JP3465255B2 - Optical device and driving method thereof - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical device (for example, a numeral or a character or an X-character whose light transmittance can be controlled).
The present invention relates to a display element or device for performing Y matrix display, an optical filter) and a driving method thereof.

[0002]

2. Description of the Related Art In recent years, with the development of electronics technology, electrochromic (hereinafter sometimes referred to as EC) materials and the like have been used in electrically driven voltage-driven display devices to display, for example, time. It is used in digital watches.

For example, an electrochromic display element (hereinafter, also referred to as an ECD) is a non-emissive display device, and since it is a display by reflected light or transmitted light, it can be observed for a long time. Also has the advantage of being less tired, and has the advantages of relatively low driving voltage and low power consumption. For example, JP-A-59-24
As disclosed in Japanese Patent No. 879, there is known a liquid type ECD which uses an organic molecule-based viologen molecule derivative which forms a reversibly colored and decolored state as an EC material.

FIG. 13 shows an example 10 of a conventional ECD. A pair of transparent substrates (for example, glass plates) 4 and 5 forming a display cell are displayed with a spacer 6 at a constant interval. A transparent electrode (for example, an ITO (Indi
um Tin Oxide) electrodes 2 and 3 are provided to face each other in a predetermined pattern.

A liquid 1 of an electrochromic (EC) material such as a viologen molecule derivative is sealed between the counter electrodes 2-3 in contact with these electrodes. One of the counter electrodes 2 and 3 is used as an anode, and the other is used as a cathode. By applying a DC drive voltage between them for a predetermined time, the EC material 1 reversibly changes its light transmission amount and is colored or colored. The color can be erased and the desired display pattern can be observed.

In such an ECD 10, one pixel PX is configured as shown in FIGS. 14 and 15, and for example, conduction to the transparent electrode 3 formed on the substrate 5 is performed by one electrode. On the other hand, it is general to connect one lead wire 7 made of metal (for example, gold, chromium, copper, etc.) and lead this to an external connection terminal.

In this case, however, coloring and erasing are performed by switching the voltage applied to the transparent electrode 3 by using only one lead wire 7. Therefore, at the time of switching, as shown by the phantom line in FIG. SiO ₂ coating the lead wire 7
A voltage for coloring or decoloring is not sufficiently applied near the boundary between the insulating film 8 and the transparent electrode 3 etc., so that many unerased portions are likely to occur. Such an increase in the unerased portion causes a visual defect in the display portion and greatly shortens the life of the display element itself. In addition, it was also a cause of uneven coloring.

[0008]

SUMMARY OF THE INVENTION An object of the present invention is to provide an optical device capable of sufficiently changing the amount of light transmission such as coloring and decoloring, and greatly reducing unevenness and defects such as unerased light. It is to provide the driving method.

[0009]

That is, the first invention of the present invention is to provide an amount of light transmission (especially coloring) by driving these electrodes between opposed electrodes (for example, the above-mentioned transparent electrodes 3 and 2: hereinafter the same). In an optical device in which a substance whose hue such as decoloring: hereinafter the same) changes (for example, the above-mentioned EC material 1: hereinafter the same) is arranged, at least one electrode of the counter electrodes is An EC having a plurality of types of lead wires for driving (for example, a lead wire 27 for erasing and a lead wire 37 for coloring which will be described later: the same applies hereinafter)
The present invention relates to an optical device such as D (hereinafter the same).

In order to drive the optical device according to the first aspect of the present invention, the present invention provides, as a second aspect of the present invention, a first lead wire (for example, an erasing lead wire 27 described below: , The same), and a driving voltage is applied to a second lead wire (for example, a coloring lead wire 37 to be described later: hereinafter the same) when reducing the light transmission amount.
A method of driving an optical device is provided.

In a third aspect of the present invention, in an optical device in which a substance whose light transmission amount changes by driving these electrodes is arranged between the counter electrodes, at least one of the counter electrodes is 1 Each has a plurality of lead wires for driving, one of these lead wires (for example, a lead wire 77 described below: hereinafter, the same) is connected to the peripheral portion of the electrode, and the other (for example, a lead wire described later). There is also provided an optical device characterized in that the line 47: the same applies hereinafter) is connected to the central position of the electrode or in the vicinity thereof.

In order to drive the optical device according to the third aspect of the present invention, the present invention provides, as a fourth aspect of the invention, a drive of the optical device in which the one lead wire and the other lead wire are simultaneously energized to increase or decrease the light transmission amount. It provides a method.

Furthermore, the present invention is, as a fifth invention, an optical device in which a substance whose light transmission amount is changed by driving these electrodes is arranged between the counter electrodes, wherein at least one of the counter electrodes is Each one has a first lead wire and a second lead wire for driving,
The lead wire has a plurality of lead wires, and one of these lead wires (for example, a lead wire 77 described below: the same applies hereinafter)
Is connected to the peripheral portion of the electrode, and the other (for example, a lead wire 47 described below: hereinafter, the same) is connected to the central position of the electrode or the vicinity thereof, and the second lead wire is also a plurality of lead wires. And one of these lead wires (for example, a lead wire 67 described below: hereinafter, the same) is connected to a peripheral portion of the electrode, and the other (for example, a lead wire 57 described below: hereinafter, the same) is connected to the electrode. Also provided is an optical device characterized in that the optical device is connected to the central position of or in the vicinity thereof.

In order to drive the optical device according to the fifth aspect of the present invention, as a sixth aspect of the present invention, the one and the other lead wires of the first lead wire are simultaneously energized to increase or decrease the light transmission amount. On the contrary, in order to reduce or increase the light transmission amount, a driving voltage is simultaneously applied to the one lead wire and the other lead wire of the second lead wire. Is.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION In the above first invention, second invention, third invention, fourth invention, fifth invention and sixth invention of the present invention, specifically, a transparent electrode (for example, the above-mentioned transparent electrode) is used. Three
And 2: hereinafter the same) and a spacer (for example, the above-mentioned spacer 6: hereinafter the same) is sandwiched between a pair of substrates each provided with a lead wire in a predetermined pattern, and between the pair of substrates held by the spacer. The display device is filled with a material that can reversibly adjust the amount of light transmission by driving the transparent electrode. For one of the transparent electrodes, two types of lead wires (for example, lead wires 27 and 3 described later) are provided.
7: same as below), or a plurality of lead wires (for example, lead wires 47 and 77 described later: same below), or first and second lead wires (for example, lead wires 47, 77 and 57, 67 described below: The same shall apply hereinafter).

In the first and second inventions, a first lead wire (for example, a lead wire 2 to be described later) is provided for one of the electrodes.
7: The same applies hereinafter) and a second lead wire (for example, a lead wire 37 described below: the same applies below), and the first lead wire is an annular lead wire attached to the peripheral portion of the electrode. And a lead wire portion extending from the annular lead wire portion to the external connection terminal side, and the second lead wire is connected to the electrode outside the annular lead wire portion to the external connection terminal side. It should be extended.

Further, in the third and fourth inventions, the electrode has a notch portion (for example, a slit-like notch portion 50 described later) partially notched from one side to a central position thereof, and one of the leads is provided. The wire comprises a substantially annular lead wire portion attached to the peripheral portion of the electrode and a lead wire portion extending from the lead wire portion to the external connection terminal side, and the other lead wire is the cutout portion. It is preferable that the electrode be connected to the electrode at or near the central position facing to and extend to the external connection terminal side.

Further, in the fifth and sixth inventions, the first and second cutout portions (for example, slit-like cutouts to be described later) in which the electrodes are partially cut out from the one side and the other side thereof to the central position are formed. 50 and 60), and one of the first lead wires has a substantially annular lead wire portion attached to the peripheral portion of the electrode and a lead extending from the lead wire portion to the external connection terminal side. A second lead wire that is connected to the electrode and extends toward the external connection terminal at the central position facing the first cutout portion or in the vicinity thereof, and the second lead One of the lead wires is composed of a substantially annular lead wire portion attached to the peripheral portion of the electrode and a lead wire portion extending from this lead wire portion to the external connection terminal side, and the other lead wire is , The center facing the second notch It is preferable that the electrode be connected to the electrode at or near the position and extend to the external connection terminal side.

In the first invention, the second invention, the third invention, the fourth invention, the fifth invention and the sixth invention, the first lead wire and the second lead wire, or one and the other lead wire. Each of the two may be formed by patterning a common metal layer, and the lead wire may be covered with an insulating layer.

[0020]

EXAMPLES Examples of the present invention will be described below.

1 to 7 show a first embodiment in which the present invention is applied to an ECD (electrochromic display device).

First, the structure of the ECD according to this embodiment will be described with reference to FIGS. 1 to 6. The ECD basically has the same structure as that of the conventional example shown in FIG. 13 except for the transparent electrode and its wiring. Therefore, mainly different parts will be described.

That is, for example, for the ITO transparent electrode 3 to which a driving voltage is applied in order to reversibly adjust the light transmission amount of an EC material such as a viologen molecule derivative, a plurality of ITO transparent electrodes 3 per one transparent electrode 3 constituting one pixel PX are provided. A type of lead wire, that is, a first lead wire 27 and a second lead wire 37 are connected.

Of these, the first lead wire 27 includes a square annular lead wire portion 27a attached to the peripheral portion of the square transparent electrode 3 and an external connection terminal (of the substrate 5) from the annular lead wire portion 27a. Although it is a contact which is connected to the outside such as a connector at one end, it is composed of a lead wire portion 27b extending to the side (not shown: hereinafter the same). Also, the second lead wire 37
Are contact portions 3a, 3b, 3 which are respectively provided on the three sides of the transparent electrode 3 so as to project outside the annular lead wire portion 27a.
It is composed of lead wire portions 37a, 37b, 37c connected on c and a lead wire portion 37d connecting these lead wire portions and extending to the external connection terminal side.

Both the first lead wire 27 and the second lead wire 37 are provided to establish electrical continuity between the individual transparent electrodes 3 and the external connection terminals (see FIG. 6). Here, the former lead wire is used. Wire 27 is for erasing EC material, and lead wire 37 of the latter is E
Used for coloring C material.

Each of the first lead wire 27 and the second lead wire 37 is formed by patterning a common metal layer made of gold, chromium, copper, nickel or the like as described later.

Each lead wire 27, 37 is covered with an insulating film 28 such as SiO ₂ (phantom line in FIGS. 4 and 5), and E
It is designed so as not to be exposed to the C material (electrolytic solution).

Each of the contact portions 3a, 3b, 3c forms a part of the transparent electrode 3 and is made of the same layer, but is completely covered with the insulating film 28 including the lead wire portion 27a. (See FIGS. 3 to 5). Therefore, the EC material is erased or colored only in the exposed transparent electrode 3 (pixel PX) which is not covered with the insulating film 28.

FIG. 7 shows a process of forming the above-mentioned lead wires 27 and 37 together with the transparent electrode 3 on the substrate 5. This process is described next.

First, on the surface of the transparent glass substrate 5, (A)
ITO film 43 by vacuum deposition or sputtering
Is formed into a film and is processed into a predetermined pattern (see FIG. 1 or FIG. 6) by photolithography as shown in (B) to form the transparent electrode 3.

Then, as shown in (C), a metal 40 such as copper is deposited on the entire surface by a vacuum evaporation method or a sputtering method, and this is subjected to a predetermined pattern by photolithography as shown in (D) (see FIG. 1 or 6). Processed into each lead wire 27 and
Form 37 respectively.

Then, as shown in (E), a SiO ₂ film 48 is deposited on the entire surface by CVD (chemical vapor deposition), and further processed into a predetermined pattern by photolithography as shown in (F). An insulating film 28 that covers the lead wires 27 and 37 and exposes the surface of the transparent electrode 3 as the pixel PX so as to contact the EC material is formed.

As described above, the transparent electrode 3 and the lead wires 27 and 37 are formed in a predetermined pattern on the transparent substrate 5 to form a group of pixels PX having a matrix pattern as shown in FIG. 6, for example. be able to. Incidentally, similarly to this, the transparent electrode 2 and each lead wire can be formed in a predetermined pattern on the other transparent substrate 4, and the ECD can be assembled in the same manner as described in FIG. 13 (the same applies hereinafter). .

Next, a method of driving the ECD constructed as described above will be described.

When the coloring and erasing are repeated by driving only the lead wire 37 as in the above-mentioned conventional technique, the unerased portion may occur in the vicinity of the boundary line between the transparent electrode 3 and the insulating film 28.
Due to this, unevenness in material deposition (coloring) is likely to occur. Further, when both the coloring and the erasing are performed using the lead wire 27 (lead wire portions 27a and 27b), the concentration of the current density near the boundary line described above also occurs at the time of coloring, which eventually causes an increase in the unerased portion. Will be.

On the other hand, in the present embodiment, at the time of coloring, the lead wire 27 (lead wire portions 27a and 27b) is not driven, only the lead wire 37 is driven, and a drive voltage is externally applied thereto. When the color is erased, the drive of the lead wire 37 is stopped, only the lead wire 27 (lead wire portions 27a and 27b) is driven, and a drive voltage is externally applied thereto.

That is, the separate lead wires 27 and 37 are selected and driven at the time of erasing and coloring, respectively, so that the transparent electrode 3 is electrically connected at each operation through the metal of low resistance. , A high voltage for decoloring or coloring can be efficiently applied to the transparent electrode 3, and the transparent electrode 3 and the insulating film
Since the current density is concentrated near the boundary with 28, it is possible to wipe out the remaining portion near the boundary.

Therefore, when the lead wire 37 (lead wire portions 37a, 37b, 37c, 37d) is used for coloring and the lead wire 27 (lead wire portions 27a, 27b) is used for decoloring,
It is very effective in that the color erasing can be sufficiently performed, the remaining color and uneven coloring are eliminated, the display of the pixel PX is improved, and the life as a display element is extended. Further, since coloring and erasing are performed by separate lead wires, the drive voltage required for each is lower than that when performing coloring and erasing with one lead wire, which results in lower driving voltage. Low power consumption is possible.

Although the lead wire 37 is arranged so as to be in contact with the contact portions 3a, 3b and 3c on the three sides of the transparent electrode 3 which are provided in a protruding manner, since the three contact portions are provided in this manner, the driving voltage is increased. Can be applied from each side, and coloring or decoloring of the transparent electrode 3 can be performed as uniformly as possible.

The voltage driving method may be applied as the coloring and erasing driving method, but the current driving method may also be used. In either case, in order to increase the coloring-decoloring speed, a driving method in which a rectangular shape is changed from a high voltage value or a high current value to a low voltage value or a low current value can be used.

FIG. 8 shows an EC according to the second embodiment of the present invention.
3 shows a main part of D.

In this embodiment, as compared with the example shown in FIG. 1, the contact portions 3a, 3b, 3c of the transparent electrode 3 are eliminated, the area of the transparent electrode 3 is enlarged instead, and each side is formed in the peripheral portion. The lead wire portions 37a and 37c for coloring are routed along and are connected to the lead wire portion 37d.

Even with this structure, it is clear that the same effects as those of the first embodiment described above can be obtained. Since the lead wire portions 37a and 37c of the lead wire 37 are in contact with each other in the peripheral portion of the transparent electrode 3 along each side, the drive voltage can be more sufficiently applied from each side and coloring or erasing can be further achieved. It can be performed uniformly.

9 and 10 show the essential parts of an ECD according to the third embodiment of the present invention.

In this embodiment, the transparent electrode 3 has a slit-like cutout portion 50 that is partially cut away from one side to the central position, and is processed into a U-shape, and one lead wire 77 is formed. A lead wire portion 77a of a substantially annular quadrangle that is attached to the peripheral portion of the transparent electrode 3 and a lead wire portion 77b extending from the lead wire portion 77a to the external connection terminal side, and
The other lead wire 47 is connected to the transparent electrode 3 at the semicircular tip portion 47A at or near the electrode center position facing the cutout portion 50 and extends to the external connection terminal side.

Normally, when electrical continuity is established in the peripheral portion of the transparent electrode 3 by the annular lead portion 77a as described above, there is a difference depending on the size of one transparent electrode, but the distance is greater in the central portion than in the peripheral portion. The voltage drop due to the resistance of the transparent electrode 3 itself (tens of Ω / sq.) Increases in proportion to
As a result, coloring unevenness that the coloring becomes thin easily occurs.

Therefore, if the two lead wires 77 and 47 are simultaneously energized to the outer peripheral portion and the central portion of the transparent electrode 3 as in the present embodiment, a sufficient voltage is generated in both the outer peripheral portion and the central portion. Since the problem of voltage drop as described above does not occur when applied, uneven coloring can be reduced. this is,
The same applies when erasing color, and it is possible to eliminate the remaining color.

In order to prevent the display from being visually affected by the reduction of the pixel area due to the cutout portion 50 of the transparent electrode 3,
It is desirable to determine the width of the cutout portion 50, and correspondingly, the width of the lead wire 47 is preferably set to about 0.1 mm.

In this embodiment also, the lead wires 77 and 47 are used.
Is formed by patterning a common metal layer (for example, a metal layer of gold, chromium, nickel, copper, or the like), and the transparent electrode 3 is I
It may be formed of TO or SnO ₂ .

11 and 12 show the essential parts of an ECD according to the fourth embodiment of the present invention.

In this embodiment, similarly to the third embodiment described above, the transparent electrode 3 has a slit-like cutout portion 50 that is partially cut out from one side to the central position, and the lead wire Reference numeral 77 denotes a substantially annular rectangular lead wire portion 77a attached to the peripheral portion of the transparent electrode 3 and the lead wire portion 77a.
From a lead wire portion 77b extending to the external connection terminal side, and the lead wire 47 is connected to the transparent electrode 3 at or near the electrode center position facing the cutout portion 50 at the semicircular tip portion 47A thereof. Extend to the external connection terminal side.

Then, a slit-like cutout portion 60 (which has the same shape as the cutout portion 50) is cut out partially from the other side of the transparent electrode 3 (the side opposite to the one side) to the central position. And a lead wire 67 (having the same shape and size as the lead wire 47) is attached to the peripheral portion of the transparent electrode 3 (outer side of the lead wire portion 77a). Lead wire portions 67a, 67e, 67c and lead wire portions extending from these lead wire portions to the external connection terminal side
67d, and the lead wire 57 is connected to the transparent electrode 3 at the semicircular tip portion 57A facing the lead wire portion 47 at or near the electrode center position facing the cutout portion 60. , Extends to the external connection terminal side.

The lead wire 67 (lead wire portions 67a, 67
e, 67c) and 57 are connected to the lead wires 77 and
Separated from 47 and above the leads 67 and 57 is further Si
It is covered with an insulating layer 78 such as O ₂ .

As in the present embodiment, two lead wires 77 and 47 are provided for the outer peripheral portion and the central portion of the transparent electrode 3, respectively, and
Using 67 and 57, the former lead wires 77 and 47 for coloring, the latter lead wires 67 and 57 for erasing, and energizing them at the same time, sufficient voltage is applied to both the outer peripheral portion and the central portion, The above-mentioned voltage drop problem does not occur.

Therefore, it is possible to reduce the coloring unevenness when the lead wires 77 and 47 are driven, and it is also possible to eliminate the unerased residue when the lead wires 67 and 57 are driven. Besides, the configuration is similar to that of the third embodiment described above, and the same effect can be obtained.

Although the embodiments of the present invention have been described above, the above embodiments can be further modified based on the technical idea of the present invention.

For example, the above-described lead wire pattern and position, the number of lead wires, the connection structure with the transparent electrode, and the like are not limited to those described above, and may be variously modified.

Further, the structure of the optical element including the transparent electrode pattern, the material of each component, and the driving method are not limited to those described above. For example, the electrode pattern as shown in FIG. 6 may be variously changed into a stripe shape, a lattice shape, or the like, or E different for each divided electrode.
The cells of the C material can be divided and juxtaposed.

The type and concentration of the EC material described above may be specified in various ways. In addition to the EC material, a liquid crystal material may be used.
It can also be configured and driven as a liquid crystal display element. The material of the transparent electrode is not limited to ITO, and SnO ₂ or the like can be selected in various ways.

Further, the optical device according to the present invention is another known optical device (for example, an inorganic electrochromic material,
It is also possible to combine it with a liquid crystal or an electroluminescent material). Further, the present invention is widely applied not only as a display, but also as an optical diaphragm for a CCD, as an electric light control element, as various optical systems, and as a light amount control for electrophotographic copying machines and optical communication devices. It is possible.

[0061]

As described above, according to the present invention, in an optical device in which a substance whose light transmission amount is changed by driving these electrodes is arranged between the counter electrodes, at least one of the counter electrodes is 1 Each of them has a plurality of types of lead wires for driving, a drive voltage is applied to the first lead wire when increasing the light transmission amount, and a second voltage is applied when decreasing the light transmission amount. Since the drive voltage is applied to the lead wire, separate lead wires are selected and driven at the time of erasing and coloring, respectively, so that the metal lead wire having low resistance up to the electrodes is made conductive at each operation, Therefore, a high voltage for erasing or coloring can be efficiently applied to the electrode, and the current density is concentrated near the boundary line between the electrode and the insulating film. Can be wiped out.

Therefore, when using one lead wire for coloring and using the other lead wire for erasing,
It is very effective in that the color can be sufficiently erased, the remaining color and uneven coloring are eliminated, and the life of the optical element is extended. Further, since coloring and erasing are performed by separate lead wires, the drive voltage required for each is lower than that when performing coloring and erasing with one lead wire, which results in lower driving voltage. Low power consumption is possible.

[Brief description of drawings]

FIG. 1 is a plan view of a main part of an ECD (electrochromic display device) according to a first embodiment of the present invention.

FIG. 2 is a perspective view of the main part.

FIG. 3 is a plan view of a part of the main part.

4 is a sectional view taken along line IV-IV in FIG.

5 is a sectional view taken along line VV of FIG.

FIG. 6 is a plan view of a part of the ECD.

FIG. 7 is a cross-sectional view showing a main part of the manufacturing process of the EC.

FIG. 8 is a plan view of an essential part of an ECD according to a second embodiment of the present invention.

FIG. 9 is a plan view of an essential part of an ECD according to a third embodiment of the present invention.

10 is a cross-sectional view taken along line XX of FIG. 9.

FIG. 11 is a plan view of an essential part of an ECD according to a fourth embodiment of the present invention.

12 is a sectional view taken along line XII-XII in FIG. 11.

FIG. 13 is a sectional view of an ECD.

FIG. 14 is a plan view of a main part of an ECD according to a conventional example.

15 is a sectional view taken along line XV-XV in FIG. 14.

[Explanation of symbols]

1 ... EC (electrochromic) material, 2, 3 ... Transparent electrodes, 3a, 3b, 3c ... Contact parts, 4, 5 ... Transparent substrate,
6 ... Spacer, 10 ... ECD (electrochromic display element), 27, 37, 47, 57, 67, 77 ... Lead wire, 27a, 27
b, 37a, 37b, 37c, 37d, 67a, 67c, 67d, 67
e, 77a, 77b ... Lead wire portion, 28, 48, 78 ... Insulating film, 5
0, 60 ... Notch, 47A, 57A ... Tip, PX ... Pixel

Claims (30)

(57) [Claims] 1. In an optical device in which a substance whose light transmission amount changes by driving of these electrodes is arranged between opposed electrodes, at least one electrode of said opposed electrodes is provided for each of said electrodes. An optical device having a plurality of types of lead wires. 2. A transparent electrode and a lead wire sandwich a spacer between a pair of substrates provided in a predetermined pattern, and reversibly transmit light by driving the transparent electrode between the pair of substrates held by the spacer. The optical device according to claim 1, wherein the optical device is configured as a display element filled with a substance whose amount can be adjusted, and is electrically connected to one of the transparent electrodes by two types of lead wires. 3. An annular lead wire portion in which a first lead wire and a second lead wire are attached to one of the electrodes, and the first lead wire is attached to a peripheral portion of the electrode. And a lead wire portion extending from the annular lead wire portion to the external connection terminal side, and the second lead wire is connected to the electrode outside the annular lead wire portion and extends to the external connection terminal side. The optical device according to claim 1, wherein 4. The optical device according to claim 3, wherein each of the first lead wire and the second lead wire is formed by patterning a common metal layer. 5. The optical device according to claim 1, wherein the lead wire is covered with an insulating layer. 6. A first lead wire for driving, wherein a substance whose light transmission amount changes by driving these electrodes is disposed between the counter electrodes, and at least one electrode of the counter electrodes is provided for each electrode. When driving an optical device having a second lead wire and a second lead wire, a drive voltage is applied to the first lead wire when increasing the light transmission amount, and the drive voltage is applied when decreasing the light transmission amount. A method of driving an optical device, wherein a driving voltage is applied to a second lead wire. 7. A transparent electrode and a lead wire sandwich a spacer between a pair of substrates provided in a predetermined pattern, and reversibly transmit light by driving the transparent electrode between the pair of substrates held by the spacer. 7. An optical device, which is configured as a display element filled with a substance whose amount can be adjusted, and drives one of the transparent electrodes to be electrically connected by first and second lead wires. The described driving method. 8. The first lead wire comprises an annular lead wire portion adhered to the peripheral portion of the electrode and a lead wire portion extending from the annular lead wire portion to the external connection terminal side, and the second lead wire portion is provided. 7. The driving method according to claim 6, wherein the lead wire drives an optical device connected to the electrode outside the annular lead wire portion and extending to the external connection terminal side. 9. The driving method according to claim 8, wherein each of the first lead wire and the second lead wire drives an optical device formed by patterning a common metal layer. 10. The driving method according to claim 6, further comprising: driving an optical device in which the first and second lead wires are covered with an insulating layer. 11. In an optical device in which a substance whose light transmission amount changes by driving of these electrodes is arranged between opposed electrodes, at least one electrode of the opposed electrodes is provided for each of the electrodes. An optical device having a plurality of lead wires, wherein one of these lead wires is connected to a peripheral portion of the electrode and the other is connected to a central position of the electrode or the vicinity thereof. 12. A transparent electrode and a lead wire sandwich a spacer between a pair of substrates provided in a predetermined pattern, and reversibly transmit light by driving the transparent electrode between the pair of substrates held by the spacer. 12. The optical device according to claim 11, which is configured as a display element filled with a substance whose amount can be adjusted, and is electrically connected to one of the transparent electrodes by a plurality of lead wires. 13. The electrode has a cutout part that is partially cut out from one side thereof to a central position, and one lead wire is a substantially annular lead wire part that is attached to a peripheral part of the electrode. And a lead wire portion extending from the lead wire portion to the external connection terminal side, and the other lead wire is connected to the electrode at or near the central position facing the cutout portion and the external connection terminal side. Extending to claim 11.
The optical device described in 1. 14. The optical device according to claim 13, wherein the one lead wire and the other lead wire are formed by patterning a common metal layer. 15. The optical device according to claim 11, wherein one and the other lead wires are covered with an insulating layer. 16. A material, the amount of light of which is changed by driving these electrodes, is arranged between the opposing electrodes, and at least one electrode of the opposing electrodes is provided with a plurality of lead wires for the driving. When driving an optical device having one of these lead wires connected to the peripheral portion of the electrode and the other connected to the central position of the electrode or in the vicinity thereof,
A method for driving an optical device, wherein the one and the other lead wires are simultaneously energized to increase or decrease the light transmission amount. 17. A transparent electrode and a lead wire sandwich a spacer between a pair of substrates provided in a predetermined pattern, and reversibly transmit light by driving the transparent electrode between the pair of substrates held by the spacer. The driving method according to claim 16, which is configured as a display element filled with a substance whose amount can be adjusted, and drives an optical device that is electrically connected to a plurality of lead wires with respect to one of the transparent electrodes. . 18. The electrode has a cutout part partially cut away from one side thereof to a central position thereof, and one lead wire is a substantially annular lead wire adhered to a peripheral part of the electrode. Portion and a lead wire portion extending from this lead wire portion to the external connection terminal side, and the other lead wire is connected to the electrode at or near the central position facing the cutout portion and the external connection terminal 17. The driving method according to claim 16, wherein the optical device extending to the side is driven. 19. The driving method according to claim 18, wherein the one and the other lead wires drive the optical device formed by patterning a common metal layer. 20. The driving method according to claim 16, wherein an optical device in which one and the other lead wires are covered with an insulating layer is driven. 21. In an optical device in which a substance whose light transmission amount changes by driving of these electrodes is arranged between the counter electrodes, at least one electrode of the counter electrodes corresponds to one electrode for driving. A first lead wire and a second lead wire, wherein the first lead wire has a plurality of lead wires, one of the lead wires being connected to a peripheral portion of the electrode, and the other Is connected to the central position of the electrode or in the vicinity thereof, and the second lead wire also has a plurality of lead wires, one of these lead wires being connected to the peripheral portion of the electrode, and the other Is connected to the central position of the electrode or the vicinity thereof. 22. A transparent electrode and a lead wire sandwich a spacer between a pair of substrates provided in a predetermined pattern, and reversibly transmit light by driving the transparent electrode between the pair of substrates held by the spacer. 22. The optical device according to claim 21, which is configured as a display element filled with a substance whose amount can be adjusted, and is electrically connected to one of the transparent electrodes by first and second lead wires. 23. The electrode has first and second cutout portions that are partially cut out from one side and the other side of the electrode toward a central position, and one lead wire of the first lead wire comprises: It is composed of a substantially annular lead wire portion attached to the peripheral portion of the electrode and a lead wire portion extending from the lead wire portion to the external connection terminal side, and the other lead wire is the first cutout portion. Of the second lead wire is connected to the electrode at the central position or in the vicinity thereof and extends to the external connection terminal side, and one lead wire of the second lead wire is a substantially annular shape attached to the peripheral portion of the electrode. A lead wire portion and a lead wire portion extending from the lead wire portion to the external connection terminal side, and the other lead wire is connected to the electrode at the central position facing the second cutout portion or in the vicinity thereof. Is extended to the external connection terminal side Optical device according to claim 21. 24. The optical device according to claim 23, wherein one and the other lead wires of the first and second lead wires are formed by patterning a common metal layer. 25. The one and the other lead wires of the first and second lead wires are covered with an insulating layer.
The optical device described in 1. 26. In an optical device in which a substance whose light transmission amount changes by driving these electrodes is arranged between opposed electrodes, at least one electrode of the opposed electrodes is provided for each of the electrodes. A first lead wire and a second lead wire, wherein the first lead wire has a plurality of lead wires, one of the lead wires being connected to a peripheral portion of the electrode, and the other Is connected to the central position of the electrode or in the vicinity thereof, and the second lead wire also has a plurality of lead wires, one of these lead wires being connected to the peripheral portion of the electrode, and the other When driving an optical device connected to the central position of the electrode or in the vicinity thereof, the one and the other lead wires of the first lead wire are simultaneously energized to increase or decrease the light transmission amount, On the contrary, the light In order to reduce or increase the excess, at the same time applies a driving voltage to said one and the other lead of the second lead, the driving method of the optical device. 27. A transparent electrode and a lead wire sandwich a spacer between a pair of substrates provided in a predetermined pattern, and reversibly transmit light by driving the transparent electrode between the pair of substrates held by the spacer. 27. An optical device which is configured as a display element filled with a substance whose amount can be adjusted, and which drives an optical device connected to one of the transparent electrodes by first and second lead wires. The described driving method. 28. The electrode has first and second cutout portions that are partially cut away from one side and the other side thereof to a central position thereof, and one lead wire of the first lead wire is ,
It is composed of a substantially annular lead wire portion attached to the peripheral portion of the electrode and a lead wire portion extending from the lead wire portion to the external connection terminal side, and the other lead wire is the first cutout portion. Of the second lead wire is connected to the electrode at the central position or in the vicinity thereof and extends to the external connection terminal side, and one lead wire of the second lead wire is a substantially annular shape attached to the peripheral portion of the electrode. A lead wire portion and a lead wire portion extending from the lead wire portion to the external connection terminal side, and
27. The driving method according to claim 26, wherein the other lead wire drives an optical device connected to the electrode and extending to the external connection terminal side at or near a central position facing the second cutout portion. 29. The driving method according to claim 28, wherein one and the other lead wires of the first and second lead wires drive an optical device which is formed by patterning a common metal layer. 30. The driving method according to claim 26, wherein an optical device in which one and the other lead wires of the first and second lead wires are covered with an insulating layer is driven.