JP2000180887A - Device and method for displaying information - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device and a method for displaying information with which a display style (fast forward display mode) similar to riffling through the pages of a printed matter can be executed so as to watch easily even for the person of weak sight. SOLUTION: This display device displays information by selecting a liquid crystal(LC) at a crossing position into planar state or focal conic state by applying pulse voltages to scanning electrodes and signal electrodes arranged in the shape of matrix on an LC display cell holding the LC between transparent substrates, for example. In the fast forward display mode, plural images are successively displayed while being partially expanded by speedily operating the LC through phase transfer drive.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to LC, EL, PD
The present invention relates to an information display device including a display element such as P and a display method thereof.

[0002]

BACKGROUND OF THE INVENTION At present, information is provided over a wide area by printed matter, but there is concern that it will be discarded as garbage and that forest resources for pulp and paper will be depleted. The present inventors distribute the information printed on conventional paper in a state recorded on a digital information recording medium, and establish a form in which a user can read the information on a display device such as an LC, EL, or PDP. An electronic book system is being developed with the idea that the consumption of paper itself is suppressed and the resource problem is eased. As information, we believe that any printed matter such as books (paperback books, weekly magazines, monthly magazines, specialized magazines, etc.), newspapers, and advertising magazines can be replaced with such a system.

[0003] Digital information of books is distributed as a recording medium by a publisher (manufacturer), and a general user who owns (or rents) a reproduction display device inserts the recording medium into the electronic book device body. This is a system for viewing (reproducing) information.

[0004] In order to achieve the above systematization, it is necessary to finish the device as small and thin as a book, and to be freely open and viewable anywhere. For that purpose, it is necessary to use a display element with low power consumption and make the power supply compact. In addition, in order to reduce the weight and thickness of the apparatus, it is necessary to adopt a reflection type that does not require a light source. Most preferably, a reflective liquid crystal display element having a memory property is mounted.

However, it has been found that the reflection type liquid crystal display element having the memory property has a peculiar drawback that the drive response speed is slow, and the above system depends on how to overcome this drawback. . If the response speed is improved or the information to be displayed is reduced, the display screen can be flipped like a book (fast forward display mode), and the above-described electronic book can achieve the same handling function as a book.

[0006]

Heretofore, when referring to display devices using liquid crystal display elements, they use low molecular liquid crystals. For this reason, the type using a glass substrate has a problem that, when the substrate is large, it is difficult to uniformly apply a rubbing orientation treatment and the substrate is easily broken. Further, the viewing angle of the display unit was narrow, and it was difficult to read the displayed information. Furthermore, when a shock or pressure is applied to the display panel itself, the orientation is disturbed, and image information cannot be read.In addition, the liquid crystal itself has no memory property, and it is necessary to constantly supply a constant power during display, and power consumption is reduced. Was also large.

[0007] On the other hand, the conventional display device is difficult to see for a person with poor visual acuity, especially in the fast-forward display mode.

[0008] In view of the above problems, an object of the present invention is to provide an information display device and a display device that execute a display mode (fast-forward display mode) similar to flipping a page of a printed material in a manner that is easily viewable even by a person with low visual acuity. It is to provide a display method. The present invention proposes an information display device that is put to practical use as a portable electronic book and that also considers the electronic information supply mode (bending system).

[0009]

In order to achieve the above objects, an information display device according to the present invention includes a display element that forms a screen with a plurality of two-dimensionally arranged pixels, and includes information for one screen. And a fast-forward display mode in which information to be displayed is partially enlarged and displayed, or information on a plurality of screens is displayed one after another.

In the fast-forward display mode, the drive speed is increased by partially displaying information to be displayed. At this time, the information is enlarged and displayed so that it is easy to see, and even a person with weak vision has a fast forward display easily. It is possible to keep up with the mode. In particular, the character information becomes easier to see. If the desired information is found in the fast-forward display mode, the display may be switched to the normal display mode.

In such a fast-forward display mode, various display modes can be adopted. Basically, multiple lines on the screen are selected to display low resolution information. Only the head portion may be displayed for each image. The driving speed of the display element is improved for low-resolution display, and the visibility is improved by enlarging the information. Further, if the character information is displayed in an enlarged and thick line, it becomes easier to see.

In the case of an apparatus (electronic book) having two screens on the left and right, when fast-displaying vertically written character information, character information is displayed on the right screen from right to left on the screen and on the left screen. Then, character information is displayed from the left to the right of the screen. By shifting to the display of the next page in the middle of this display, it is possible to use the same way as flipping through the pages of the book and searching for the content to be read. Alternatively, one or more lines may be omitted and displayed. Information can be checked quickly without crushing text information.

To fast-forward information on multiple screens,
If display drive to another screen is started while information is displayed on one screen, display can be performed efficiently, and even if the drive speed is slow, it can be covered. When a plurality of pieces of information are sequentially fast-forward displayed on one screen, the next information is displayed in a screen area that does not overlap the currently displayed information, so that driving time can be saved and display switching can be made faster as a whole. . In addition, if information to be displayed next is displayed using information data synthesized so as not to overlap information currently being displayed, driving of overlapping pixels can be omitted, and display switching can be speeded up.

Further, when image information and character information are mixed on one screen, if only the image information is displayed in a fast-forward manner, the image information usually has a larger amount of information than the character information. , Can recognize the contents quickly.

On the other hand, in the information display device according to the present invention, it is preferable to use a reflective liquid crystal display element having a memory property. As the liquid crystal, it is preferable to use a liquid crystal exhibiting a cholesteric phase at room temperature (for example, a chiral nematic liquid crystal). This type of liquid crystal having memory properties does not require the use of glass for the substrate, and thus has no risk of breakage. In addition, orientation control is easy, the viewing angle is wide,
No unevenness occurs even on a large screen. Moreover,
Because it has memory properties, it is economical because it does not consume power to maintain the display, it does not have the adverse effect of noise,
The display can be maintained even when the power is cut off.

In particular, if a structure in which a liquid crystal and resin structure exhibiting a cholesteric phase at room temperature is sandwiched between transparent plastic films, an information display device that is thin, lightweight, and resistant to external force (bending, impact) can be obtained. It is ideal for portable information devices such as electronic books targeted by the present invention.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of an information display device and a display method according to the present invention will be described with reference to the accompanying drawings.

(Display Element Using Liquid Crystal Showing Cholesteric Phase) In a liquid crystal display element in which a cholesteric liquid crystal or a chiral nematic liquid crystal is sandwiched between two substrates, display is performed by switching the liquid crystal state between a planar state and a focal conic state. Do. When the liquid crystal is in the planar state, the helical pitch of the cholesteric liquid crystal is P, and the average refractive index of the liquid crystal is n.
Then, light having a wavelength λ = P · n is selectively reflected.
In the focal conic state, when the selective reflection wavelength of the cholesteric liquid crystal is in the infrared light range, it is scattered, and when it is shorter than that, it transmits visible light. Therefore, by setting the selective reflection wavelength in the visible light range and providing the light absorbing layer on the side opposite to the observation side of the element, it is possible to display the selective reflection color in the planar state and display black in the focal conic state. In addition, by setting the selective reflection wavelength in the infrared light range and providing a light absorption layer on the side opposite to the observation side of the element, light in the infrared light range is reflected in the planar state, but the wavelength in the visible light range is reflected. Is transmitted, so that a black display and a white display due to scattering in the focal conic state are possible.

By the way, assuming that a first threshold voltage for untwisting a liquid crystal exhibiting a cholesteric phase is Vth1,
After the voltage Vth1 has been applied for a sufficient time, the voltage becomes lower than a second threshold voltage Vth2 which is lower than the first threshold voltage Vth1, and a planar state is established. Further, when a voltage of Vth2 or more and Vth1 or less is applied for a sufficient time, a focal conic state is established. These two states are stable even after the voltage application is stopped. It is also known that a mixture of these two states exists, and it is known that gray scale display is possible (see US Pat. No. 5,384,067).

Since the liquid crystal exhibiting the cholesteric phase has a memory characteristic capable of maintaining a display state even when no voltage is applied, a liquid crystal element having a plurality of pixels is driven by a simple matrix drive to obtain a desired image or character. Can be displayed. However, since this type of liquid crystal has a hysteresis characteristic, the display state is different even with the same driving voltage due to the state before the liquid crystal.

In view of the above, in the normal display mode, the liquid crystal constituting all the pixels is first simultaneously reset to a focal conic state requiring a long time for selection, and thereafter, each pixel is constituted. A selection signal is sequentially applied to the liquid crystal to select the display state of the liquid crystal constituting all the pixels. According to this driving method, all the pixels are simultaneously reset to the focal conic state, so that the long selection time required to select the focal conic state is required only once for one screen. As a result, the rewriting speed is improved when simple matrix driving is performed.

In the liquid crystal display element used in the present invention, the liquid crystal material is sandwiched in the order of resin film / transparent electrode / alignment control film / liquid crystal material / alignment control film / transparent electrode / resin film as described in detail below. The alignment is determined by the combination of the alignment control film and the liquid crystal material. Usually, the alignment process is the same for the upper and lower layers, but this combination may be changed depending on the colorization, driving method, application, and the like.

Although such a name is used for the orientation control film for convenience, its function is not always clear. Rather than the general effect of controlling the alignment of liquid crystal molecules,
It can be said that the effect of improving the stability is great.

(Configuration of Liquid Crystal Display Element) FIG. 1 shows an example of a reflection type liquid crystal display element used in the present invention. In the liquid crystal display element 10, a red display layer 11R for performing display by switching between red selective reflection and a transparent state is disposed on a light absorber 19, and display is performed thereon by switching between green selective reflection and a transparent state. A green display layer 11G to be performed is stacked, and a blue display layer 11B for performing display by switching between blue selective reflection and a transparent state is further stacked thereon.

Each of the display layers 11R, 11G, and 11B has a structure in which a resin columnar structure 15 and a liquid crystal 16 are sandwiched between transparent substrates 12 on which transparent electrodes 13 and 14 are formed, respectively. Further, an orientation control film or an insulating film (not shown) may be provided on the transparent electrodes 13 and 14.

The transparent electrodes 13 and 14 are respectively connected to the driving circuit 2
0, and the transparent electrode 1
A predetermined pulse voltage is applied between 3 and 14, respectively. In response to the applied voltage, the display is switched between a transparent state in which the liquid crystal 16 transmits visible light and a selective reflection state in which visible light is selectively reflected.

The transparent electrodes 13 and 14 provided on each of the color display layers 11R, 11G and 11B are composed of a plurality of strip electrodes arranged in parallel at a fine interval, respectively. They are opposed so as to be at right angles. Current is sequentially applied to these upper and lower strip electrodes. That is, display is performed by sequentially applying a voltage to each liquid crystal 16 in a matrix. This is called matrix driving. The liquid crystal display element 1 is formed by sequentially or simultaneously performing such matrix driving for each color display layer.
A full color image is displayed at 0.

By providing the light absorber 19 in the lowermost layer with respect to the direction of observation (the direction of arrow A), each color display layer 1
Light transmitted through 1R, 11G, and 11B is all light absorber 19
Is absorbed by That is, if all the color display layers are in a transparent state, black display is performed. As such a light absorber 19, for example, a black film can be used. Alternatively, a black paint such as black ink may be applied to the lowermost surface of the display element to form the light absorber 19.

In FIG. 1, the red display layer 11R shows a planar state, the green display layer 11G shows a focal conic state, and the blue display layer 11B shows a state where both the planar state and the focal conic state coexist.

(Various Materials of Display Element) As the transparent substrate 12, a colorless and transparent glass plate or a transparent resin film can be used. Examples of the material of the transparent resin film include polyarylate resin, polyether sulfone resin, polycarbonate resin, norbornene resin, amorphous polyolefin resin, and modified acrylate resin. The characteristics of resin film are high translucency, no optical anisotropy, dimensional stability, surface smoothness, friction resistance, bending resistance, high electrical insulation, chemical resistance, liquid crystal resistance, heat resistance , Moisture resistance, gas barrier properties, etc. are required.

As the transparent electrodes 13 and 14, transparent electrodes such as ITO and Nesa films can be used, and those formed on the transparent substrate 12 by a sputtering method or a vacuum evaporation method are used. Further, as the transparent electrode 14 in the lowermost layer, a black electrode can be used including the role as a light absorber.

As the liquid crystal 16, a liquid crystal exhibiting a cholesteric phase at room temperature is particularly preferable. Further, a chiral nematic liquid crystal obtained by adding a chiral dopant to a nematic liquid crystal can be used.

The nematic liquid crystal has rod-shaped liquid crystal polymers arranged in parallel, but does not have a layered structure. As the nematic liquid crystal, various single liquid crystals such as a biphenyl compound, a tolan compound, a pyrimidine compound, and a cyclohexane compound, or a mixed liquid crystal thereof can be used.
Those having a positive dielectric anisotropy are preferred. Specifically, a liquid crystal K15 mainly containing a cyanobiphenyl compound is used.
, M15, mixed liquid crystal MN1000XX (all manufactured by Chisso), E44, ZLI-1565, TL-213, B
L-035 (all manufactured by Merck).

The chiral dopant is an additive having a function of twisting the molecules of the nematic liquid crystal when added to the nematic liquid crystal. By adding a chiral dopant to a nematic liquid crystal, a helical structure of liquid crystal molecules having a predetermined twist interval is generated, thereby exhibiting a cholesteric phase.

The chiral nematic liquid crystal has an advantage that the pitch of the helical structure can be changed by changing the addition amount of the chiral dopant, thereby controlling the selective reflection wavelength of the liquid crystal. In addition,
In general, as a term representing the pitch of the helical structure of liquid crystal molecules, a “helical pitch” defined by a distance between molecules when the liquid crystal molecules rotate 360 degrees along the helical structure of the liquid crystal molecules is used.

As the chiral dopant, those having a layered helical structure in nematic liquid crystal molecules can be used. For example, it is a nematic liquid crystal such as a biphenyl compound, a terphenyl compound or an ester compound. Specifically, commercially available chiral dopants S811, CB1 obtained by bonding an optically active group as a terminal group of the compound.
5, S1011, CE2 (all manufactured by Merck) and the like can be used. A cholesteric liquid crystal having a cholesteric ring represented by cholesteric nonanoate (CN) can also be used as a chiral dopant.

As the chiral dopant to be added to the nematic liquid crystal, plural kinds of chiral dopants may be mixed and used. In addition to the combination of the same kind of optical rotation, a combination of different kinds of optical rotation can also be used. The use of multiple types of chiral dopants not only changes the phase transition temperature of cholesteric liquid crystals, reduces the change in selective reflection wavelength in response to temperature changes, but also provides dielectric anisotropy, refractive index anisotropy and viscosity. And other properties of the cholesteric liquid crystal can be changed, thereby improving the characteristics of the display device.

The materials used for the columnar structure 15 include:
For example, a thermoplastic resin can be used. For this purpose, a material which is softened by heating and solidified by cooling, is desired not to cause a chemical reaction with a liquid crystal material to be used and to have appropriate elasticity.

As specific examples, for example, polyvinyl chloride resin, polyvinylidene chloride resin, polymethacrylate resin, polyacrylate resin, polyvinyl acetate resin, polystyrene resin, polyamide resin, polyethylene resin, polypropylene resin, fluorine resin Resins, polyurethane resins, polyacrylonitrile resins, polyvinyl ether resins, polyvinyl ketone resins, polyvinyl pyrrolidone resins, polycarbonate resins, chlorinated polyether resins, and the like.

The columnar structure 15 may be formed singly or as a mixture of a plurality thereof, or a material containing at least one or a mixture thereof.

The substance is printed by a known printing method using a pattern so as to form dot columns. Depending on the size of the liquid crystal display element and the pixel resolution, the size of the cross-sectional shape, arrangement pitch, and shape (cylinder, drum, polygon, etc.)
Is appropriately selected. Further, it is more preferable to arrange the columnar structures 15 preferentially between the electrodes 13 because the aperture ratio is improved.

The shape may be a stripe shape instead of a dot shape, and may be selected according to the purpose. Further, in order to improve the accuracy of the gap control between the substrates 12, the columnar structures 15
When forming a spacer material having a size smaller than the thickness of the resin, for example, glass fibers, ball-shaped glass or ceramic powder, or spherical particles made of an organic material, the gap is changed by heating or pressing. If it is made difficult, gap accuracy is further improved, and voltage unevenness, color unevenness and the like can be reduced.

(Display of Color) In the color display layers 11R, 11G, and 11B using such a chiral nematic liquid crystal, when the selective reflection wavelength of the cholesteric liquid crystal is in the visible light region, the helical axis of the cholesteric liquid crystal molecule is aligned with the substrate surface. In the focal conic arrangement state which is almost parallel to the visible light, the light is slightly scattered with respect to incident visible light, but is almost transparent. Also,
In a planar arrangement state in which the helical axis of the cholesteric liquid crystal molecules is substantially perpendicular to the substrate surface, light having a wavelength corresponding to the helical pitch is selectively reflected with respect to incident visible light. These two states can be switched by a change in a field such as a predetermined electric field, magnetic field, or temperature. Even when the field disappears, each state is maintained, that is, it has a memory property.

In the case where a chiral nematic liquid crystal is used from the above characteristics, the amount of the chiral dopant added to the nematic liquid crystal is adjusted so that the helical pitch of the chiral nematic liquid crystal can be adjusted by the selective reflection wavelength.
By adjusting the wavelengths to correspond to the red, green, and blue light, respectively, it selectively reflects light in the wavelength ranges corresponding to red, green, and blue, respectively, in the planar arrangement state, In the state of alignment, a liquid crystal material which is transparent and transmits visible light can be obtained. By sandwiching the thus obtained liquid crystal material between the transparent electrodes, a color liquid crystal display element can be obtained.

(Addition of Dye for Improving Color Purity and Contrast, Arrangement of Color Filter)
In R, 11G, and 11B, in order to improve the color purity of the display performed by selective reflection and to absorb a light component that leads to a decrease in the transparency in the transparent state, a dye is added to each color display layer, or a dye equivalent thereto is added. A colored filter layer that provides an effect, that is, a plate member such as a color glass filter or a color film may be provided on each color display layer. The dye may be added to any of the liquid crystal material, the resin material, the transparent electrode material, and the transparent substrate material constituting each color display layer, and a plurality of the constituent elements may contain the dye. However, in order not to lower the display quality, the dye to be added and the filter layer to be added are:
It is desirable not to hinder color display by selective reflection of each color display layer.

As the dye to be added to the liquid crystal material, conventionally known various dyes can be used. For example,
Various dyes such as resin dyes and liquid crystal display dichroic dyes can be used. Specific examples of the dye for resin dyeing include SPR-Red1 and SPR-Yellow1.
(All manufactured by Mitsui Toatsu Dye Co., Ltd.). Further, specific examples of the dichroic dye for liquid crystal display include SI-426,
M-483 (all manufactured by Mitsui Toatsu Dye Co., Ltd.). Among these dyes, a dye that does not hinder display by the selective reflection wavelength of the liquid crystal and absorbs spectral light in a wavelength region that causes a reduction in display may be appropriately selected and used for each color display layer. Further, as described above, since the light component that degrades the display quality is considered to be mainly present on the short wavelength side, the dye that absorbs the spectrum light in the wavelength range shorter than the selective reflection wavelength of the liquid crystal. Is more preferably used.

The amount of the dye to be added is not particularly limited as long as the switching operation characteristic for displaying a liquid crystal is not remarkably reduced.
It is preferable to add the above, and about 1% by weight is sufficient.

When a color filter is employed in place of the addition of a dye, an additional filter layer material may be a colorless and transparent substance to which a dye is added. It may be a material that is inherently colored without adding a dye, or a thin film of a specific substance that functions similarly to the dye. Specific examples of the filter layer include commercially available colored glass filters and Wratten gelatin filter Nos. 8, no. 25 (all manufactured by Eastman Kodak Co.) can be used. Of course, instead of disposing the filter layer, the transparent substrate 12
It is clear that the same effect can be obtained even if the filter itself is replaced with the above-mentioned filter layer material.

(Color Display Method) In the liquid crystal display element 10 in which the respective color display layers 11R, 11G, 11B manufactured by the above-described material constitutions are laminated, the blue display layer 11B and the green display layer 11G are formed by the liquid crystal 16 being focal. A red display can be performed by setting the transparent state in the conic arrangement and the selective reflection state in which the liquid crystal 16 has the planar arrangement in the red display layer 11R. Further, the blue display layer 11B is set in a transparent state in which the liquid crystal 16 is in a focal conic arrangement, and the green display layer 11G and the red display layer 11R are
Is set in the selective reflection state in which the elements are in a planar arrangement, so that yellow display can be performed. Similarly, red, green, blue, white, cyan, magenta, yellow, and black can be displayed by appropriately selecting the state of each color display layer between a transparent state and a selective reflection state. Further, by selecting an intermediate selective reflection state as the state of each color display layer 11R, 11G, 11B, display of an intermediate color becomes possible, and it can be used as a full-color display element.

Each color display layer 11 in the liquid crystal display element 10
The order of lamination of R, 11G, and 11B may be other than that shown in FIG. However, considering that the transmittance of the light in the long wavelength region is higher than that in the short wavelength region, the selective reflection wavelength of the liquid crystal contained in the upper layer is changed to that of the liquid crystal contained in the lower layer. It is better to keep it shorter than the wavelength
Since more light is transmitted to the lower layer, a bright display can be performed. Therefore, it is most desirable to sequentially form the blue display layer 11B, the green display layer 11G, and the red display layer 11R in order from the observation side (the direction of arrow A), and this state provides the most preferable display quality.

(Production Example of Liquid Crystal Display Element) The resin columnar structure 15 is formed on the upper substrate 12 by the printing method. FIG. 2 shows the upper substrate 12 in this state. here,
The resin film as the substrate was made of 20 μm PES (polyether sulfone: manufactured by Sumitomo Bakelite Co., Ltd.), and a screen printing coater MS400 (manufactured by Murakami Co., Ltd.) having a thickness of about 15 μm in a dot pattern of polyvinyl chloride was formed thereon. And printed.

On this resin film, an ITO thin film was formed in a belt shape with a thickness of 700 angstroms by a known sputtering method. Subsequently, a silicon oxide film was laminated to a thickness of 4000 angstroms using the same device to form an insulating film. Next, the temperature of the resin film was adjusted to 25 ° C., and a sealing material 17 was printed around the thermoplastic polyester resin using the screen printing applicator MS400. After printing, the whole is 80 ° C on a hot plate,
Heating was performed for 20 minutes, and the solvent contained in the columnar structure 15 and the sealing material 17 was dried.

As a result, the diameter was 35 μm, the height was 10 μm,
A columnar structure 15 having a pitch of 300 μm and a sealing material 17 having a width of 1 mm and a height of 10 μm were formed.

Next, SE-610 was used as an orientation control material.
(Manufactured by Nissan Chemical Industries, Ltd.) by a known spin coating method to about 50
It was applied to a thickness of 0 Å and heated at 180 ° C. for 1 hour.

Next, another PES serving as the lower substrate
(Same as the upper side) is prepared, and the strip-shaped transparent electrode surface is superimposed on the upper side film, and the liquid crystal 16 is dropped between the two films 12 by the apparatus shown in FIG.
The liquid crystal 16 was sealed while heating and pressing with. However, at this stage, the sealing region at the end was opened without heating and pressing so that excess liquid crystal could be discharged to the outside.

Next, the two superposed films 12 were sandwiched between two stainless steel flat plates to obtain 0.37 kg / cm.
^With a load of ² applied, the film 12 was left in a thermostat at 160 ° C. for 1 hour, and the entire surface of the film 12 was bonded. Thereafter, the power of the thermostat was turned off, and the chamber was cooled to room temperature while applying a load.
Ultraviolet-curable resin Photolec A-704-60 (manufactured by Sekisui Fine Chemical Co., Ltd.) was applied to the peripheral portions of both films 12 and irradiated with ultraviolet light to complete the sealing.

As a liquid crystal material, MLC6068-00 is used.
No. 0 (a nematic liquid crystal material manufactured by Merck) and 2.4 wt% of a chiral material S-811 (manufactured by Merck) were added. Using the cholesteric liquid crystal display device thus manufactured, a full-color liquid crystal display device 10 was manufactured.

(Driving Circuit and Driving Method of Display Element) Since the pixel configuration in each display layer of the liquid crystal display element 10 is a simple matrix, as shown in FIG.
1, R2 to Rm and an m × n matrix of signal electrodes C1, C2 to Cn. A pixel at the intersection of the scanning electrode Ra and the signal electrode Cb (a and b are natural numbers satisfying a ≦ m and b ≦ n) is defined as LCa-b. Further, these electrode groups are respectively a scan drive IC 21 and a signal drive IC 22.
Of the driving ICs 21 and
From 22, a scanning voltage and a selection voltage are applied to each electrode.

The driving circuit of the liquid crystal display element 10 is not limited to the matrix-structured driver, and the signal driving IC is provided for each line of the scanning driving IC 21.
The image data may be transferred serially from 22 via a line latch memory. In this case, the scanning drive IC 21 is not line-compatible, but needs to be for serial use, and the cost of the driver is low.

In the liquid crystal display element 10, the display state of the liquid crystal is a function of the applied voltage and the pulse width. When a pulse voltage having a constant width is applied to the liquid crystal after resetting the liquid crystal to a focal conic state showing the lowest Y value (luminous reflectance) at first, the display state becomes as shown in FIG. Changes. In FIG. 5, the vertical axis represents the Y value, and the horizontal axis represents the applied voltage. When the pulse of the voltage Vp is applied, the planar state showing the highest Y value is selected, and the voltage Vf
Is applied, the focal conic state showing the lowest Y value is selected. When an intermediate voltage is applied, a state in which the planar state and the focal conic state exhibiting an intermediate Y value are mixed is selected, and halftone display becomes possible.

FIGS. 6A and 6B show the waveforms (a) and (b) of the pulse voltage applied to the liquid crystal of the test cell prototyped by the present inventors. Here, only the selection signal is applied from the signal electrode during scanning with respect to only one pixel. The voltage of the reset signal is 50 V, the pulse width (reset time) is 200 msec at the wavelength (a), and 50 msec at the wavelength (b).
And Then, a selection signal for setting the liquid crystal to the planar state was applied at a voltage of 110 V for 5 msec. Although 110 V is used here, the value is not limited to this value, and another value can be taken depending on the material, thickness, and pulse width of the voltage of the liquid crystal.

As shown in the waveform (a), when the reset signal is applied for 200 msec, the selection signal is applied regardless of the state of the liquid crystal before the reset is in the planar state or the focal conic state. A good planar state was obtained, and gradation expression when the voltage value of the selection signal was changed was also possible. On the other hand, as shown in the waveform (b), when the reset signal was applied for 50 msec, the liquid crystal was not always reset sufficiently, and the Y value when the liquid crystal was set to the planar state thereafter varied.

It has been found from the above experiments that the longer the reset signal application time is, the less likely it is to be affected by the state before rewriting, and that if the time is sufficiently long, the desired display state can be rewritten irrespective of the state before rewriting. It is. In other words, by applying the reset signal for a sufficiently long time,
No longer affected by the previous state. In the waveform (a), it was found that the display time of about 4 gradations was possible with the application time of the reset signal being 200 msec.
By applying a reset signal of c or more, there is no difference in the selected display state due to the difference in the initial state, and a display of four or more gradations is possible.

(Fast-forward display mode, phase transition drive) FIG.
5A and 5B show pulse voltage waveforms (a) and (b) when the liquid crystal display element 10 is driven in the fast-forward display mode. The fast-forward display mode includes a reset period, which is a first period, a selection period, which is a second period, and a state maintaining period, which is a third period.

In the waveform (a), first, a pulse voltage of 100 V was applied to reset the liquid crystal to a homeotropic state. No pulse voltage was applied during the selection period, and a pulse voltage of 50 V was applied during the state maintaining period. In this case, the liquid crystal changes to and maintains the focal conic state and scatters incident light (off state). Also, in the waveform (b), 100 V is applied following the reset to the homeotropic state.
Was applied for 1.5 msec, and a pulse voltage of 50 V was applied in the state maintaining period. In this case, the liquid crystal changes to and maintains a planar state and transmits / reflects incident light (on state). By selecting the waveforms (a) and (b) according to the image information, an on / off binary image can be displayed.

(First Example of Normal Display Mode) FIG. 8 shows a pulse voltage waveform of a first example in which the liquid crystal display element 10 is driven with a gradation in the normal display mode. In the first example, the liquid crystal is reset to a focal conic state in a reset period (first period), and a selection period (second period) is performed.
In the above, a pulse voltage changing in two steps was applied for 3 msec to reproduce the gradation. The applied voltage is set to 0 in the state maintaining period (third period).

In driving in the fast-forward display mode shown in FIG. 7 and the normal display mode shown in FIG. 8 (the same applies to the normal display mode shown in FIG. 9), the pulse waveform created by the pulse generator is used by the amplifier. After the voltage was increased to the required voltage, the voltage was applied to the driver terminal of the liquid crystal display element 10 using a multiplexer having a multi-terminal type voltage switching element.

(Second Example of Normal Display Mode) FIG. 9 shows a pulse voltage waveform of a second example in which the liquid crystal display element 10 is driven with a gradation in the normal display mode. The reset period is the same as that of the first example (see FIG. 8). In the selection period, a pulse voltage of 120 V is applied to each pixel for 1 msec.
It is applied N times at 1 msec intervals c times. The number of times N is arbitrary, but if the number of times is small, an image with low contrast is displayed. For example, it is set so that the final image of full contrast is displayed by applying the fourth pulse voltage. In this case, an expression similar to fade-in is possible. If the image can be grasped in the middle of the fade-in, an instruction to display the next page is input, and if the display is switched to the next page, the same usage as the fast-forward display mode is finally achieved.

FIG. 10 shows an information display device 1 according to an embodiment of the present invention including a drive / image signal processing circuit 20 adapted to rewrite image data. The scanning drive IC 21 and the signal drive IC 22 are connected to the liquid crystal display element 10,
These ICs 21 and 22 are driven by control signals from a scanning controller 23 and a signal controller 24 having a built-in time counter. Image data to be newly displayed is input from the memory 26 to the signal controller 24, but is converted into a selection signal by the image data conversion means 25 before that.

The time counter counts the timing of rewriting the image on the liquid crystal display element 10 when the fast-forward display mode is selected. The memory 26 stores image data of a plurality of pages, and outputs the image data displayed at a timing based on the count of the time counter in the order of pages. Further, the memory 26 is provided with a CPU 3 described below.
3 is stored.

(First of enlarged display in fast-forward display mode)
Example) FIG. 11 shows a first example of enlarged display in the fast-forward display mode.
Here is an example. FIG. 11A shows a normal display screen in the fast-forward display mode for comparison, in which one dot of information data is displayed corresponding to one pixel of the display element 10. In this case, since each character information is displayed in a normal size, and the screens are sequentially switched quickly, it is difficult to follow the display with eyes. On the other hand, in the enlarged display shown in FIG. 11B, one pixel of the information data is displayed on the display element 10 so as to correspond to four dots. Therefore, even if the screen is switched at the same speed, the information is enlarged (however,
Although the amount of information is reduced to 1/4), it is easy to see, and this is a preferable display form especially for a user with weak vision.

(Second display of enlarged display in fast-forward display mode)
Example) FIG. 12 shows a second example of enlarged display in the fast-forward display mode.
Here is an example. In the second example, the display of one pixel of the information data corresponding to four dots of the display element 10 is the same as the first example, but the display is performed by thinning out one pixel (4 dots) at a time. Since the information itself is expanded, it will not be difficult to see even if it is thinned out.

(Third of enlarged display in fast-forward display mode)
Example) FIG. 13 shows a third example of enlarged display in the fast-forward display mode.
Here is an example. In the third example, one pixel of the information data is displayed corresponding to 9 dots of the display element 10. That is, the character information is enlarged and displayed with emphasis on a bold line.

FIG. 14 shows a circuit configuration in which only a portion changed when information is rewritten can be partially rewritten. Since the liquid crystal display element 10 has memory characteristics, partial rewriting is possible.

First, the current image data is stored in the image memory 1. The image data to be newly displayed is stored in the image memory 2. Line memory 1 has image memory 1
, Data per scanning electrode is read out and stored. In addition, data is similarly read from the image memory 2 and stored in the line memory 2. This line memory 1,
The data of No. 2 is compared by the comparing means, here the comparator 41, and the line numbers which do not match are stored in the address storage means. In this way, only the part that changes from the current image is extracted for each scanning electrode, and is set as a rewriting target.

A predetermined time is set in advance in a time counter built in the controller 24, and when this time has elapsed, the scanning controller 23 and the data signal controller 24 store the address stored in the address storage means 42. Referring to FIG. 3, the control signal is supplied to the scanning signal driving IC 2 so that only the liquid crystal on the corresponding scanning electrode is rewritten.
1. Output to the data signal drive IC 22. As a result, the scanning signal driving IC 21 and the data signal driving IC 22 drive only the liquid crystal to be rewritten. According to such a driving method, only the portion to be rewritten can be rewritten, and display can be performed faster than rewriting the entire screen.

(Information Display Device) FIG. 15 shows an information display device 80 in the form of a portable electronic book using display elements 81 other than liquid crystal. As the display element 81, organic E
L (electroluminescence) or PDP (plasma display panel) can be used. These display elements 81 are of a light-emitting type, all of which have a very fast drive response speed, and can achieve a sufficient response (several tens of microseconds) even when driven in the fast-forward display mode described above. Note that an electronic book can be formed using various display elements other than LE and PDP, which have good responsiveness and can be configured to be small and thin. Of course, the display device 80 shown in FIG. 15 may be formed using liquid crystal.

In the information display device 80, reference numeral 82 denotes a power switch, 83 denotes an operation key group, and the operation key 83a is a fast-forward display mode selection key. When the key 83a is turned on, the fast forward display mode is executed. When the key 83a is turned on again, the mode returns to the normal still image display mode. The operation key 83b is a page feed instruction key in the normal display mode. When the key 83b is turned on, an image of the next page is displayed on the display element 81.

FIG. 16 shows a case where the liquid crystal display element 10 is
3 shows a portable electronic book type information display device 40 disposed on the left and right sides of a cover 45 which can be folded. It goes without saying that a light-emitting display element 81 or the like shown in FIG. 15 may be used instead of the liquid crystal display element 10. Here, the element 10 on the left is screen 1 and the element 10 on the right is screen 2. The information display device 40 displays character information when the screen 2 is an odd page and the screen 1 is an even page when displaying vertical Japanese text. When the fast-forward display mode is selected, the screen 2 displays 1 from the right to the left.
The display (image scanning) is sequentially performed line by line, and the screen 1 is sequentially displayed (image scanning) line by line from left to right.

[0080] As shown in FIG. 17, if flip through pages with open book, information of the central portion X ₂ is not able to see much, tends to glance information on both sides X _1. Thus, in the fast-forward display mode, to shorten the scanning time so as to display an enlarged only information on both sides X _1,
Display one after another in page order. The display speed is improved by reducing the number of lines in the display area. The observer can display the page in full by switching from the fast forward display mode to the normal display mode on the page to be read.

In FIG. 16, reference numeral 43 denotes a power switch, and reference numeral 44 denotes an operation key group.
Is a fast-forward display mode selection key. When the key 44a is turned on, the fast forward display mode is executed. When the key 44a is turned on again, the mode returns to the normal still image display mode. The operation key 44b is a page feed instruction key in the normal display mode. When the key 44b is turned on, the screens 1 and 2 display the image of the next page.

FIG. 18 shows an example in which the fast forward display mode is executed by another method using the information display device 40 in the electronic book form shown in FIG. In this fast-forward display mode, images are sequentially enlarged on screens 1, 2, 1, 2,... And displayed in page order. For example, when displaying the images A, B, and C, the images A and B are sequentially displayed on the screens 1 and 2, and while the image B is being scanned, the image C starts to be scanned on the screen 1.
In this fast-forward display mode, the images of odd-numbered pages and even-numbered pages are displayed on the screens 1 and 2 while being sorted, thereby reducing the total display time. That is, by using two screens effectively, the time can be reduced to half that when displaying only one screen.

(Light Amount Compensation) In the liquid crystal display element 10, the amount of reflected light on the screen decreases at night or in a dark room. Therefore, as shown in FIG. 19, a front light 47 and a diffusion plate 48 for compensating the amount of reflected light are provided on the front surface of the liquid crystal display element 10. Front light 47 on,
Turning off or adjusting the light amount is performed by the light receiving sensor 4 shown in FIG.
9 based on the detection result. If the detected light amount is equal to or less than the predetermined value, the light amount of the front light 47 is increased, and if the detected light amount exceeds the predetermined value, the light amount of the front light 47 is fixed to a relatively low constant value or the light 47 is turned off.

Note that such light quantity compensation is not limited to the electronic book type, but may be a wall-mounted display element 10 shown in FIG.
And the like.

Further, a temperature sensor is provided in place of the light receiving sensor 49, and when the temperature detected by the temperature sensor exceeds a predetermined value, the currently displayed screen is reset once, and the driving voltage at the time of writing is reset. Also rewrite at a lower voltage. The contrast of the liquid crystal used in the present embodiment becomes too large as the temperature rises. Therefore, it is preferable to recover the contrast that has become too large due to the temperature rise. A change in contrast due to a temperature change has a large adverse effect in the fast-forward display mode, and is effective in the fast-forward display mode.

FIG. 20 shows an example of a display method of the liquid crystal display element 10. Here, the screen of the display element 10 is divided into an image information area 10a and a character information area 10b, and the image information area 10a is displayed in the fast-forward display mode by the phase transition drive shown in FIG. Usually, it is considered that the image information has a larger information amount than the character information, and the information can be easily specified. Therefore, when image information and character information are mixed on one screen, the image information is preferentially displayed in the fast forward display mode, the image to be displayed is determined, and the corresponding character information is displayed in the normal display mode. Display.

(Control procedure in fast-forward display mode) FIG. 21
Shows a first example of a control procedure in the fast-forward display mode. Here, by selecting and enlarging a plurality of lines of character information to be displayed on one page and enlarging and displaying the first half and the second half, the outline of the character information can be checked quickly, and the display information itself is displayed one character at a time. Displayed without collapse.

That is, in step S11, the liquid crystal display element 10
Is reset (see display state 1), and if there is a fast-forward write request in step 12, the first half of one page of information is enlarged and written in step S14 (see display state 2). Next, if there is a second half display request in step S15, the second half is enlarged and written in step S16 (see display state 3).
This means that the character information of one page is fast-forward displayed in the first half and the second half. Next, if there is a full reset request in step S17, the process returns to step S11 to perform reset processing. In such control means, the period during which the display states 1, 2, and 3 are displayed is a period until a write request, a second half display request, or a full reset request is made (see steps S13 and S18).

The information of one page may be divided into three or more parts and written. Step S1
A request to display the next page may be issued from 4.

FIG. 22 shows a second example of the control procedure in the fast-forward display mode. Here, only a plurality of lines of the character information of each page are selected, a low-resolution display is started from the first writing (enlarged display), and the resolution is increased with an increase in the number of writings. Display at full resolution by writing.

That is, in step S21, the liquid crystal display element 10
Is reset to start image display, and step S2
In step 2, the first writing (enlarged display) is performed. Here 1
The first plurality of lines of the character information of the page are selected and displayed at a low resolution (1/4 thinning). Next, it is determined whether or not a display screen is selected in step S23. Here, if the observer selects to view the screen with another higher resolution (YES in step S23), the second writing is performed in step S24, and the character information of a plurality of lines is displayed with one higher resolution. . If the observer selects to view the next page (NO in step 23), step S21
Returning to step S22, the same display as described above is performed on the next page in the next step S22.

Next, if there is a request to write another row in step S25, the flow returns to step S21 to start writing the next plurality of rows. If there is no request to write another row,
In step S26, a third writing operation is performed to further increase the resolution by one step. Similarly, in step S27, it is determined whether or not there is a request to write another row. If there is no request, the fourth writing is performed in step S28, and the display at full resolution is completed. Until there is a request to write another row in step S29, the display at full resolution is maintained in step S30.

(Information Display System) FIG. 23 shows a first example of an information display system using the information display device 40. In this system, an information display device 40 and a host device 50 are combined into an electronic book form shown in FIG. The host device 50 includes a signal processing unit 52, a controller 53, a driver 54, and a power supply 55. The information recording medium 51 is a card type memory, a CD-
It is a well-known recording medium such as a ROM or a magnetic memory, and is purchased or rented from a store such as a convenience store by a user and inserted into the host device 50. The information data from the inserted information recording medium 51 is input to the signal processing unit 52. Of course, such a system can be configured using the information display device 80 shown in FIG.

The information display device 40 shown in FIG. 23 is constituted by the circuit shown in FIG. Here, the host device 50
Receiving the information data transferred from the driver 54 of the receiving circuit 3
1 and input to the CPU 33 via the demodulation circuit 32 and further stored in the memory 35. The display of information on the liquid crystal display element 10 is performed by reading data from the memory 35 and driving the display element 10 by the drive / image signal processing circuit 20. The power supply unit 36 supplies power to various circuits in the display device 40.

FIG. 25 shows a second example of the information display system. This system is an electronic book type information display device 40.
And the host device 50 ′, and one host device 5
The information data can be transferred from 0 'to a plurality of information display devices 40.

The host device 50 'is provided with an IRDA (infrared communication means) 56 at an output portion, and transfers information data to the information display device 40 by remote control. In this system, for example, if a host device 50 'is installed in one room of a building, information can be transferred to the information display devices 40 at a plurality of locations. That is, a plurality of users can view information of the same source. In addition, IRDA5
Instead of 6, other communication means such as a frequency modulation communication means may be used.

(Information Display Device with Speaker) FIG.
The information display device 40 'provided with the speaker 61 is shown. The speaker 61 has a film shape and is provided below the liquid crystal display element 10. Further, the host device 50 shown in FIG. 23 is also incorporated in the device 40 ', and the information recording medium 51 is inserted. Further, an operation unit 62 for volume control and information display is installed integrally with the power supply unit and the like. Although the speaker 61 plays audio information stored in the medium 51 in advance, in the fast forward display mode, the display information can be supplemented with audio information. Also, the audio may be fast-forwarded in synchronization with the fast-forward of the screen. Note that the headphones 63 may be provided instead of the speakers 61, or may be provided together.

(Bending System) FIG.
5, a first example of a bending system for supplying an information recording medium 51 to a user having the information display device 40 shown in FIGS. 16 and 23 is shown. Information recording medium 51
Is manufactured by a publisher or the like as an electronic information maker, and is brought into a convenience store, which is a dealer, via a dedicated cable, dedicated communication using radio waves, or a maintenance man. The user purchases or rents the desired recording medium 51 at the convenience store. The user may store desired information in the display device 40 owned by the user at the convenience store.

FIG. 28 shows a second example of the bending system. In this vending system, an electronic information maker transfers information ordered by a user after viewing a catalog or the like to a user's personal computer 75 via a cable (telephone line). The user outputs the information transferred on the screen of the personal computer 75 or stores the information in the recording medium 51 owned by the user, and inputs the information to the information display device 40 via the recording medium 51. In addition, the electronic information maker that has received the order is
1 may be delivered directly to the user.

(Other Embodiments) The information display apparatus and the display method according to the present invention are not limited to the above embodiments, but can be variously changed within the scope of the invention. In particular, specific examples and numerical values of various materials such as a liquid crystal are merely examples. Further, there are various usages and display contents of the display device or the system, and an optimum control method may be adopted.

As the liquid crystal display element, besides the reflection element 10 of the full-color system, a conventionally known transmission type liquid crystal display element using a backlight (which may be monochrome) can be used. .

[Brief description of the drawings]

FIG. 1 is a sectional view showing an example of a liquid crystal display element used in an information display device or an information display system according to the present invention.

FIG. 2 is a plan view showing a state in which a columnar structure and a sealing material are formed on a film substrate of the liquid crystal display element.

FIG. 3 is an explanatory view showing a manufacturing process of the liquid crystal display element.

FIG. 4 is a block diagram showing a matrix drive circuit of the liquid crystal display element.

FIG. 5 is a graph showing a relationship between a voltage applied to a selection signal and a Y value in the matrix driving circuit.

FIG. 6 is a chart showing a voltage waveform experimentally applied to a test cell.

FIG. 7 is a chart showing a voltage waveform applied in a fast-forward display mode.

FIG. 8 is a chart showing a first example of a voltage waveform applied in a normal display mode.

FIG. 9 is a chart showing a second example of a voltage waveform applied in the normal display mode.

FIG. 10 is a block diagram showing a driving / image signal processing circuit used in an embodiment of the present invention.

11A is a plan view illustrating a normal display screen in a fast-forward display mode, and FIG. 11B is a plan view illustrating a first example of performing enlarged display in the fast-forward display mode.

FIG. 12 is a plan view showing a second example of performing enlarged display in the fast-forward display mode.

FIG. 13 is a plan view showing a third example of performing enlarged display in the fast-forward display mode.

FIG. 14 is a block diagram showing another example of the driving circuit of the liquid crystal display element.

FIG. 15 is a plan view showing an example of an information display device as an electronic book form.

FIG. 16 is a plan view showing a display example in a fast-forward display mode in another example of the information display device in the form of an electronic book.

FIG. 17 is a perspective view showing a state where a book is opened.

18 is a plan view showing another display example in the fast-forward display mode in the information display device in the electronic book form shown in FIG.

FIG. 19 is a schematic side view showing an example in which a front light is attached to the information display device.

FIG. 20 is an explanatory diagram illustrating an example of a display method on a liquid crystal display element.

FIG. 21 is a flowchart showing a first example of a control procedure in the fast-forward display mode.

FIG. 22 is a flowchart showing a second example of the control procedure in the fast-forward display mode.

FIG. 23 is a block diagram showing a first example of an information display system according to the present invention.

24 is a block diagram showing a control circuit incorporated in the information display device shown in FIG.

FIG. 25 is a block diagram showing a second example of the information display system according to the present invention.

FIG. 26 is a plan view showing an information display device incorporating a speaker.

FIG. 27 is an explanatory diagram illustrating a first example of a recording medium bending system.

FIG. 28 is an explanatory diagram showing a second example of the recording medium bending system.

[Description of Signs] 1, 40, 40 ', 80: Information display device 10, 81: Display element 16: Liquid crystal 20: Driving / image signal processing circuit 31: Receiving circuit 50, 50': Host device

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Makiko Manbukuro 2-3-13 Azuchicho, Chuo-ku, Osaka-shi, Osaka Inside Osaka International Building Minolta Co., Ltd. (72) Inventor Naoki Shozumi, Osaka-shi, Chuo-ku, Osaka 2-13-13 Azuchicho Osaka International Building Minolta Co., Ltd. F-term (reference) 2H089 HA33 KA19 QA16 RA12 TA07 UA09 5C094 AA01 AA15 AA52 BA27 BA31 BA43 BA49 CA19 CA20 DA06 EB02 GA10 HA10

Claims (19)

[Claims] 1. A display element that forms a screen with a plurality of pixels arranged two-dimensionally, a driving unit that selectively drives the display element one pixel at a time, and a partial display when a fast-forward display mode is executed. An information display device comprising: control means for enlarging and displaying information to be displayed. 2. A display element forming a screen with a plurality of pixels arranged two-dimensionally, a driving unit for selectively driving the display element one pixel at a time, and displaying information of one screen entirely. An information display device comprising: a normal display mode; a fast-forward display mode in which information to be displayed is partially enlarged and displayed; and selection means for selecting the normal display mode and the fast-forward display mode. . 3. The information display device according to claim 1, further comprising a receiving unit that receives information data transferred from outside. 4. The information display device according to claim 1, further comprising a film speaker. 5. The information display device according to claim 1, wherein the display element is a reflection type liquid crystal display element having a memory property. 6. The information display device according to claim 5, wherein the liquid crystal display element has a structure in which a liquid crystal and a resin structure are sandwiched between a pair of resin films. 7. The information display device according to claim 1, wherein the display element is an electroluminescence display element. 8. The information display device according to claim 1, wherein the display element is a plasma display panel display element. 9. A display method of an information display device for selectively driving a plurality of pixels arranged two-dimensionally to display information on a screen, wherein the information to be partially displayed is enlarged when a fast-forward mode is executed. A display method characterized by displaying the information. 10. A display method of an information display device for selectively driving a plurality of two-dimensionally arranged pixels to display information on a screen, wherein a part of information to be displayed is partially enlarged and a fast forward display mode is provided. A display method characterized by performing: 11. The display method according to claim 9, wherein in the fast-forward display mode, a plurality of lines on a screen are selected to display low-resolution information. 12. The display method according to claim 9, wherein in the fast-forward display mode, a plurality of images are displayed only at a leading portion of each image. 13. The display method according to claim 9, wherein in the fast-forward display mode, the character information is displayed in an enlarged and thick line. 14. When displaying vertically written character information on two screens on the left and right, character information is displayed from right to left on the screen on the right screen, and character information is displayed from left to right on the screen on the left screen. 11. The display method according to claim 9 or claim 10, wherein 15. The display method according to claim 9, wherein when the character information is fast-forward displayed, one or more lines are omitted and displayed. 16. The method according to claim 9, wherein when information is fast-forward displayed on a plurality of screens, display driving to another screen is started while information is displayed on one screen. Display method of description. 17. The method according to claim 9, wherein when a plurality of pieces of information are sequentially fast-forward displayed on one screen, the next information is displayed in a screen area that does not overlap with the information currently being displayed. Display method. 18. The information processing apparatus according to claim 9, wherein in the fast-forward display mode, information to be displayed next is displayed using information data synthesized so as not to overlap information currently being displayed. Display method. 19. The display method according to claim 9, wherein when image information and character information are mixed on one screen, only the image information is fast-forward displayed.