosphor
stripes in parallel. Various examples described in this application
use screens with parallel color phosphor stripes for emitting light
in red, green, and blue to illustrate various features of the
laser-based displays.
[0037] Phosphor materials are one type of fluorescent materials.
Various described systems, devices and features in the examples
that use phosphors as the fluorescent materials are applicable to
displays with screens made of other optically excitable,
light-emitting, non-phosphor fluorescent materials, such as quantum
dot materials that emit light under proper optical excitation
(semiconductor compounds such as, among others, CdSe and PbS).
[0038] Examples of scanning beam display systems described here use
at least one scanning laser beam to excite color light-emitting
materials deposited on a screen to produce color images. The
scanning laser beam is modulated to convey image information for
red, green and blue colors or in other visible colors and is
controlled in such a way that the laser beam excites the color
light-emitting materials in red, green and blue colors based on
image data from the red, green and blue color channels of the
image, respectively. Hence, the scanning laser beam carries the
image data but does not directly produce the visible light seen by
a viewer. Instead, the color light-emitting fluorescent materials
on the screen absorb the energy of the scanning laser beam and emit
visible light in red, green and blue or other colors to generate
actual color images seen by the viewer.
[0039] Laser excitation of the fluorescent materials using one or
more laser beams with energy sufficient to cause the fluorescent
materials to emit light or to luminesce is one of various forms of
optical excitation. In other implementations, the optical
excitation may be generated by a non-laser light source that is
sufficiently energetic to excite the fluorescent materials used in
the screen. Examples of non-laser excitation light sources include
various light-emitting diodes (LEDs), light lamps and other light
sources that produce light at a wavelength or a spectral band to
excite a fluorescent material that converts the light of a higher
energy into light of lower energy in the visible range. The
excitation optical beam that excites a fluorescent material on the
screen can be at a frequency or in a spectral range that is higher
in frequency than the frequency of the emitted visible light by the
fluorescent material. Accordingly, the excitation optical beam may
be in the violet spectral range and the ultra violet (UV) spectral
range, e.g., wavelengths under 420 nm. In the examples described
below, UV light or a UV laser beam is used as an example of the
excitation light for a phosphor material or other fluorescent
material and may be light at other wavelength.
[0040] In the above and other display implementations, multiple
display screens can be placed adjacent to one another in an array
to form a larger display screen. While the beam scanning may be
synchronized among the multiple display screens to allow for
synchronous operation among the multiple screens, real-time
adjustments to vertical adjusters, which are further described
below, may be made on a per screen basis. In some cases, the
orientations and adjustments of multiple, and sometimes all,
vertical adjusters in the array may be synchronized with each
other.
[0041] Referring to FIG. 1, a scanning beam display system based on
two-dimensional beam scanning is shown. For example, a polygon
scanner with different reflective polygon facets tilted at
different tilt facet angles can be used to produce a vertical array
of horizontal lines at different vertical positions on the screen.
The vertical array of lines may be parallel to one another. While
scanning is described below with respect to the polygon scanner,
various other types of scanners may also be used to produce the
horizontal lines. A vertical adjuster, for example a galvo-driven
mirror, can be used to adjust vertical positions of the horizontal
lines in one group to relative to vertical positions of the
horizontal lines in another group produced in time subsequent to
the prior group on the screen. The vertical adjuster can be
controlled to produce an interlaced scanning pattern formed by the
two or more groups of the horizontal lines or other scanning
patterns. As used herein, the vertical and horizontal directions
are used to represent two generally orthogonal directions and are
not intended to represent any specific directions such as the
vertical direction with respect to the earth's gravity.
Additionally, or alternatively, a beam that is scanned in the
vertical or horizontal directions may produce lines that are
non-linear, for example curved.
[0042] The system illustrated in FIG. 1 includes a screen 1 on
which images are displayed and an optical module 10 that produces
and scans one or more scanning optical beams 12 onto the screen 1.
An optical beam 12 is modulated to convey image information. For
example, the optical beam 12 can pulsed to be a sequence of laser
pulses that carry image data. The optical module 10 can scan the
one or more optical beams 12 in a raster scan pattern to display
the images on the screen 1, for example using the polygon scanner
and the vertical adjuster as described above, which may be included
as part of the scanning module inside the optical module 10. The
optical module can further include a scanning control module to
control the scanning of the beams.
[0043] When using the polygon scanner, the polygon scanner can be
positioned in optical paths of the one or more optical beams 12.
The polygon scanner is rotatable about a rotation axis along the
vertical direction. In operation, the polygon scanner rotates
around this rotation axis and the optical beams 12 impinge the
polygon scanner such that the polygon scanner scans the optical
beams 12 horizontally on the screen 1 along the horizontal scanning
direction as shown. The polygon is designed to have multiple
polygon facets that are sized to simultaneously receive the one or
more optical beams 12 directed from the one or more lasers. The
polygon facets are reflective to light of the optical beams 12 and
tilted with respect to the rotation axis at different tilt angles,
respectively, such that the different facets scan the optical beams
horizontally at different vertical positions on the screen,
respectively. The vertical adjuster is placed in the optical paths
of the optical beams 12 to adjust vertical positions of the optical
beams on the screen.
[0044] In operation, the polygon scanner rotates to scan the
scanning beams. Each polygon facet receives, reflects, and scans
the one or more beams 12 horizontally on the screen 1. The
immediate next polygon facet is tilted at a different tilt angle
from the previous facet and thus receives, reflects and scans the
same one or more beams 12 horizontally at different vertical
positions on the screen 1. In systems with multiple optical beams
12, the different optical beams from one polygon facet are directed
to different vertical positions on the screen 1. As different
polygon facets sequentially take turns to perform the horizontal
scanning of the one or more beams 12 as the polygon scanner
rotates, the vertical positions of the one or more beams 12 on the
screen 1 are stepped vertically at different positions along the
vertical stepping direction without a conventional vertical
scanner. During the time when a facet scans the one or more beams
12 on the screen 1, the vertical adjuster can be operated at a
fixed orientation so that each beam 12 is being scanned only along
the horizontal direction without a simultaneous vertical scanning.
After a full rotation of the polygon scanner and before its next
full rotation, the vertical adjuster can be operated to be at a
different fixed orientation so that each facet of the polygon
scanner during a succeeding rotation now scans the beams
horizontally at different vertical portions of the screen as
before. In some cases, the vertical adjuster may be adjusted during
a rotation of the polygon scanner such that, for example, the
position of the vertical adjuster is changed after each facet scans
the beams. In some cases, the vertical adjuster may be adjusted
while the facet scans the beams. Such adjustments made during the
rotation of the polygon scanner can help, for example, to improve
vertical fill in real time.
[0045] U.S. patent application Ser. No. 12/180,114 entitled "BEAM
SCANNING SYSTEMS BASED ON TWO-DIMENSIONAL POLYGON SCANNER" and
filed on Jul. 25, 2008 (now U.S. Pat. No. 7,869,112) describes
examples of polygon scanners suitable for use with the display
systems described in this application and is incorporated by
reference as part of the specification of this application.
[0046] FIG. 2 illustrates one example of interlaced raster scanning
that can be achieved, for example, using the 2D polygon scanner and
the vertical adjuster. Assuming, for example, that there are M
facets in the polygon and N optical beams 12, the tilt facet angles
of the polygon facets can be designed to vertically divide the
screen into M vertical segments to project N horizontal scan lines
in each vertical segment.
[0047] More specifically, as the polygon rotates, the different
facets direct and scan different vertical segments at different
times, one at a time. Hence, scanning by different polygon facets
in one full rotation of the polygon scanner produces a frame or
field of M.times.N horizontal scanning lines that are made of M
sequential sets of N simultaneous horizontal lines. This operation
provides both horizontal scanning by each facet and vertical
stepping by sequentially changing the polygon facets. Therefore, in
one full rotation, the polygon scanner produces one frame of a
sequential set of simultaneous horizontal scanning lines on the
screen produced by the polygon facets, respectively and each
polygon facet produces one set of simultaneous and horizontal
scanning lines.
[0048] Notably, during each full rotation, the vertical adjuster is
controlled to be at one of a predetermined number of orientation.
After completion of one full rotation of the polygon and before the
next full rotation of the polygon, the vertical adjuster is
operated to transition and stabilize to another one of the
predetermined number of orientations to thereby change vertical
positions of the optical beams 12 on the screen 1 to spatially
interlace horizontal scanning lines in one frame produced in one
full rotation of the polygon scanner with horizontal scanning lines
of a subsequent frame produced in an immediate subsequent full
rotation of the polygon scanner. The vertical adjuster and the
polygon scanner are synchronized to each other to perform the above
interlaced raster scanning. As further explained below, the number
of orientations for the vertical adjuster is determined so as to
maximize the vertical fill factor between adjacent laser beam
scans--in other words to minimize any gap between the horizontal
lines.
[0049] In the example shown in FIG. 2, each full frame image is
formed by three frames or fields, Field 1, Field 2, and Field 3,
which are spatially interlaced, with the line spacing between
adjacent lines produced by each facet being minimized or eliminated
altogether. Hence, the vertical adjuster in this example, is
operated to operate at three orientations, one orientation for the
Field 1, another for the Field 2, and yet another for the Field 3,
respectively. In this specific example, the rate for the vertical
adjustment of the beam position is only three orientation
adjustments per full frame. The vertical adjuster may switch
between the fields during a blanking period, which can be provided
after each full rotation of the polygon mirror by turning off the
beam for a short period of time, in order to minimize any undesired
visual effects on the screen. In this specific example, the
blanking typically occurs when the two adjacent facets with the
greatest change in tilt angle to the polygon rotation axis between
them are in transition from one facet to the other, when the beams
are to impinge on the one facet to the next.
[0050] Interlacing three image fields, where each field is
associated with a predetermined orientation of the vertical
adjuster, is illustrated in the example in FIG. 2. Here, the number
of scanning lines between two successive lines on the screen that
are produced by reflection of beams from a single polygon
facet--for example successive lines produced on the screen for
Field 1 by Laser 1 and Laser 2--is (P-1) where P is the number of
fields to be interlaced and is an integer not less than 3. That is,
to ensure that there are no imaging illumination gaps between
immediately vertically adjacent scanning lines that are ultimately
conveyed on to the screen over time, the scanning lines on the
screen formed by two neighboring laser beams reflected from a
single polygon facet should be spaced apart by two horizontal lines
or less in order to interlace three fields while avoiding any
vertical gaps there between. Additionally, interlacing additional
fields, for example going from two interlaced image fields to three
as described above, can help increase vertical resolution as having
more scanned lines can lead to higher pixel density in the vertical
direction.
[0051] Referring to FIG. 3, an example of a laser-based display
system using a screen having color phosphor stripes is shown.
Alternatively, color phosphor dots or quantum dot or quantum dot
regions may also be used to define the image pixels on the screen.
The illustrated system includes a laser module 110 to produce and
project at least one scanning laser beam 120 onto a screen 101. The
screen 101 has parallel color phosphor stripes in the vertical
direction where red phosphor absorbs the laser light to emit light
in red, green phosphor absorbs the laser light to emit light in
green and blue phosphor absorbs the laser light to emit light in
blue. Each group of three adjacent color phosphor stripes contains
stripes for the three different colors. One particular spatial
color sequence of the stripes is shown in FIG. 3 as red, green and
blue. Other color sequences may also be used.
[0052] The laser beam 120 is at the wavelength within the optical
absorption bandwidth of the color phosphors and is usually at a
wavelength shorter than the visible blue and the green and red
colors for the color images. As an example, the color phosphors may
be phosphors that absorb UV light in the spectral range from about
380 nm to about 420 nm to produce desired red, green and blue
light. The laser module 110 can include one or more lasers such as
UV diode lasers to produce the beam 120, a beam scanning mechanism
to scan the beam 120 horizontally and vertically to render one
image frame at a time on the screen 101, and a signal modulation
mechanism to modulate the beam 120 to carry the information for
image channels for red, green and blue colors. Such display systems
may be configured as rear light engine systems where the viewer and
the laser module 110 are on the opposite sides of the screen 101.
Alternatively, such display systems may be configured as front
light engine systems where the viewer and laser module 110 are on
the same side of the screen 101.
[0053] In the example scenario illustrated in FIG. 4A, the scanning
laser beam 120 is directed at the green phosphor stripe within a
pixel to produce green light for that pixel. FIG. 4B further shows
the operation of the screen 101 in a view along the direction B-B
perpendicular to the surface of the screen 101. Since each color
stripe is longitudinal in shape, the cross section of the beam 120
may be shaped to be elongated along the direction of the stripe to
maximize the fill factor of the beam within each color stripe for a
pixel. This may be achieved by using a beam shaping optical element
in the laser module 110. A laser source that is used to produce a
scanning laser beam that excites a phosphor material on the screen
may be a single mode laser or a multimode laser. The laser may also
be a single mode along the direction perpendicular to the elongated
direction phosphor stripes to have a small beam spread that is
confined by the width of each phosphor stripe. Along the elongated
direction of the phosphor stripes, this laser beam may have
multiple modes to spread over a larger area than the beam spread in
the direction across the phosphor stripe. This use of a laser beam
with a single mode in one direction to have a small beam footprint
on the screen and multiple modes in the perpendicular direction to
have a larger footprint on the screen allows the beam to be shaped
to fit the elongated color subpixel on the screen and to provide
sufficient laser power in the beam via the multimodes to ensure
sufficient brightness of the screen.
[0054] Accordingly, the laser beam 120, which is modulated to carry
optical pulses with image data, needs to be aligned with respect to
proper color pixels on the screen 101. The laser beam 120 is
scanned spatially across the screen 101 to hit different color
pixels at different times. Accordingly, the modulated beam 120
carries the image signals for the red, green and blue colors for
each pixel at different times and for different pixels at different
times. Hence, the beams 120 are coded with image information for
different pixels at different times. The beam scanning thus maps
the timely coded image signals in the beams 120 onto the spatial
pixels on the screen 101.
[0055] A scanning display system described in this application can
be calibrated during the manufacture process so that the laser beam
on-off timing and position of the laser beam relative to the
fluorescent stripes in the screen 101 are known and are controlled
within a permissible tolerance margin in order for the system to
properly operate with specified image quality. However, the screen
101 and components in the laser module 101 of the system can change
over time due to various factors, such as scanning device jitter,
changes in temperature or humidity, changes in orientation of the
system relative to gravity, settling due to vibration, aging, and
others. Such changes can affect the positioning of the laser source
relative to the screen 101 over time and thus the factory-set
alignment can be altered due to such changes. Notably, such changes
can produce visible and, often undesirable, effects on the
displayed images. For example, a laser pulse in the scanning
excitation beam 120 may hit a subpixel that is adjacent to an
intended target subpixel for that laser pulse due to a misalignment
of the scanning beam 120 relative to the screen along the
horizontal scanning direction. When this occurs, the coloring of
the displayed image is changed from the intended coloring of the
image. Hence, a red spot in the intended image may be displayed as
a green spot on the screen as the beam is on when the beam is over
the green phosphor region, instead of the intended adjacent red
phosphor region. For another example, a laser pulse in the scanning
excitation beam 120 may hit both the intended target subpixel and
an adjacent subpixel next to the intended target subpixel due to a
misalignment of the scanning beam 120 relative to the screen along
the horizontal scanning direction. When this occurs, the coloring
of the displayed image is changed from the intended coloring of the
image and the image resolution deteriorates. The visible effects of
these changes can increase as the screen display resolution
increases because a smaller pixel means a smaller tolerance for a
change in position. In addition, as the size of the screen
increases, the effect of a change that can affect the alignment can
be more pronounced because a large moment arm associated with a
large screen means that an angular error can lead to a large
position error on the screen. For example, if the laser beam
position on the screen for a known beam angle changes over time,
the result is a color shift in the image. This effect can be
noticeable and thus undesirable to the viewer.
[0056] A feedback control alignment mechanism can be provided in
the system in FIG. 3 to maintain proper alignment of the scanning
beam 120 on the desired subpixel to achieved desired image quality.
The screen 101 is used to provide a screen feedback signal 130 to
indicate the alignment status of the beam 120 using timing
information. The alignment feedback control system determines
spatial information derived from timing information, the control
module 110 responds to the timing information in the screen
feedback to control the scanning beam 120 to compensate for spatial
positioning error. Such feedback control can include reference
marks on the screen 101, both in the fluorescent area and in one or
more peripheral area outside the fluorescent area, to provide
feedback light that has a timing and/or positioning effect on the
excitation beam 120 and represents the position and other
properties of the scanning beam on the screen 101. The feedback
light can be measured by using one or more optical servo sensors to
produce a feedback servo signal. A servo control in the laser
module 110 processes this feedback servo signal to extract the
information on the beam positioning and other properties of the
beam on the screen and, in response, adjust the timing of the
scanning beam 120 modulation to ensure the proper operation of the
display system. The feedback light may be the same light as the
excitation light or a light of a frequency different from the
excitation light. The feedback light may be an IR range light that
is used to detect the reference marks on screen 101 The IR laser
position is calibrated against the scanning beam 120 using on or
off panel reference marks.
[0057] For example, a feedback servo control system can be provided
to use peripheral servo reference marks positioned outside the
display area unobservable by the viewer to provide control over
various beam properties, such as the horizontal positioning along
the horizontal scanning direction perpendicular to the fluorescent
stripes, the vertical positioning along the longitudinal direction
of the fluorescent stripes, the beam focusing on the screen for
control the image sharpness, and the beam power on the screen for
control the image brightness.
[0058] For another example, a screen calibration procedure can be
performed at the startup of the display system to measure the beam
position information as a calibration map. This calibration map is
then used by the laser module 110 to control the timing and
positioning of the scanning beam 120 to achieve the desired color
purity. In some cases, the calibration procedure can also include
measuring beam footprint information as a function of the beam
position, as further detailed below. For yet another example, a
dynamic servo control system can be provided to regularly update
the calibration map during the normal operation of the display
system by using servo reference marks in the fluorescent area of
the screen to provide the feedback light without affecting the
viewing experience of a viewer.
[0059] Referring now to FIG. 5, an example implementation of the
laser module 110 in FIG. 3 is illustrated. A laser array 310 with
multiple lasers is used to generate multiple laser beams 312 to
simultaneously scan the screen 101 for enhanced display brightness.
A signal modulation controller 320 is provided to control and
modulate the lasers in the laser array 310 so that the laser beams
312 are modulated to carry the image to be displayed on the screen
101. The signal modulation controller 320 can include a digital
image processor that generates digital image signals for the three
different color channels and laser driver circuits that produce
laser control signals carrying the digital image signals. The laser
control signals are then applied to modulate the lasers, e.g., the
currents for laser diodes, in the laser array 310.
[0060] The beam scanning in the system illustrated in FIG. 5 may be
achieved by using a vertical adjuster 340 such as a galvo mirror
for the vertical scanning and a multi-facet polygon scanner 350
with different facets tilted at different angles. A scan lens 360
can be used to focus the scanning beams form the polygon scanner
350 onto the screen 101. The scan lens 360 is designed to image
each laser in the laser array 310 onto the screen 101. Each of the
different reflective facets of the polygon scanner 350
simultaneously scans N horizontal lines where N is the number of
lasers. In the illustrated example, the laser beams are first
directed to the vertical adjuster 340 and then from the vertical
adjuster 340 to the polygon scanner 350 which scans the received
laser beams as output scanning beams 120 onto the screen 101. A
relay optics module 330 may be placed in the optical path of the
laser beams 312 to modify the spatial property of the laser beams
312 and to produce a closely packed bundle of beams 332 for
scanning by the polygon scanner 350. The scanning beams 120 focused
onto the screen 101 excite the phosphors and the optically excited
phosphors emit colored light to display visible images. The laser
beams 312, 120 are illustrated in FIG. 5 as separated along
horizontal axis so that the multiple beams can be seen; but in
practice the beams would be aligned horizontally and separated
along the vertical axis (into/out of the page).
[0061] The laser beams 120 are scanned spatially across the screen
101 to hit different color pixels at different times. Accordingly,
each of the modulated beams 120 carries the image signals for the
red, green and blue colors for each pixel at different times and
for different pixels at different times. Hence, the beams 120 are
coded with image information for different pixels at different
times by the signal modulation controller 320. The beam scanning
thus maps the time-domain coded image signals in the beams 120 onto
the spatially based pixel locations on the screen 101. For example,
the modulated laser beams 120 can have each color pixel time
equally divided into three sequential time slots for the three
color subpixels for the three different color channels. The
modulation of the beams 120 may use pulse modulation techniques to
produce desired grey scales in each color, a proper color
combination for each pixel, and desired image brightness. The
modulation being a pulse width modulation, a pulse amplitude
modulation, or a combination of both. The laser diodes are also
separately biased with a proper threshold current to enable fast
rise and fall times or switching speeds.
[0062] In some implementations, an imaging module 370 can be placed
in the optical path between the vertical adjuster 340 and the
polygon to image the surface of the reflective surface of the
vertical adjuster 340 onto a polygon facet that currently reflects
the beams to the screen 101. This imaging effectively makes the
vertical adjuster 340 coincident with the currently reflecting
polygon facet which, in turn, is coincident with the entrance pupil
of the scan lens 360. Therefore, the entrance pupil of the scan
lens 360 is the pivot point for the scanning beams directed to the
scan lens 360. The imaging module 370 can be in various optical
configurations and may include, for example, two lenses in a 4F
imaging configuration with a magnification of 1.
[0063] In some implementations, the scanning beam display system
can include an invisible servo beam to provide additional
positional feedback. For example, a controller 380 can be used to
provide control functions and control intelligence based on servo
detector signals from one or more servo beam detectors 390 that
detect servo feedback light from the screen 101. U.S. patent
application Ser. No. 11/769,580 entitled "SERVO FEEDBACK CONTROL
BASED ON INVISIBLE SCANNING SERVO BEAM IN SCANNING BEAM DISPLAY
SYSTEMS WITH LIGHT-EMITTING SCREENS" and filed on Jun. 27, 2007
(now U.S. Pat. No. 7,878,657) describes examples of servo feedback
control suitable for use with the display systems described in this
application and is incorporated by reference as part of the
specification of this application.
[0064] In some implementations, a beam footprint detector 400 may
be provided in the display system to output a measured footprint of
the focused beam on the screen 101. Alternatively, or additionally,
the beam footprint detector 400 may be a standalone measurement
device that can be used to measure beam footprint information at
multiple different positions on the screen. The beam footprint
measurement can be recorded for each subpixel of the screen on
which the beam is focused in order to, for example, produce a beam
footprint map for the entire screen. Beam footprint information can
include a height and a width of the optical beam that is projected
on the screen 101 as the beam is modulated and scanned across the
screen 101. In some implementation the beam footprint information
can include an arbitrary shape of the optical beam that is
projected on the screen 101 and that may change as the beam is
modulated and scanned across the screen 101. In some implementation
the beam footprint information can include information about
intensity hot spots within the detected shape of the optical beam
that is projected on the screen 101 as the beam is modulated and
scanned across the screen 101. The control system 380 may be
configured to access a memory 402 that can store the beam footprint
information associated with each beam position on the screen. In
some cases, beam footprint information may be pre-stored onto the
memory 402, either through information obtained via the footprint
detector 400 or via other means. Alternatively, or additionally,
the beam footprint information may be entered/updated in real time
during operation of the display system based on input from the
footprint detector 400.
[0065] As noted above, any gaps between adjacent scanning lines
projected on the screen should be avoided. Otherwise, the viewer
may be able to detect a black line that runs across the screen,
particularly if the viewer is positioned close to the screen.
Accordingly, the vertical adjuster should be configured to have a
sufficient number of positions so that there are no gaps between
vertically adjacent beam projections over time.
[0066] FIG. 6 illustrates an example scenario of displaying on the
screen 101 by interlacing two fields. Here, an array of N
vertically spaced laser beams are scanned horizontally across the
screen 101 to create S swaths that fill the screen 101, each swath
being created by, for example, scanning the beam array using a
respective facet of a polygon scanner with S facets. By stepping
the vertical adjuster back and forth between two predetermined
orientations following each rotation of the polygon mirror, two
fields F1 and F2 are interlaced to increase the fill factor.
[0067] Looking at a close-up view 408 of one of the swaths and
further referring to FIG. 7, because the vertical pitch p' between
adjacent beam projections, or beam footprints, 412 is greater than
the height h' of each projection along the vertical axis, gaps 410
may be present between vertically adjacent beam footprints. The
gaps 410 may be observed by the viewer as black lines or partial
black lines that streak across the screen 101.
[0068] The shape of the beam footprint 412 as shown in FIG. 7 is
merely exemplary and can include various other shapes that are
associated with different beam profiles. The dark region 413 within
the footprint represents a region of peak intensity for the focused
beam. In some cases, for example when multimode lasers are used to
produce the optical beams, multiple peaks may be present. It should
be noted that the beam footprints shown in FIG. 7 for Row A
correspond to projections that a modulated optical beam produces on
the screen during a period of time for one of the interlaced
fields. That is, the series of beam footprints 412 shown for Row A
represent the horizontal stepping of a single beam across the
screen over time. Similarly, the beam footprints shown in Row B
correspond to such projections for the interlaced field situated
immediately below. While only one instantaneous beam footprint may
be projected at a time for each row, a latent image of such a
footprint may remain for a short period of time on the phosphor
stripes, thereby allowing the screen to be filled with the desired
image. Alternatively, or additionally, the latent image may remain
within the viewer's eye as the eye has an integration time that
captures the entire scanning area and perceives it as one.
[0069] FIG. 8 illustrates an example scenario of filling the screen
101 by interlacing three fields. The same array of N vertically
spaced laser beams as shown in FIG. 6 are again scanned
horizontally across the screen 101 to create S swaths that fill the
screen 101. However, by stepping the vertical adjuster through
three, instead of two, orientations after each polygon rotation,
three fields F1, F2, and F3 are interlaced to further increase the
fill factor or add more vertical resolution.
[0070] Looking at a close-up view 414 of one of the swaths and
further referring to FIG. 9, because the vertical pitch p'' between
adjacent beam footprints is now less than or equal to the height
h'' of each scanned beam along the vertical axis, no gaps are
created between vertically adjacent beam footprints. In other
words, by providing an additional vertical adjuster position to the
system illustrated in FIGS. 5 and 6, the fill factor may be
improved without having to increase the height of the scanned beam.
As increasing the height of the scanned beam may cause crosstalk
issues if the beam were to rotate as it scans across the screen
leading to spillover of energy from one phosphor color to another.
This is illustrated in FIG. 11. Moreover, increase the density of
scanned beams vs. increasing the height of the beam has the
advantage of increasing image resolution (as each additional
scanned field carry image information).
[0071] While FIGS. 8 and 9 show that the beams within a swath are
positioned vertically equidistant from each other, the beams may be
positioned non-equidistant distances away from each other. To
create equally separated beams, the vertical adjuster may be
configured to at orientations that are separated by equidistant
angles. In some cases, due for example to pre-existing or
time-dependent variations within the display system, the vertical
adjuster may be configured to be at orientations that are separated
by non-equidistant angles in order to project vertically
equidistant beams on the screen. In some cases, the vertical
adjuster orientations may be configured to intentionally produce
beams within a swath that are positioned at non-equidistant
distances from each other in the vertical direction. The actual
setting for the vertical adjuster orientations may be determined
experimentally to yield optimal picture quality and may depend on a
number of factors. For example, height of each optical beam, the
beam's angle of incidence relative to the screen, movement range of
the vertical adjuster, beam profile, properties of the polygon
scanner, positioning tolerance of the vertical adjuster's
orientations, etc. may all have an impact on how the vertical
adjuster orientations are determined.
[0072] Referring to FIG. 10, an example scenario is shown where the
beam footprints associated with Row B (or Field 2) is shifted
vertically downward, thereby creating gaps 420 between the beams in
Rows A and B while creating bright spots 422 between the beams in
Rows B and C that can result from excessive overlap between the
beams. These kinds of anomalies may be global or localized to
particular locations on the screen. Moreover, such anomalies may be
known beforehand through footprint or scanning distortion
information stored in memory 402 or may be detected in real-time
using the footprint detector 400 or scanning image intensity maps
that is integrated within the display system.
[0073] Based on the beam footprint and scanning image intensity
maps information, the control system 380 (FIG. 5) can set or apply
an adjustment angle, or offset, to be associated with each
predetermined orientation of the vertical adjuster to eliminate any
unwanted gaps 420 or bright spots 422 between vertically adjacent
footprints. The adjustment angle implemented may depend on the
position of the beam footprint on the screen. In some cases, the
adjustment may be made while the beam is being scanned
horizontally.
[0074] As noted above, beam footprint or trajectory can vary
depending on where on the screen the beam is projected. Such
variation can be an inherent characteristic of the particular
optical system and/or may be introduced over time due to various
time-dependent factors (e.g., gravity, vibration,
temperature/humidity change, etc.)
[0075] Referring further to FIG. 11, due to inherent
characteristics of the optical system for example, the beam
footprints may be tilted near the horizontal extremes of the
screen. For example, beams projected near a left end of the screen
may be rotated up to 9 degrees in one direction, while beams
projected near a right end of the screen may be rotated up to 9
degrees in the opposite direction. Due to such rotation, or
tilting, of the beams, an effective height of the beam footprints
may be reduced in such regions, resulting in gaps 430 being formed
between vertically adjacent beam footprints. Accordingly, when
determining the number of vertical adjuster positions that will
result in the minimization of gaps, basing the determination up the
smallest vertical height of a beam footprint found on the screen
can ensure that no gaps are formed even in the regions of the
screen where due to rotation of the beams or for other reasons the
effective height of the beam footprint is reduced.
[0076] FIGS. 12 and 13 illustrate examples of other types of
variations that can lead to non-uniform filling of the screen. For
example, as shown in FIG. 12, vertical and horizontal bow
distortions can occur when using a two-dimensional f-theta scan
lens located in the optical path between the scanning optical
module (e.g., the polygon 350 and galvo mirror 340) and the screen
101. As illustrated, the bow distortion in each direction increases
from the center of the screen towards the edge of the screen as the
incident angle of the light to the scan lens increases.
[0077] FIG. 13 shows an example of a map of measured beam positions
on a screen with the above-noted optical bow distortions. The
effects of the vertical and horizontal bow distortions caused by a
scan lens assembly can be measured, for example, together with the
beam footprint measurement. Based on the measured distortions,
e.g., beam spot spacing variations, the optical energy of the
optical pulses can be adjusted to counter the non-uniformity in
screen brightness caused by the measured distortions. U.S. patent
application Ser. No. 12/796,591 entitled "LOCAL DIMMING ON
LIGHT-EMITTING SCREENS FOR IMPROVED IMAGE UNIFORMITY IN SCANNING
BEAM DISPLAY SYSTEMS" and filed on Jun. 8, 2010, describes examples
of removing distortions and improving image uniformity and is
incorporated by reference as part of the specification of this
application.
[0078] Referring again to FIG. 10, bright spots 422 can occur when
the vertically overlapping portions between adjacent beam
footprints are too large. Such a phenomenon can occur for display
systems where the number of vertical adjuster positions has been
set in order to maximize the fill factor by eliminating potential
gaps. In such cases, the optical energies, or intensities,
associated with the corresponding optical pulse may be reduced for
one of the overlapping beam pulses or the other or both, thereby
remapping the intensity distribution so that the observer does not
see hot spots. By decreasing the intensity of the beams associated
with the excess overlap, the brightness of the overlapping portion
may be reduced and appear more uniform to the viewer.
[0079] FIG. 14 illustrates a region of the screen where the
parallel horizontal scanning lines converge along the scanning
direction. So while no gaps or bright spots may be formed for beam
footprints in column S, the use of beam footprints having the same
height in the converged columns, for example column T, can lead to
excess overlap that results in bright spots 440. However, by
correspondingly reducing the optical energies associated with the
converged beams to decrease intensity of the respective beams, the
bright spots 440 may be reduced--as illustrated in FIG. 15.
[0080] As explained above, the spacing between a pair of adjacent
beam footprints should be such that the vertical fill factor is
maximized. This is generally achieved when the pitch between
adjacent footprints is equal to or less than the height of the
associated beam footprint. However, because laser beams, and other
types of optical beams, can have different kinds of beam profiles,
the "height" of the beam may not always be clearly defined.
[0081] For example, referring further to FIG. 16A, given a Gaussian
profile of the optical beams' energy, two vertically adjacent
footprints may be considered to have no gap therebetween if there
is a vertical overlap between the beams that is greater than a
first threshold, where the first threshold can represent a non-zero
minimal vertical overlap that is required to eliminate the
appearance of a gap to the user and help improve brightness
uniformity. Because the distance between vertically adjacent beam
footprints, or pitch P, as well as an effective height H of a beam
footprint can both vary as a function of position on the screen,
the determination of what the first threshold should be can be made
based on a screen location having the largest difference between P
and H, thereby ensuring that a gap is avoided for all recorded beam
positions on the screen. The beam footprint and position
information as used in this determination may be obtained from the
beam footprint measurement process as noted above.
[0082] In some cases, where the beam profile is Gaussian, the first
threshold may represent the point at which points associated with
the 1/e.sup.2 widths of the respective beams pass each other. In
some cases, the first threshold may be derived experimentally based
on the particular characteristics of the display system and/or the
viewer (e.g., viewing distance). As another example, the optical
beam can have a trapezoidal profile, as illustrated in FIG. 16B, or
a multimode shape as in FIG. 16C. Alternatively, in some cases, the
first threshold may represent the point at which the respective
tails of the beams just begin to touch each other.
[0083] Referring back to FIGS. 14 and 15, it was noted that excess
overlap between adjacent beam footprints can result in bright spots
440. To avoid such bright spots, the optical energies associated
with the beam footprints at issue may be decreased so that, for
example, the size that is associated with the overlapping region
does not surpass a second threshold. That is, by further relying on
the collected beam footprint data to decrease the intensities of
one or both of the overlapping beams so that the associated
intensity of the overlapping region is less than this second
threshold, bright spots may be avoided across the entire screen.
Accordingly, by ensuring that the overlapping region is greater
than the first threshold but less than the second threshold, both
gaps and bright spots may be avoided. In some cases, the second
threshold may refer not to the size of the overlapping region but
rather the intensity that is associated with such region. In other
words, once the size of the overlap between adjacent beam
footprints satisfy the first threshold, thereby ensuring no gap,
the resulting intensity of the overlapping region can be controlled
to be kept below the second threshold, thereby ensuring that the
appearance of bright spots is avoided.
[0084] When decreasing the optical energy of the affected beam, the
height of the beam footprint as perceived by the user may decrease
correspondingly. However, the energy decrease should be controlled
such that the resulting beam height does not lead to an overlapping
region that falls below the first threshold (i.e. creates gaps).
The second threshold may be based on intensity, thus indicating a
maximum intensity that the overlapping region should stay under.
Notably, the optical energy may be adjusted on a per pixel basis,
thereby allowing the adjustment of size/intensity for individual
pixels. While the energy for each pixel is also dynamically
controlled by corresponding image data, for example to display a
moving picture on the screen, the second threshold effectively
serves as a gain-controlling mechanism that limits the maximum
intensity produced in the overlapping region.
[0085] In some cases, the second threshold may be based on size,
thus indicating a maximum allowable physical size of the
overlapping region. For example, referring to FIG. 16A, the second
threshold may represent the amount of overlap at which the points
associated with the 1/e.sup.2 widths of the respective beams pass
each other. In some cases, the second threshold may represent the
amount of overlap at which the points associated with the full
width half maximum of the Gaussian beams pass each other. Referring
to the trapezoidal beam profile shown in FIG. 16B, the second
threshold may represent the amount of overlap at which the points
associated with the half widths of the beams pass each other.
[0086] In some implementations, the image information associated
with each video frame buffer may not be in a format compatible with
the number of orientations of the vertical adjuster. For example,
referring to FIG. 17A, a series of images shown on the screen over
time is represented as Image 1, Image 2, Image 3, etc. Here, each
image is shown as having a set of pixel values A associated with
Field 1 and a second set of pixel values B associated with Field 2.
Thus, by switching the vertical adjuster back and forth between
positions corresponding Field 1 and Field 2, a single image made up
of pixel values A and B can be displayed on the screen.
[0087] However, if the imaging system of FIG. 17A is modified to
include three fields (Field 1-3) that correspond to three distinct
positions of the vertical adjuster, then additional pixel values
may be needed. For example, if pixel value A is assigned to Field 1
and pixel value B is assigned to Field 3, then an additional pixel
value will be needed for Field 2. One example scheme for filling
the added field is shown in FIG. 17B. Here, the pixel value for
Field 1 (A) and the pixel value from Field 3 (B) are alternately
assigned to Field 2 over time in order to provide a vertically
filled image. Alternatively, FIG. 17C illustrates an interpolation
method in which the pixel value for Field 2 is interpolated, in
this case through simple averaging, from the pixel values of Field
1 and Field 3. Various other types of filling and interpolation
methods may be utilized in assigning an appropriate pixel value to
the added field. As another example, a cubic interpolation method
based on 4 points may be used.
[0088] Of course, interpolation and other pixel filling methods may
not be needed if there is sufficient pixel data to fill the added
field. For example, FIG. 17D illustrates pixel values A, B, and C
being assigned to Fields 1, 2, and 3, respectively. The additional
pixel value corresponding to the added field may be available, for
example, if the native resolution is increased correspondingly.
[0089] In some cases, a two-field imaging system may rely on a
video frame that is rendered, or painted across the screen,
multiple times before progressing to the next video frame. For
example, if a video frame is updated at 60 Hz, then each video
frame may be refreshed 8 times at 480 Hz on the screen. More
specifically, as shown in Images 1-4 in FIG. 18A, a single video
frame may yield 8 refreshes on the screen, with each refresh
corresponding to a distinct pixel value. As further illustrated in
FIG. 18A, the first two refreshes for video frame 1 may lead to
displaying a first image Image 1 on the screen that is made up of
pixel value A and pixel value B. The subsequent two refreshes for
video frame 1 may lead to displaying a second image Image 2 that is
made up of pixel values A and B. Once 8 refreshes in total have
been completed (forming Images 1-4 on the screen over time in the
process), the video frame will update to video frame 2, and Images
5-8 will then be displayed in a similar manner. For a polygon
scanner-based system, each render/refresh may correspond to a
single full rotation of the polygon scanner.
[0090] Referring now to FIG. 18B, a three-field imaging system is
shown. However, if the 8 refreshes per video frame scheme is
maintained, there may be instances where there is insufficient
pixel information. In other words, because a three-field system as
illustrated in FIG. 18B requires 3 refreshes to form one complete
image on the screen (as opposed two 2 refreshes in the previous
example shown in FIG. 18A), a video frame that is rendered 8 times
as before may only be able to provide enough pixel information for
2 and 2/3 images. In such cases, pixel value from the subsequent
video frame may be used to fill the missing 1/3 image. For example,
looking at FIG. 18B, relying on just the 8 refreshes of video frame
1 would not provide a sufficient number of pixel values to cover
the bottom 1/3 of Image 3; however, as shown, the corresponding
pixel value from video frame 2 may be assigned to Field 3 of Image
3 in order to completely fill Image 3. This way, video frames
designed for a two-field imaging system may be used in a
three-field system without changing the associated refresh
rates.
[0091] While this document contains many specifics, these should
not be construed as limitations on the scope of an invention or of
what may be claimed, but rather as descriptions of features
specific to particular embodiments of the invention. Certain
features that are described in this document in the context of
separate implementations can also be implemented in combination in
a single implementation. Conversely, various features that are
described in the context of a single implementation can also be
implemented in multiple implementations separately or in any
suitable subcombination. Moreover, although features may be
described above as acting in certain combinations and even
initially claimed as such, one or more features from a claimed
combination can in some cases be excised from the combination, and
the claimed combination may be directed to a subcombination or a
variation of a subcombination.
[0092] Only a few implementations are disclosed. However, it is
understood that variations, enhancements, and other implementations
can be made based on what is described and illustrated in this
application.
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