![[US Patent & Trademark Office, Patent Full Text and Image Database]](/netaicon/PTO/patfthdr.gif)
| United States Patent |
5,751,272
|
|
Silverbrook
, et al.
|
May 12, 1998
|
Display pixel balancing for a multi color discrete level display
Abstract
A pixel display includes a pixel pattern containing multiple pixels each of
which having multiple primary color sub-regions of illumination. These
sub-regions are arranged such that they extend in a first direction
substantially from one side of the pixel to the other, and in a second
direction, substantially normal to the first direction, they have only a
limited extent in the pixel. These sub-regions include a multiple number
of illumination areas and are arranged such that the center of
illumination is substantially stable with respect to movement in the first
direction and is substantially constrained to movement in the second
direction.
| Inventors:
|
Silverbrook; Kia (Leichhardt, AU);
Naylor, Jr.; William Clark (Santa Clara, CA)
|
| Assignee:
|
Canon Kabushiki Kaisha (Tokyo, JP)
|
| Appl. No.:
|
402507 |
| Filed:
|
March 13, 1995 |
Foreign Application Priority Data
| Mar 11, 1994[AU] | PM4402 |
| Mar 11, 1994[AU] | PM4408 |
| Current U.S. Class: |
345/694; 349/144 |
| Intern'l Class: |
G09G 003/36 |
| Field of Search: |
345/149,147,152,43,103,89
349/144,146,85
|
References Cited [Referenced By]
U.S. Patent Documents
| 4811003 | Mar., 1989 | Struthman et al. | 345/152.
|
| 4965565 | Oct., 1990 | Noguchi | 345/93.
|
| 5124695 | Jun., 1992 | Green | 345/149.
|
| 5157524 | Oct., 1992 | Dijon et al. | 359/54.
|
| 5552800 | Sep., 1996 | Uchikoga et al. | 345/149.
|
| Foreign Patent Documents |
| 0322106 | Jun., 1989 | EP.
| |
| 0526135 | Feb., 1993 | EP.
| |
| 2637407 | Apr., 1990 | FR.
| |
| 59-128058 | Mar., 1986 | JP.
| |
Primary Examiner: Lee; Michael H.
Attorney, Agent or Firm: Fitzpatrick, Cella, Harper & Scinto
Claims
We claim:
1. A display having a pixel pattern comprising a multiplicity of pixels
with each pixel having a multiplicity of primary colour sub-regions of
illumination each of which further comprises a multiplicity of
illumination areas, the illumination areas being able to be set to an
illuminating state or a non-illuminating state wherein:
(a) the primary colour sub-regions extend in a first direction
substantially from one side of the pixel to the other, but in a second
direction substantially normal to the first direction have only a limited
extent in the pixel; and
(b) the colour sub-regions are arranged to be able to be illuminated with
changing intensity with a centre of illumination which is substantially
stable with respect to movement in the first direction and is
substantially constrained to movement in the second direction.
2. A display as claimed in claim 1 wherein the multiplicity of primary
colours comprises red, blue and green.
3. A display having a pixel pattern comprising a multiplicity of pixels
with each pixel having a multiplicity of primary colour sub-regions of
illumination each of which further comprises a multiplicity of
illumination areas, the illumination areas being able to be set to an
illuminating state or a non-illuminating state wherein:
(a) the primary colour sub-regions extend in a first direction
substantially from one side of the pixel to the other, but in a second
direction substantially normal to the first direction have only a limited
extent in the pixel;
(b) the colour sub-regions are arranged to be able to be illuminated with
changing intensity with a centre of illumination which is substantially
stable with respect to movement in the first direction and is
substantially constrained to movement in the second direction and wherein
the distance between the centre of illumination of any primary colour
sub-region and the centre of illumination of the next adjacent pixel in
the first direction is substantially equal to the distance between the
centre of illumination of the primary colour sub-region and the centre of
illumination of the corresponding primary colour sub-region of the next
adjacent pixel in the second direction.
4. A display as claimed in claim 3 wherein the multiplicity of primary
colours comprises red, blue and green.
5. A display having a pixel pattern comprising a multiplicity of pixels
with each pixel having a multiplicity of primary colour sub-regions of
illumination each of which further comprises a multiplicity of
illumination areas, the illumination areas being able to be set to an
illuminating state or a non-illuminating state wherein:
(a) the primary colour sub-regions extend in a first direction
substantially from one side of the pixel to the other but in a second
direction substantially normal to the first direction have only a limited
extent in the pixel;
(b) the colour sub-regions are arranged to be able to be illuminated with
changing intensity with a centre of illumination which is substantially
stable with respect to movement in the first direction and is
substantially constrained to movement in the second direction and wherein
at least one distance between the centre of illumination of any primary
colour sub-region and the corresponding primary colour sub-region of any
next adjacent pixel is maximized.
6. A display as claimed in claim 5 wherein the multiplicity of primary
colours comprises red, blue and green.
7. A method of determining a pixel layout pattern for a discrete level
display, the display comprising a multiplicity of pixels, with each pixel
including a multiplicity of primary colour sub-regions of illumination and
each primary colour sub-region of illumination further comprising a
multiplicity of illumination areas with each illumination area setable to
an illuminating or a non illuminating state, said method comprising the
steps of:
(a) determining a distance measure from the centre of the primary colour
sub-region to the centre of each corresponding primary colour sub-region
of adjacent next pixels;
(b) determining a minimum of the distance measures;
(c) determining a series of patterns of the illumination areas, each
pattern of the series having an optical centre of illumination whose
distance remains substantially constant with respect to the corresponding
optical centre of illumination of a closest adjacent next primary colour
sub-region but whose optical centre is able to move in a normal direction
thereto.
8. A pixel layout pattern for a multi colour discrete level display, the
display including a multiplicity of pixels, with each pixel including a
multiplicity of primary colour sub-regions of illumination and each
primary colour sub-region of illumination further comprising a
multiplicity of illumination areas, with each illumination being area
setable to an illuminating or a non illuminating state, wherein the
illumination areas are divided into a series of illumination levels, each
illumination level having an optical centre of illumination and wherein a
first pixel direction is defined to be the shortest distance from the
optical centre of illumination of the primary colour sub-region to the
centre of a neighbouring corresponding primary colour sub-region and
wherein the optical centre of illumination remains substantially constant
for each level with respect to the first direction while the optical
centre is able to be moved in a direction substantially normal to the
first direction.
9. A pixel layout pattern as claimed in claim 8, wherein the multiplicity
of primary colours comprises red, green and blue.
10. A display having a pixel pattern comprising a multiplicity of
sub-regions, wherein:
(a) the sub-regions consist of a first sub-region, a second sub-region
arranged at one side of a first direction of the first sub-region, a third
and a fourth region arranged at both sides of a second direction of either
one of the first and the second sub-regions and a fifth and a sixth
sub-region arranged at both sides of the second direction of the other of
the first and the second sub-regions; and
(b) the ratio of the area of the first sub-region, the second sub-region,
the third and the fourth sub-regions together and the fifth and the sixth
sub-regions together is 1:2:4:8.
11. A display according to claim 10, wherein the third and the fourth
sub-regions are set to an illuminating state or non-illuminating state in
response to an image signal.
12. A display according to claim 10, wherein the first and the second
sub-regions are on a same first common line.
13. A display according to claim 10, wherein the third and the fourth
sub-regions are on a same first segment line, and the fifth and the sixth
sub-regions are on a same second segment line.
14. A display according to claim 12 or 13, wherein the third and the fifth
sub-regions are on a same second common line, and the fourth and the sixth
sub-regions are on a same third common line.
15. A display according to claim 13, wherein the first sub-region is on the
first segment line, and the second sub-region is on the second segment
line.
16. A display according to claim 10, wherein the display is a liquid
crystal display.
17. A colour display where at least two pixel patterns of pixel patterns
provided for each colour comprise a multiplicity of sub-regions,
respectively, wherein:
(a) the sub-regions consist of a first sub-region, a second sub-region
arranged at one side of a first direction of the first sub-region, a third
and a fourth region arranged at both sides of a second direction of either
one of the first and the second sub-regions and a fifth and a sixth
sub-region arranged at both sides of the second direction of the other of
the first and the second sub-regions; and
(b) the ratio of the area of the first sub-region, the second sub-region,
the third and the fourth sub-regions together and the fifth and the sixth
sub-regions together is 1:2:4:8.
18. A display according to claim 17, wherein the third and the fourth
sub-regions are set to an illuminating state or non-illuminating state in
response to an image signal.
19. A display according to claim 17, wherein the first and the second
sub-regions are on a same first common line.
20. A display according to claim 17, wherein the third and the fourth
sub-regions are on a same first segment line, and the fifth and the sixth
sub-regions are on a same second segment line.
21. A display according to claim 19 or 20, wherein the third and the fifth
sub-regions are on a same second common line, and the fourth and the sixth
sub-regions are on a same third common line.
22. A display according to claim 20, wherein the first sub-region is on the
first segment line, and the second sub-region is on the second segment
line.
23. A display according to claim 17, wherein said display is a liquid
crystal display.
Description
FIELD OF THE INVENTION
The present invention relates to the display of Colour Images, and, in
particular, to the display of colour images on a discrete level display
device such as a plasma panel display or a liquid crystal display device.
BACKGROUND OF THE INVENTION
U.S. Pat. No. 5,124,695 (Green/Thorn EMI) discloses a monochrome discrete
level display adapted to display a gray scale, in which each pixel is
formed of four separately energizable areas which have relative light
intensity outputs in the ratio of 1:2:4:8 respectively. FIG. 5 of U.S.
Pat. No. 5,124,695 is reproduced as FIG. 1 herein. Each of the areas of
illumination having Roman numerals I-IV has a number of portions, which
are spaced-apart and concentrically arranged, in order to have the same
average position when illuminated, so that different bit patterns cause
the pixel to change in brightness only, without any apparent change in
position.
As best seen from FIG. 5 of this U.S. patent (FIG. 1 herein), the need to
maintain concentrically arranged areas of illuminosity results in a
substantial portion 1 of the area of each pixel 2 being occupied by opaque
portions of the screen with the resulting aperture being defined by the
Roman numerals I to IV. It can be clearly seen that the aperture is
severely restricted. Normally, this aperture is utilised by shining an
intense white back light through the display with the areas illuminated
being defined by the various apertures of each pixel in conjunction with
the set state for that display.
In order to obtain a colour display, colour filters are normally placed
over the apertures with one colour filter for each desired primary colour
of the display. One common form of colour display is a red, green, blue
(RGB) display which has separate red, green and blue pixel sub-portions
for each pixel of the display.
U.S. Pat. No. 5,124,695 further discusses the creation of a colour display
through the juxtapositioning of Red, Green and Blue pixels, each created
in accordance with the arrangement of FIG. 1 for a monochrome display.
For a given intended final illuminosity of display, a smaller aperture will
require the usage of a higher intensity back light. Of course, a higher
intensity back light will require more power in addition to giving off
more heat. This is a particular problem with liquid crystal displays
designed to be used in portable battery powered systems with the higher
power requirements resulting in a shorter battery life.
U.S. Pat. No. 5,124,695 also discloses the use of a metallisation layer in
construction of displays in order to reduce energy losses due to the
attempt to drive a transparent electrode column of pixels.
European Patent Application No. 361,981 (Nakagawa et al/Sharp) discloses a
monochrome pixel arrangement for a liquid crystal display. EP A 361,981 is
primarily directed to a pixel pattern, with each pixel containing separate
binary weighted luminable areas. One embodiment, FIG. 8c of EP A 361,981,
reproduced as FIG. 2 herein, discloses a pixel arrangement in which the
centre of illuminosity undergoes substantial movement for each increased
level of illumination. A second embodiment, FIG. 10 of EP A 361,981 and
reproduced as FIG. 3 herein, discloses a pixel layout pattern where the
centre of illuminosity remains substantially constant for each level of
illumination. EP A 361,981 does not disclose the use of a metallisation
layer, with the electrodes being made up purely of transparent substances.
With large panel displays, the need to drive long transparent electrodes
makes the resulting display unworkable owing to the high resistivity of
the transparent electrodes. With larger display devices, it becomes
necessary to use an opaque metallic conductor coupled with any transparent
electrode in order to minimise voltages necessary to drive the display.
Additionally, the pixel arrangement disclosed in EP A 361,981 leaves
substantial gaps between each electrode where the state of illumination
will be undefined. Finally, EP A 361,981 is concerned only with monochrome
displays and does not disclose any extension to full colour displays.
The construction of high quality colour displays requires large numbers of
pixel patterns to be created in an exacting manner under extreme
conditions of cleanliness. Hence, expensive and advanced semiconductor
processing techniques are normally required in the construction of such
devices and an error in just one of these techniques can render a display
unusable.
As each pixel is to be replicated, perhaps several million times, a trade
off is presented to the designer of a single pixel. On the one hand there
is the requirement to ensure each pixel is as simple as possible, with
each additional separately controlled area requiring separate control
circuitry and each level of added complexity increasing the likelihood of
failure. On the other hand it is of critical importance to reduce or
eliminate unwanted artifacts in any displayed image, as these are easily
able to be detected by the human observer. One form of artifact is that
created through the shift in the optical centre of illumination of a pixel
to which the invention disclosed in U.S. Pat. No. 5,124,695 is directed.
An additional competing factor to be considered in the construction of
large displays is that, given each pixel is to be of a predetermined size,
the more space that is devoted to opaque wiring and other control
circuitry, the less the amount of space that is available to those
portions of the pixel that are responsible for illumination. For example,
in a liquid crystal type display, it is desirable to maximise the areas of
the transparent electrodes which are responsible for the illumination, at
the expense of the space devoted to the normally opaque driving circuits
responsible for conveying signals for the control of the transparent
areas.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide an improved form of
full colour display that substantially minimises any overall movement of
the optical centre of illumination of a pixel while simultaneously
providing for an improved tradeoff in the abovementioned factors.
In accordance with a first aspect of the present invention, there is
provided a discrete level coloured pixel display having a pixel pattern
comprising a multiplicity of pixels with each pixel having a multiplicity
of primary colour sub-regions of illumination each of which further
comprises a multiplicity of illumination areas, said illumination areas
being able to be set to an illuminating state or a non-illuminating state
wherein:
(a) the primary colour sub-regions extend in a first direction
substantially from one side of the pixel to the other, but in a second
direction substantially normal to the first direction have only a limited
extent in said pixel;
(b) the illumination areas are arranged to be able to be illuminated with
changing intensity with a centre of illuminosity which is substantially
stable with respect to movement in the first direction and any movement of
said centre of illuminosity is substantially constrained to movement in
the second direction.
In accordance with a second aspect of the present invention, there is
provided a discrete level coloured pixel display having a pixel pattern
comprising a multiplicity of pixels with each pixel having a multiplicity
of primary colour sub-regions of illumination each of which further
comprises a multiplicity of illumination areas, said illumination areas
being able to be set to an illuminating state or a non-illuminating state
wherein:
(a) the primary colour sub-regions extend in a first direction
substantially from one side of the pixel to the other, but in a second
direction substantially normal to the first direction have only a limited
extent in said pixel;
(b) the illumination areas are arranged to be able to be illuminated with
changing intensity with a centre of illuminosity which is substantially
stable and wherein the distance between the centre of illuminosity of any
primary colour sub region and the centre of illuminosity of the next
adjacent pixel in said first direction is substantially equal to the
distance between the said centre of illuminosity of said primary colour
sub region and the centre of illuminosity of the corresponding primary
colour sub region of the next adjacent pixel in said second direction.
In accordance with a third aspect of the present invention, there is
provided a discrete level coloured pixel display having a pixel pattern
comprising a multiplicity of pixels with each pixel having a multiplicity
of primary colour sub-regions of illumination each of which further
comprises a multiplicity of illumination areas, said illumination areas
being able to be set to an illuminating state or a non-illuminating state
wherein:
(a) the primary colour sub-regions extend in a first direction
substantially from one side of the pixel to the other, but in a second
direction substantially normal to the first direction have only a limited
extent in said pixel;
(b) the illumination areas are arranged to be able to be illuminated with
changing intensity with a centre of illuminosity which is substantially
stable and wherein the distance between the centre of illuminosity of any
primary colour sub region and the corresponding primary colour sub region
of any next adjacent pixel is maximised.
BRIEF DESCRIPTION OF THE DRAWINGS
The preferred embodiment of the present invention will now be described
with reference to the accompanying drawings in which:
FIG. 1 reproduces the pixel arrangement illustrated in U.S. Pat. No.
5,124,695;
FIG. 2 reproduces the levels possible with a first pixel arrangement
illustrated in EP A 361,981;
FIG. 3 reproduces the levels possible with a second pixel arrangement
illustrated in EP A 361,981;
FIG. 4 illustrates a single full colour pixel arrangement suggested by the
prior art;
FIG. 5 illustrates a 6.times.2 array of pixels of FIG. 4;
FIG. 6 illustrates a single pixel formed in accordance with one embodiment
of the present invention;
FIG. 7 illustrates a 3.times.4 array of pixels of FIG. 6;
FIG. 8 illustrates a schematic perspective view of the operation of a
ferroelectric liquid crystal device;
FIG. 9 illustrates an array of pixels of the preferred embodiment;
FIG. 10 illustrates a single pixel constructed in accordance with the
preferred embodiment;
FIG. 11 illustrates the number of possible levels available for the red
portions of a pixel;
FIG. 12 illustrates the number of green levels available with the pixel
arrangement of the preferred embodiment, and
FIG. 13 illustrates the number of blue levels available with the pixel
arrangement of the preferred embodiment.
FIG. 14 is a cross sectional view of the construction of the colour filter
layer of the preferred embodiment;
FIG. 15 is a plan view of the colour filter mask used in construction of
the colour filter layer;
FIG. 16 is a cross sectional view of the construction of the data level
metal layer of the preferred embodiment;
FIG. 17 is a plan view of the data level metal mask used in construction of
the data metal layer;
FIG. 18 is a cross sectional view of the construction of the formation of
the data level dielectric layer of the preferred embodiment;
FIG. 19 is a plan view of the data level dielectric pixel mask used in the
construction of the data level dielectric layer;
FIG. 20 is a cross sectional view of the construction of the data level
transparent electrode layer of the preferred embodiment;
FIG. 21 is a plan view of the data level transparent electrode mask used in
the formation of the data level transparent electrode layer;
FIG. 22 is a cross sectional view of the construction of the data level
surface layers of the preferred embodiment;
FIG. 23 is a plan view of the common level metal mask used in the
construction of the common level metal layer;
FIG. 24 is a plan view of the common level dielectric mask used in the
construction of the common dielectric layer of the preferred embodiment;
FIG. 25 is a plan view of the common level electrode mask used in the
construction of the common transparent electrode layer of the preferred
embodiment;
FIG. 26 is a cross-section of a pixel through the line A--A of FIG. 10;
FIG. 27 illustrates a graph of the aperture of a colour panel constructed
in accordance with the preferred embodiment with respect to the panel
size; and
FIG. 28 illustrates a single pixel constructed in accordance with an
alternative embodiment.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Investigation of the need to maintain the optical centre of illumination
has surprisingly revealed that this need mainly arises as a result of the
interference effects that can occur between the illumination present at a
given pixel and the illumination present at its surrounding neighbours.
The eye is very sensitive to apparent changes in the pixel position and
this sensitivity is especially prevalent with respect to the overall
illumination position of a pixel in relation to its adjacent pixels and in
areas of slowly varying pixel colour.
Referring now to FIG. 4, there is shown a simplified illustration of a
pixel 6 of a full colour display constructed in accordance with U.S. Pat.
No. 5,124,695. In order to display a predetermined colour, various
portions of the red 3, green 4 and blue 5 sub-pixels are illuminated.
Unfortunately, as the colour intensity of these sub-pixel portions is
altered, so too will be the overall optical centre of illumination. For
example, in displaying a mainly red colour the optical centre of
illumination will be substantially near the red sub-pixel 3, and in
displaying a predominantly blue colour the optical centre will be
substantially near the blue sub-pixel 5. Note that for reasons which will
be clarified below, it is assumed that the optical centre of illumination
of each primary colour sub-portion 3, 4, 5 is substantially at the centre
of each of the designated areas.
Referring now to FIG. 5, there is shown a simplified illustration of a
6.times.2 array of colour pixels 7, with each pixel constructed in
accordance with that suggested by FIG. 4. Considering now the consequences
of failing to properly center each level of illumination, by way of
example, in considering a red sub-pixel 8, it can be seen that the
anti-symmetries of the pixel layout are such that movement of the optical
centre of the red sub pixel 8 in a horizontal direction with differing
levels of red colour illumination interferes very little with a
corresponding red sub pixel 11 in the next column of pixels of the
display. However, movement of the optical centre of red sub pixel 8 with
respect to the red sub pixel 10 in the row above will create substantial
interference effects due to their close proximity. As a result, movements
of the optical centre of the red sub pixel 8 in the row direction will
result in minimal interference effects with its neighbour 11 whereas
movement of the optical centre in a vertical direction will result in
substantial interference effects with its neighbours 9 and 10. This means
that, firstly, the need to maintain optically balanced pixels can be
relaxed in the horizontal direction in this arrangement, with this
condition relaxation resulting in improvements in other conditions such as
wire routing, pixel design or aperture ratio.
Further, referring now to FIG. 6, there is shown a first improved pixel
arrangement 13. In this arrangement the vertical dimension has been
stretched with respect to the horizontal dimension, with the actual
overall area occupied by the overall pixel remaining constant. By
stretching in the vertical dimension, there will be a corresponding
distancing of the centre of illumination of optical pixels in the vertical
direction at the expense of a reduction in the optical centres in the
horizontal direction.
Referring now to FIG. 7, there is shown an array of 3.times.4 pixels 14,
with each pixel constructed in accordance with FIG. 6. The optical centre
of red sub pixel 15 is now closer to the optical centre of red sub pixel
16 on the same row but in the next column. Additionally, the optical
centre of red sub pixel 15 is further away from the optical centre of the
red sub pixel 17. The elongation of the pixel structure has resulted in a
distancing of optical centres of illumination in the column direction at
the expense of a shortening of the distance between optical centres in a
row direction. However, as the array 14 comprises full colour pixels, the
distance between red sub-pixel 15 and its row neighbour 16 is still
substantial.
This preferred pixel arrangement of maximising the distance between the
optical centres of neighbouring sub-pixels in column direction is of
significant importance in reducing unwanted artifacts in images as a
result of any movement of optical centres. By distancing the proposed
optical centres of illumination of each of the subpixel portions e.g. 15
from those of its neighbours, it is possible to partially relax the
requirement for fully optically balanced subpixels while not introducing
the distracting artifacts associated with a non-optically balanced pixel
arrangement.
Therefore, in a first example embodiment, the need to ensure that the
optical centre of illumination of a pixel remains constant in a horizontal
direction is relaxed. The first embodiment of the present invention will
now be described in relation to a ferro-electric liquid crystal display,
however it should be noted that the present invention is not limited
thereto, applying equally to other forms of discrete level displays such
as anti ferroelectric liquid crystal displays, plasma panel displays or
electro-luminescent displays.
Referring now to FIG. 8 there is illustrated the basic operation of a
ferroelectric liquid crystal display device (FLCD) 20 which comprises a
pair of electrode plates (normally consisting of glass substrates coated
with a transparent form of electrodes) 21 and 22 and a layer of ferro
electric liquid crystal having molecular layers 23 disposed between and
perpendicular to the electrode plates. The ferroelectric liquid crystal
assumes a chiral smectic C phase or an H phase and is disposed in a
thickness thin enough (e.g: 0.5-5 microns) to release the helical
structure inherent to the chiral smectic phase.
When an electric field E (or -E) 24 exceeding a certain threshold is
applied between the upper and lower substrates 21, 22 liquid crystal
molecules 23 are oriented in accordance with the electric field. A liquid
crystal molecule has an elongated shape and shows a refractive anisotropy
between the long axis and the short axis. Therefore if the ferroelectric
liquid crystal device 20 is sandwiched between a pair of crossed
polarisers (not shown) mounted on the glass substrates 21, 22, there will
be provided a liquid crystal light modulation device.
When an electric field 24 exceeding a certain threshold is applied the
liquid crystal molecules 23 are oriented to a first polarisation
orientation state 25. Further, when a reverse electric field (-E) is
applied, the liquid crystal molecules 23 are oriented to a second
polarisation orientation state 26. These orientation states are further
retained as long as the electric field which is applied, does not exceed a
certain threshold in the reverse direction.
Referring now to FIG. 9, there is shown a portion the pixel layout of a
liquid crystal device 20 according to the preferred embodiment. The liquid
crystal display 20, is designed for the high resolution display of full
colour images and includes a substantial number of common lines and
corresponding common transparent electrodes 28 laid out on a first
substrate. The common lines are electrodes laid substantially
perpendicular to a large number of data drive lines and data transparent
electrodes 29 formed on a second substrate in the manner as will be
hereinafter described.
Common sizes for high resolution computer displays included displays having
1024 distinct rows of pixels each divided into 1280 distinct columns of
pixels, with one set of lines formed on a first glass substrate and the
other set of drive lines formed on a second glass substrate. At the
intersection of these rows and columns are formed pixels indicated by the
box 30. In the preferred embodiment of the present invention, each pixel
of the display has more than one drive line and more than one common line
associated with it.
In particular, with reference to FIG. 10 wherein there is shown the layout
of a single pixel 30, each pixel 30 has three common drive lines 31, 32,
33 with the outer two common drive lines 31, 33 being optionally
electrically connected together at the edge of the display. Similarly,
each pixel has multiple data lines, divided into red data drive lines 35,
36, green data drive lines 39, 40 and blue data drive lines 37, 38.
The data drive lines are treated symmetrically for each colour and, as
such, only the operation of the red data drive lines 35, 36 will now be
described. The red data drive lines 35, 36 control the transparent
electrode areas 42-47. The first red data drive line 35 controls the
transparent electrode areas 42, 44, 46 and the second data drive line
controls areas 43, 45 and 47.
Preferably, each transparent electrode area 42-47, which is able to be
independently driven, forms a binary area relationship with other areas.
For example, area 44 is 1 square unit, area 45 is 2 square units, areas 42
and 46 together form a 4 square unit area, and areas 43 and 47 form an 8
square unit area. Therefore, in driving combinations of the drive lines
and the common lines, and remembering that the outer drive lines 31 and 33
are preferably electrically connected together, 16 possible levels for
each primary colour of the pixel 30 can be achieved or 16.sup.3 =4096
different colours per pixel 30. Of course, by forming such a binary
relationship in illumination areas, substantially more levels can be
achieved than if the areas were to be all of the same size.
Referring now to FIG. 11, the 16 possible levels for the red primary colour
of the pixel 30 are shown. Similarly FIG. 12 and FIG. 13 show the 16
possible levels for the green primary colour and the blue primary colour
respectively. In combination, each pixel of the preferred embodiment is
therefore able to display 4096 different possible colours.
As can be seen from observation of the patterns produced in FIG. 11 to FIG.
13, the optical centre or the centre of illumination of each primary
colour, as the primary colour's intensity is increased from level to
level, remains substantially in the same position. The need to minimise
the movement of the optical centre of illumination of the pixel intensity
as the intensity is increased is an important consideration in the removal
of unwanted artifacts in pictures displayed on an FLCD device, and it is
primarily for this reason that the two outer common lines have been
provided however, as discussed previously, the optical centering process
has been slightly relaxed in the horizontal direction.
The common lines 31, 33 can be optionally connected together at the edge of
the device using a number of methods. The selection of the common lines
31, 33 is made in the time period different from that of the common line
32. The preferable method of connecting common lines 31, 32 is to
duplicate the logical circuitry and various bonding pads required for the
interconnected drive lines and drive both lines with the same decoded
signal. Alternatively, the drive lines can be electrically connected on a
Tape Antomated Bonding (TAB) flexible Printed Circuit Board (PCB), by
using double sided TAB traces.
Manufacturing
Although the present invention applies to all forms of displays, the
manufacture of a ferro electric display having a pixel layout in
accordance with FIG. 10 will now be described.
The manufacturing processes utilised in the display construction are very
similar to those used in the construction or fabrication of Very Large
Scale Integrated Circuit Devices (VLSI) and familiarity with the
constructions of such devices is assumed.
The construction of a FLCD display begins with the two glass substrates.
Referring initially to FIG. 14, the construction of the top glass
substrate 22 will now be described.
Colour Filters
After the surface of the substrate has been thoroughly cleaned, an
aluminium chelate coupling agent (not shown) can be applied to ensure the
proper adhesion to the glass of subsequent layers to the glass substrate.
A spin coating process is then used to apply a 1.5 .mu.m layer of
photosensitive polyamide containing a primary colour die, which in the
first case will be red. To remove residual solvents, the polyamide is
pre-baked for approximately 10 minutes at 80.degree. C. The photosensitive
polyamide is then exposed using a pixel mask as shown in FIG. 15, with the
aperture 50 corresponding to the area of the red colour filter 51 to be
exposed. The polyamide layer is then developed leaving the red colour
filter portions 51 of each pixel on the substrate 22. This first colour
filter portion is then post baked to form a stable structure before the
process is repeated for the green filter 52 and blue filter 53, with
appropriate masks (not shown) whose aperture is appropriately shifted by a
one third pixel width.
Data Level Metal Layer
Referring now to FIG. 16 the next portion of the display device constructed
is preferably the data level metal layer 35-40. The deposition of this
metal layer occurs directly over the colour filters.
In the construction of devices using metal layers, the use of Molybdenum
(Mo) has been preferred for the formation of the relevant circuitry.
Molybdenum is preferred due to its superior patterning properties and
planarisation properties.
Aluminium is also a possible candidate for use in patterning of the metal
layer. The resistivity of aluminium is 0.027 .mu..OMEGA.m at 25.degree.
C., whereas the resistivity of molybdenum is 0.0547 .mu..OMEGA.m at
25.degree. C. Hence a metal conductive layer made of aluminium is almost
twice as conductive as one made of molybdenum. However, hillock or spike
formation in aluminium, as a result of stress release during differential
thermal expansion of aluminium, in comparison with other substances used
in the creation of the display, creates a serious problem with prior forms
of displays which currently prevents the use of aluminium.
As the distance between substrates is of the order of 1-2 .mu.m, a hillock
in the metal layer of this order or greater may result in substrate
separation beyond specifications resulting in a defective panel. The
manufacturing method does not eliminate the formation of hillocks.
However, by positioning the data metal layer on top of the colour filter
layer and covering the data metal layer with a 2 .mu.m planarised
dielectric layer (to be described below), the affect of hillock formation
can be significantly reduced as most of the hillocks will be absorbed
within the dielectric layer. Of course, extremely large hillocks (greater
than 3 .mu.m) will still cause panel separation.
The deposition of a metal layer is well known to those skilled in the art
of semiconductor circuit fabrication and an example process for such
deposition will now be described.
A 0.3 .mu.m layer of a Aluminium and 0.5% Copper (AlCu) alloy is first
sputtered onto the surface of the substrate. Preferably the aluminium is
planarised to a 0.09 .mu.m surface height difference. The sputtered
aluminium layer is then primed for photoresist adhesion by spin coating a
monolayer of hexamethyldisilazane (HMDS). A 1 .mu.m layer of positive
photoresist such as AZ1370 is then spin coated on top of the priming
layer. The photoresist is then pre-baked for 3 minutes at 90.degree. C.
using an infra-red oven. The photoresist is then exposed using the pixel
mask shown in FIG. 17, which comprises simple vertical stripes
corresponding to the various areas of the data metal layer 35-40. The
photoresist is exposed to the metal mask at 35 mJ/cm.sup.2.
The photoresist can then be developed for 50 seconds at 23.degree. C. in
25% aqueous solution AZ-351 and 40% aqueous solution AZ-311. A development
inspection can then take place before the resist is stripped and any out
of tolerance panels are either discarded or reworked. The photoresist can
then be post-baked at 150.degree. C. before the sputtered aluminium is wet
etched in an agitated solution of 80% phosphoric acid, 5% nitric acid, 5%
acetic acid and 10% water at 40.degree. C. for 2 minutes.
Finally the remaining photoresist is stripped using a low phenol organic
stripper such as Shipley remover "1112A", leaving the data level metal
layer 35-40 on the bottom substrate 22.
Data Level Dielectric Layer
Referring now to FIG. 18, there is shown the data level dielectric layer
65. This layer is formed from a simple photosensitive polyamide process.
The processing steps that can be used to form this layer include the spin
coating of a 2 .mu.m of a photosensitive transparent polyamide layer.
Preferably a good planarisation is obtained through the use of a ester
oligomer solvent with 50% resin content rather than the more usual PIQ
polyamide acid method.
The polyamide is then prebaked for 10 minutes at 80.degree. C. The
polyamide is then exposed using the mask as shown in FIG. 19, before being
developed and post-baked to ensure that the final dielectric layer 65
takes the form as shown in FIG. 18.
Data Level Transparent Electrode Layer
Referring now to FIG. 20, there is shown the data level transparent
electrode layer including first portions 66, 67 controlling the red
primary colour area. This layer is formed by applying a transparent
electrode such as ITO (Indium Tin Oxide) on the substrate 22.
Although a functional display could be produced with the data level
transparent layer being formed initially on the colour filter layer and
the data level metal layer being formed on top of the data level
dielectric layer, the preferred embodiment includes the data level
dielectric layer being created before the data level transparent layer.
This has the advantage that the data level transparent layer is created
very close to the liquid crystal portion upon which it operates. Hence the
electric field created between an adjacent data level transparent
electrode and a corresponding common level transparent electrode is
substantially increased.
The process of formation of the data level dielectric layer includes the
sputtering of indium and tin in an oxygenated atmosphere to initially form
a 0.07 .mu.m layer of ITO. This layer of ITO is then primed, again by spin
coating a monolayer of HMDS. On top of this layer is spin coated a 1 .mu.m
layer of positive photoresist such as AZ1370. The photoresist can then be
pre-baked, to remove solvents, for approximately 3 minutes at 90.degree.
C. using an infra-red oven.
The photoresist is then exposed to the data level electrode mask as shown
in FIG. 21 at an energy of approximately 35 mJ/cm.sup.2. The photoresist
is developed for 50 seconds at 23.degree. C. in a 25% aqueous solution
AZ-351 and a 40% aqueous solution AZ311. The photoresist is then post
baked at 120.degree. C. The ITO is then wet etched and the remaining
photoresist is stripped using a low phenol organic stripper such as
Shipley `Remover 1112A` leaving the data transparent electrode layer
connected to the data metal layer.
Referring now to FIG. 22, the surface layers 68 can then be applied. This
includes the sputtering of 0.1 .mu.m of a tantalum pentoxide insulator,
the application of 0.1 .mu.m of silicon titanium oxide, the spin coating
of 0.02 .mu.m of polyamide which is then post baked and the surface rubbed
for the proper liquid crystal molecule alignment.
The second substrate 21 (FIG. 8) is laid out in the same manner as the
first substrate but for different masks being used and the dispensing of
the colour filter layer.
After the surface of the substrate has been thoroughly cleaned, a common
metal layer, a common dielectric layer, a common transparent electrode
layer and the various surface layers are laid down with the common metal
mask as shown in FIG. 23, the common dielectric mask as shown in FIG. 24,
and the common electrode mask as shown in FIG. 25.
Referring now to FIG. 26 there is shown a final cross-section of a pixel 30
of the display taken through the line A--A of FIG. 10. In order to better
illustrate the preferred embodiment, the approximate scale of the
cross-section has been magnified in the vertical direction.
This cross-section includes the upper 22 and lower 21 glass substrates as
previously described. On each glass substrate is deposited polarising film
71, 72, which, depending on the required driving mechanisms, can have
either parallel or perpendicular polarising axes with respect to one
another.
Layers deposited on the substrates are designed to create a transparent
electrode portion for the particular transparent area required, in
addition to a supply means for delivering a voltage source to the
transparent electrode so that the required electric field can be set up
between the top substrate 22 and the bottom substrate 21, and so that the
liquid crystal 73, sandwiched between the substrates, can be forced into
its relevant bistable state.
As mentioned previously, the bistability is with respect to the liquid
crystal's influence on the polarisation of light. Hence, light 74 is shone
through the panel by means of a backlight (not shown), and is polarised by
the bottom substrate polariser 72. It then has its polarisation state
changed depending on the bistable state of the liquid crystal 73, before
passing through the second polarising film 71 which, depending on the
required driving arrangement, may have its polarisation axis at right
angles to, or parallel to, the bottom substrate polariser 72. Hence,
depending on the state of the crystal 73, which is preferably of a ferro
electric liquid crystal type, the light will be either blocked or
transmitted by the combination of the polarisers 71, 72 and liquid crystal
73.
The state of the liquid crystal 73 is altered, as previously mentioned, by
setting up electric fields between the transparent electrodes of the top
and bottom substrates. This is done primarily by means of intersecting
portions of transparent electrodes. For example, a top common transparent
electrode 76 and a bottom data transparent electrode 66, 67. These
transparent electrodes comprise, approximately 0.7 .mu.m thick of Indium
Tin Oxide (ITO) connected to a 0.7 .mu.m metal voltage supply line. The
common level transparent layer 76 is connected to corresponding portions
of common metal layer 77 which include the common metal lines 31-33 of
FIG. 10. The data or segment level transparent layer e.g. 66, 67 is
connected to corresponding portions of the data level metal layer which
includes the data metal lines 35, 36 of FIG. 10.
The transparent common electrode layer 76 is insulated from an adjacent
common metal electrode 77 by means of a common dielectric layer 78.
Additionally, it is necessary to insulate the common transparent layer 76
from the liquid crystal itself. This insulation is provided by a 0.1 .mu.m
insulation layer 79 made up of Tantalum Pentoxide (Ta.sub.2 O.sub.5). A
0.1 .mu.m layer of Silicon Titanium Oxide (SiTiO.sub.x) 80 is then
provided to smooth out any irregularities in the surface of the substrate.
An alignment layer 81 comprising approximately 0.02 .mu.m of polyamide is
then formed with the alignment layer being formed by laying down the
polyamide layer and then rubbing the surface thereof in one direction with
velvet, cloth, paper etc. As mentioned previously, the various layers are
also replicated on the bottom substrate 21 with the addition of the colour
filter layer.
The two substrates 22, 21 are held apart by 1.5 .mu.m glass spheres 82.
These spheres are shown elongated due to the scaled dimensions of the
panel. Sphere densities in the order of 100 spheres per square millimeter
are appropriate. The substrates are held together by adhesive droplets 83,
so that between the droplets 82 and the spheres 83, the panel is kept in a
static equilibrium with the thickness of the liquid crystal being of the
order of 1.5 .mu.m, being the diameter of the spheres 82.
Sub-Pixel Dimensions
As mentioned previously, the display of images is normally in accordance
with predetermined standards. For example, a standard used with CRT type
displays in common use with computer terminals is to display images with a
resolution of 1,280 pixels by 1,024 lines. An image that is stored with
reference to the above display format can be displayed on a variety of
display sizes, in a similar manner that television displays come in a
variety of display sizes and yet all display the same image. The
difference is in the actual size of each pixel.
In the preferred embodiment, different sized pixels can be achieved by
altering the area of the transparent electrode areas. With reference to
FIG. 10, the dimensions A, B, C and D can be altered depending on the
desired pixel size. Preferably the width of the metal lines are kept
constant at 20 .mu.m although this width will be dependent on the
manufacturing process used. Table A below shows the various sizes (in
microns) of the dimensions A, B, C, D for different sized displays, with
the measurement for the display measured along its diagonal and the
dimensions of the relevant pixel areas shown to the nearest 0.1 micron.
FIG. 27 illustrates a graph of the corresponding aperture ratio of the
colour FLCD display utilizing the data set out in Table A.
TABLE A
______________________________________
Dimensions For Various Pixel Sizes
Metal
Panel size
width Dim. A Dim. B Dim. C Dim. D
Inches (cm)
(.mu.m) (microns)
(microns)
(microns)
(microns)
______________________________________
15 (38) 20.0 12.5 25.0 34.5 69.0
16 (40) 20.0 14.2 28.4 37.6 75.2
17 (44) 20.0 15.9 31.9 40.7 81.4
18 (44) 20.0 17.7 35.3 43.8 87.6
19 (45) 20.0 19.4 38.8 46.9 93.8
20 (51) 20.0 21.1 42.2 50.0 100.0
21 (53) 20.0 22.8 45.6 53.1 106.2
22 (56) 20.0 24.5 49.1 56.2 112.4
23 (58) 20.0 26.3 52.5 59.3 118.6
24 (61) 20.0 28.0 56.0 62.4 124.8
25 (64) 20.0 29.7 59.4 65.5 131.0
26 (66) 20.0 31.4 62.9 68.6 137.2
27 (69) 20.0 33.2 66.3 71.7 143.3
28 (71) 20.0 34.9 69.7 74.8 149.5
29 (74) 20.0 36.6 73.2 77.9 155.7
30 (76) 20.0 38.3 76.6 81.0 161.9
______________________________________
The foregoing describes only one embodiment of the present invention.
Modifications, obvious to those skilled in the art, can be made thereto
without departing from the scope of the invention.
In particular, extension of the present invention to other forms of
discrete level displays such as plasma displays would be readily apparent
to those skilled in the art.
In the above-explained embodiment, each of three primary colour pixels,
i.e., the red, green and blue pixels, is divided into six areas so that
they each may realize a gradation display with 16 levels. However, the
present invention is not limited to this structure and is able to be
extended to the structure such that at least one of the red, green and
blue primary colour pixels is constructed as shown in FIGS. 11-13 and the
rest is at the liberty whether to be divided into a plurality of areas or
not. One concrete example of this structure wherein the red and green
primary colour pixels each have such patterns as shown in FIGS. 11 and 12
and the blue primary colour pixel only is divided into three areas is
shown in FIG. 28.
* * * * *
![[Image]](/netaicon/PTO/image.gif)
![[Home]](/netaicon/PTO/home.gif)
![[Boolean Search]](/netaicon/PTO/boolean.gif)
![[Manual Search]](/netaicon/PTO/manual.gif)
![[Number Search]](/netaicon/PTO/number.gif)
![[Help]](/netaicon/PTO/help.gif)
![[Bottom]](/netaicon/PTO/bottom.gif)
![[View Shopping Cart]](/netaicon/PTO/cart.gif)
![[Add to Shopping Cart]](/netaicon/PTO/order.gif)
![[Top]](/netaicon/PTO/top.gif)