[0001] This invention relates in general to the addressing of image displays and in particular
to the addressing of image displays that are capable of "remembering" the images written.
[0002] Two types of devices have been used for displaying images. The first type has very
short addressing times, typically of the order of microseconds. The images written,
however, decay rapidly and the device is said to have no memory capability. A common
display device of this type is the cathode ray tube (CRT). To write an image at the
proper address on the CRT screen in a process known as addressing, an electron beam
is directed at such address. The CRT screen contains a fluorescent material, usually
phosphor, which fluoresces when struck by an electron beam. Once the striking stops,
however, the brightness of the image thus formed decays rapidly. Thus, to maintain
an image on such a device the image has to be continuously refreshed.
[0003] A second type of frequently used image displays has long addressing times, typically
of the order of milliseconds, but has memory capability. In this type of display,
the image written remains indefinitely after addressing stops so that the image need
not be refreshed. One example of the second type of image displays is the electropnoretic
image display (EPID). An EPID device typically comprises charged particles suspended
in an organic fluid such as xylene. The suspension is contained between a front, a
back and side panels, the outside surface of the front panel serving as the display
surface.
[0004] The EPID suspension fluid is normally dyed to become opaque for masking the particles
which are away from the display surface. The suspension is placed between two sets
of electrodes, one set near the back panel and the other set near the front panel.
By applying appropriate voltages across selected individual electrodes of the two
sets of electrodes the charged particles are caused to move from the back panel towards
the front panel. When the particles reach the front panel, they are not masked by
the suspension fluid. They can then be seen at locations on the display surface determined
by the locations of the particular electrodes selected for application of voltages.
In such manner, the application of voltages to selected electrodes generates images
on the display surface. The colors of the particles and of the dye in the suspension
fluid are chosen so that the images created will have good brightness and contrast.
The EPID type device is disclosed in U.S. Patent Nos. 3,668,106; 3,892,563; 4,041,481;
4,093,534 and 4,203,106. The above six patents are incorporated herein by reference
as background for the technology and display techniques for the EPID type device.
[0005] In the CRT, addressing is accomplished .by moving the electron beam so that it strikes
a display surface at the location where the desired image is to be displayed. In the
EPID type device addressing is accomplished by applying the appropriate voltages across
the electrodes that intersect at points corresponding to the desired address of the
image on the display surface. Because of the limitations in two dimensional addressing
(X-Y addressing) using electrodes, the addressing of images in EPID devices is performed
sequentially. In other words, the images to be written on a section of the screen
covered by a number of pixel lines are written one pixel line at a time.
[0006] For the CRT type of image displays with very short addressing times (microseconds),
the sequential addressing of a large amount of information requires little time so
that it causes little inconvenience to the viewer. With display devices requiring
long addressing times such as in EPID type displays this is not the case. In the EPID
type device long addressing times (of the order of 10 milliseconds) are required in
order to move enough charged particles from the back panel of the device to the front
panel to create images of full brightness and contrast. A display surface may contain
100 or more pixel lines. If a large amount of information is to be written all the
pixel lines must be addressed. In conventional addressing methods, each pixel line
is written sequentially to the full brightness and contrast before the next pixel
line is written so that 1 second is required to write a full screen of text or other
images on an E
PID device. The lengthy writing time becomes 'particularly troublesome when a viewer
desires to only skim or scroll a text such as instances at which the viewer wishes
to find a particular page of a long document. It is therefore desirable to provide
a method for writing images which allows a viewer to scroll a long document. It is
also desirable to provide a method which allows more flexibility than the conventional
method of addressing and writing images.
[0007] According to the invention there is provided a method for writing information in
a display device, wherein information written on the display surface of the device
remains thereon for viewing after addressing stops, wherein the brightness of the
information on the display surface increases with the length of time during which
the information is written, wherein said length of time defines the writing time of
the information add wherein the brightness reaches a maximum level after the writing
time exceeds a predetermined time period defining a saturation time, said method comprising
writing a first information on the display surface for a first writing time less than
the saturation time.
[0008] If so desired, the same information can be written repeatedly at the same address
to increase the brightness of the informatin to the desired level. Alternatively,
information can be written once for a selected writing time to achieve any level of
brightness desired. In such manner a grey scale of brightness for displaying images
may be implemented.
[0009] The invention will be better understood from the following description, given by
way of example and with reference to Fig.1 of the accompanying drawings, which is
an exploded perspective view of an EPID cell partially cut away to illustrate a preferred
embodiment of this invention.
[0010] As shown in Fig.1, EPID cell 10 comprises a front panel 12 and a back panel 14. Substantially
parallel strips of an electrically conductive material are deposited on the inside
surface of the front panel 12 to serve as a set of anodes 16 (A1, A2, ..., Am), m
being a positive integer. Substantially parallel strips 18 (C1, C1, ..., Cn), n being
a positive integer, of a conductive material are deposited on the inside surface of
back panel 14 to serve as a set of cathodes. Each strip anode is electrically isolated
from adjacent strip anodes and each strip cathode is electrically isolated from adjacent
strip cathodes. On top of cathodes 18 is deposited a layer of electrically insulating
material 20. On top of layer 20 are deposited p substantially parallel strips 22 (Gl,
G2, ..., Gp) of conductive material to serve as the grid electrodes, p being a positive
integer. Adjacent grid electrodes are also electrically isolated from each other.
[0011] The portions of insulating layer 20 exposed in between the grid electrodes are etched
away in a conventional manner to expose small sections of the cathodes between the
columns of grid electrodes. When cell 10 is viewed from the front through front panel
12, the grid electrodes 22 overlap cathodes 18 in square or rectangular sections.
Dalisa in U.S. Patent No. 4,203,106 discloses an EPID cell somewhat similar to that
described above.
[0012] The electrophoretic suspension is enclosed between the front panel, back panel and
side panels (not shown) of the cell. When voltages of the appropriate waveforms are
applied to the anodes, grids and cathodes, EPID cell 10 is made to display desirable
images. In a preferred embodiment the number of m strips of anodes correspond to m
lines for displaying m lines of characters of text or other images through the front
panel 12. To display a character such as a letter of the alphabet, the display screen
must be addressed so that pigment particles will appear only in some parts and not
in other parts of the area of the screen for displaying the character so that the
contrast formed between the parts at which there are particles and the parts at which
there are no particles will display the desired character. Thus each character line
must be further divided into smaller units known as pixels for addressing in order
to display characters. The addressing of pixels is explained in more detail below.
The outside surface of front panel 12 is the display surface through which images
are viewed. In the preferred embodiment there may be 27 strip anodes for displaying
27 lines of characters or images at the display surface. There are many more strip
cathodes and strip grids than strip anodes. In the preferred embodiment there are
over 200 cathodes and grids.
[0013] The square or rectangular section on the display surface corresponding to the area
where a cathode and a grid intersect is called a pixel and each cathode Ci defines
a pixel line Pi, i = 1, 2, ..., n. Each anode, thus, matches a number of cathodes
and the same number of pixel lines. The anode Al for example matches cathodes Cl-C9
and pixel lines Pl-P9 as shown in Fig. 1. The area 32 on the display surface corresponding
to a section of anode Al may correspond to the area suitable for displaying one image
or character. As shown in Fig. 1 area 32 contains 81 smaller rectangular or square
sections each corresponding to a pixel. Pixel 34' for example may correspond to the
overlap between cathode C7 and grid GG as shown in the Fig. 1. By applying the appropriate
voltages to the selected anodes, grids and cathodes, the appropriate images may be
displayed in each individual pixel such as pixels 34 across the entire display surface
12a. Dalisa et al, in U.S. Patent No. 4,203,106, describe certain voltages and the
technique for applying such voltages to the electrodes for displaying desired images
in each individual pixel.
[0014] The process of writing images on the display surface 12a can now be described. Typically
such images are written from one side of the surface to the other, such as from top
to bottom. Thus, the appropriate voltages may be applied to anode Al, cathode Cl and
grids Gl-Gp to write the top pixel line Pl.of display surface 12a. Then the appropriate
voltages are applied to cathode C2 and all the grids to write the next to the top
line P2. This process is then repeated until we reach the bottom of the display surface
at the bottom line Pn. Alternatively, the process may instead begin with cathode Cn
so that the images are written from the bottom line of the display surface Pn towards
the top line Pl.
[0015] The conventional addressing method in EPID cells is to apply the appropriate voltages
for a time period sufficient to bring enough particles in the suspension towards each
pixel line, such as line Pl, so that the images written thereby appear in full brightness
and contrast before the next line is written. After th
E first line P1 of images is written the appropriate voltages are then applied to cathode
C2, the grids and anode Al for writing the second line of images again to the full
brightness and contrast. In order to write a pixel line to the full brightness and
contrast a time period on the order of 10 milliseconds is required. Thus, if 200 pixel
lines are to be written, it will require 2 seconds to completely write all the pixel
lines Pl to P200.
[0016] For many viewing purposes, however, full brightness and contrast may not be required.
Thus, when EPID cell 10 is used to display textual material in word processing, the
viewer may only wish to find the appropriate paragraph or page in a long document.
Thus the viewer is interested not in reading each individual word on the display surface
but only in the general content of images on a large number of pixel lines. For such
purpose displaying images with less brightness and contrast than the maximum may be
adequate. Fainter but adequate images are achieved by addressing each pixel line Pl-Pn
for a time period less than the saturation time period. If the viewer wishes to read
each individual word of the display so that greater brightness and contrast are desirable
the images already written on the pixel lines can simply be written again at the same
address to the desired brightness and contrast. The process of writing an image already
written at the same address is referred to below as "overwriting." Alternatively,
if the viewer wishes to discard the images displayed to display another screen full
of information the viewer will have spent less time in the process. The different
applications and advantages of the invention are explained below.
[0017] Using the above-described method, either a screen full of information or a single
character line such as the character line corresponding to anode A1 can be written
to the desired brightness and contrast. Each individual pixel line in such character
line can be multiply written. Assume for the purpose of discussion that 10 milliseconds
is the time required to achieve full brightness and contrast, that is, the saturation
time. Each individual cathode among cathodes C1-C9 corresponding to the character
line is first written or addressed for a time period less than 10 milliseconds to
write the pixel lines Pl-P9. This will cause the 9 pixel lines to display a faint
image. Then the same pixel lines P1-
P9 are addressed a second time for a time period less than the saturation time to increase
the brightness and contrast of the images already written. Thus, to the viewer, the
entire character line corresponding to anode Al will be brought to full brightness
and contrast uniformly. In contrast, if the prior art method of writing is used, one
side of the character line will be written first before the remaining part of the
line. For example, pixel line P1 may be written to full brightness and contrast and
then the next pixel line P2 and then lines P3-P9.
[0018] Similarly the entire screen may be written for a writing time period less than the
saturation time and then overwritten to bring the entire screen uniformly to increased
brightness and contrast. Bringing the image to be displayed to full brightness and
contrast more uniformly by overwriting may cause less distraction to the viewer than
the conventional method.
[0019] By choosing to write for time periods less than the saturation time, it is possible
for the viewer to scroll information in a faster and smoother manner than the conventional
method. During scrolling each individual character line is shifted towards the top
of the display surface by one character line at a time. This means that each individual
character line has to be erased and rewritten so that the entire display surface must
simply be erased and rewritten. If each individual line is written to the full brightness
before the next pixel line is written a full 1 or 2 seconds may be required to write
the entire display surface. Thus, the viewer will have to wait 1 or 2 seconds for
the character lines to be shifted by one character line. For scrolling purposes the
viewer does not need to see each character line in its full brightness before deciding
to continue scrolling. By reducing the addressing time from 10 milliseconds to say
2 milliseconds, each screenful of information will have been displayed in 0.2 or 0.4
seconds so that the viewer can decide whether to continue scrolling after only 0.2
or 0.4 seconds. It is found that addressing times on the order of one-fifth of the
saturation time may be adequate for the purpose of scrolling.
[0020] Faster and smoother image changes on the screen other than scrolling can also be
achieved including movement of windows or graphic animation. To accomplish such change
the character lines on which the changes occur are simply erased and rewritten for
time periods less than the saturation time to speed up the addressing process. For
many of such viewing purposes full brightness and contrast are again not necessary.
[0021] The description above relates tn application to an EPID cell with a number of strip
anodes, such as 27 strip anodes. It will be understood that the invention may be applied
to an EPID cell which includes a different number of strip anodes, or even only one
anode (that is, m in Am may be any positive integer, including 1). The description
above has been given in the context of an addressing scheme where the consecutively
written lines on the display, or pixel lines, correspond to strip cathode lines; that
is, Pi corresponds to Ci, i=l,..., n. It will be understood that the technique described
above is equally applicable in the context of an addressing scheme where the pixel
lines correspond to the strip grid lines instead; that is, Pi corresponds to Gi, i=l,...,
p. In such addressing scheme and where the grid lines are vertical as shown in Fig.
1, it may be desirable to rotate the EPID cell about an axis perpendicular to surface
12 for 90 degrees so that the grid lines and hence the pixel lines will again be horizontal
for the convenience of viewers.
[0022] It is also possible to display images having different degrees of brightness and
contrast. To increase the brightness of a particular pixel it is simply overwritten
repeatedly. In one implementation of the method, during each of a number of passes
in addressing, each individual pixel addressed is written for substantially the same
time period. To increase the brightness of a particular pixel such pixel is simply
overwritten repeatedly. For other pixels where less brightness is adequate they are
either not overwritten or overwritten for fewer passes. Thus, if an image is written
with n passes of equal duration, there can be n + 1 shades between light and dark,
ranging from no pass to n passes. In an alternative implementation of the method,
all the pixels to be written are written only once in a single pass, but the writing
time of each pixel may differ. The unequal durations of the addressing passes may
be chosen, for example, from a set of different writing times, so that the brightness
of the information displayed is selectable from up to n+1 levels for n passes. The
set of different writing times may be selected from multiples of a base time period
such as 1 millisecond. The set of writing times may conveniently be a binary progression
of addressing times (1, 2, 4, 8, 16, ... 2
n microseconds). The two schemes can be combined to achieve up to 2
n grey levels. In the combined scheme, selected pixels may be overwritten repeatedly
and for unequal durations.
[0023] Some of the different modes described above can be combined. Thus, after the viewer
has scrolled a document to the point that the viewer wants to stop scrolling and read
the information more carefully the erasing and rewriting of the full screen of images
stop and the display surface is simply multiply overwritten repeatedly so that the
brightness and contrast increase uniformly to the maximum.
[0024] In the EPID type device, addressing times of the order of one or two milliseconds
have been found to achieve sufficient brightness for purposes such as scrolling. If
an image is overwritten repeatedly, it is found that the brightness achieved bears
a generally linear relationship to the total time during which it is written. Thus,
two strikes of one millisecond each may be equivalent to one strike for two milliseconds.
It will be understood, however, that the invention as defined in the appended claims
is not limited to EPID type devices, or devices where the brightness is related linearly
with the addressing time.
1. A method for writing information in a display device, wherein information written
on the display surface of the device remains thereon for viewing after addressing
stops, wherein the brightness of the information on the display surface increases
with the length of time during'which the information is written, wherein said length
of time defines the writing time of the information and wherein the brightness reaches
a maximum level after the writing time exceeds a predetermined time period defining
a saturation time, said method comprising writing a first information on the display
surface for a first writing time less than the saturation time.
2. A method as claimed in claim 1, further comprising writing second information on
the display surface for a second writing time.
3. A method as claimed in claim 2, wherein the second information is substantially
the same as the first information and has substantially the same address as the first
information so that writing of the second information increases the brightness of
the first information on the display surface.
4. A method as claimed in claim 2, wherein the second information is different from
the first information.
5. A method as claimed in claim 4, wherein the second information does not overlap
the first information, so that both the first and second information are displayed.
6. A method as claimed in claim 5, wherein the first and second writing times are
selected so that each of the first and second information is displayed with the desired
brightness.
7. A method as claimed in claim 5 or 6, further comprising overwriting the first or
the second information to increase the brightness of the 'first or the second information.
8. A method as claimed in claim 4, further comprising the step of erasing at least
part of the first information before the second information is written, and wherein
the first and second writing times are selected so that the first and second information
can be skimmed or scrolled quickly and so that the brightness of the first and second
information are adequate for skimming or scrolling.
9. A method as claimed in claim 2, further comprising the steps of sequentially writing
up to n information, n being an integer, where the ith information is written for the ith writing time, and wherein the n writing times are selected from a set of different
writing times, so that the brightness of the information displayed is selectable from
up to n+1 levels.
10. A method as claimed in claim 9, wherein said set of different writing times is
formed from multiples of a predetermined base time period.
11. A method as claimed in claim 10, wherein said set of different writing times is
formed from multiples of 2 of the predetermined base time period.
12. A method as claimed in claim 2, further comprising the steps of sequentially writing
up to n information, n being an integer, wherein at least some of the n information
are substantially the same and have substantially the same address and wherein each
of the n information is written for substantially the same writing time, so that a
selected information may be written repeatedly for up to n times and so that the brightness
of information displayed is selected from n + 1 levels, wherein the ti+1)th level is selected by repeatedly writing such information for i times.
13. A method as claimed in claim 2, further comprising the steps of sequentially writing
up to n information, n being an integer, wherein at least some of the n information
are substantially the same and have substantially the same address and wherein at
least two of the n information are written for unequal writing times, so that a selected
information may be written repeatedly for up to n-times and so that the brightness
of information displayed is selected from 2n levels.
14. A method as claimed in any one of claims 1 to 5, wherein the first and second
writing times are of the order of 2 milli-seconds.