CN100403479C

CN100403479C - Electrode pair structure of plasma display

Info

Publication number: CN100403479C
Application number: CNB021419612A
Authority: CN
Inventors: 简钰庭; 黄日锋
Original assignee: AU Optronics Corp
Current assignee: AU Optronics Corp
Priority date: 2002-08-29
Filing date: 2002-08-29
Publication date: 2008-07-16
Anticipated expiration: 2022-08-29
Also published as: CN1479340A

Abstract

The present invention provides an electrode pair structure of a plasma display. The electrode pair structure comprises a first metal electrode and a second metal electrode, wherein the first metal electrode is arranged on the surface of a front base plate, the second metal electrode and the first metal electrode are arranged on the surface of the front base plate in parallel, and a plurality of hexagonal hollow metal structures are connected in series to form the first metal electrode and the second metal electrode.

Description

A kind of electrode pair structure of plasma scope

Invention field

The present invention relates to a kind of plasma scope, relate in particular to a kind of electrode pair structure that is applied to plasma scope.

Background technology

Generally speaking, display unit can be divided into cathode ray tube (cathode ray tube) and two kinds of patterns of flat-panel screens, and flat-panel screens can be divided into LCD, plasma scope and Field Emission Display (field emission display, FED) etc.Wherein because plasma scope has gently, approach, easy maximization, the no width of cloth is penetrated and do not have the visual angle problem, so become the main flow of following large scale full-color display.

Please refer to Fig. 1 and Fig. 2, Fig. 1 is the structural representation of existing plasma scope 10, and Fig. 2 is the generalized section of Fig. 1 along tangent line 2-2 '.Existing plasma scope 10 consists predominantly of a prebasal plate 12, a metacoxal plate 14 and prebasal plate 12 parallel being oppositely arranged, and an ionized gas 16 is filled between prebasal plate 12 and the metacoxal plate 14.In addition; plasma scope 10 includes a plurality of electrode pairs that are arranged in parallel (electrode pair) 18 and is located at prebasal plate 12 surfaces; one black line (black matrix) layer 20 is arranged at prebasal plate 12 surfaces in electrode pair 18 outsides; in order to increase image comparison; one transparent dielectric layer 22 is arranged on the prebasal plate 12; and be covered on electrode pair 18 and the black lamina 20; and one protective layer 24 be arranged on the transparent dielectric layer 20; in order to prevent the ionic bombardment transparent dielectric layer 20 and electrode pair 18 in the ionized gas, to increase the life-span of plasma scope 10.

Electrode pair 18 includes two parallel electrodes 18a and electrode 18b, and has a discharging gap (discharge gap) 26 between two electrode 18a and the 18b.Electrode 18a includes and keeps electrode (sustaining electrode) 28a and an auxiliary electrode (bus electrode) 30a is arranged on the outside of keeping electrode 28a, and electrode 18b also includes and keeps electrode 28b and an auxiliary electrode 30b is arranged on the outside of keeping electrode 28b.Generally speaking, keep electrode 28a with keep electrode 28b be by tin indium oxide (Indium Tin Oxide, ITO) or tin ash (SnO ₂) transparency electrode that constituted, its light transmission is good, but has bigger resistance value, and

auxiliary electrode

30a and 30b are the opaque electrodes that is made of chromium/copper/chromium (Cr/Cu/Cr) three-layer metal material or silver, though there is light transmission relatively poor, yet but have good conductivity, can be used to auxiliary electrode 28a and the 28b conduction kept.

In addition, plasma scope 10 includes a plurality of addressing electrodes (address electrode) 32 in addition, claim data electrode again, its with keep the orthogonal direction of electrode 28a and 28b and be arranged at metacoxal plate 14 surfaces abreast, one white reflective dielectric layer 34 is located on the metacoxal plate 14 and is covered each addressing electrode 32, in order to improve visible reflection of light to increase brightness, and provide flatness high plane, a plurality of barrier ribs that are parallel to each other (rib) 36 are arranged on the metacoxal plate 14 between the two adjacent addressing electrodes 32, and a redness, green and blue-

fluorescence layer

38R, 38G, 38B respectively and the compartment of terrain coat on the two side of dielectric layer 34 surface between each barrier rib 32 and each barrier rib 32.When ionized gas after exciting ionization, can produce ultraviolet irradiation

fluorescent layer

38R, 38G, 38B, and produce red, green or blue light respectively.

It should be noted that, in the process of making transparency electrode, be to utilize a physical sputtering (sputtering) technology to form a transparent conductive metal layer on prebasal plate earlier, carry out an etch process again, the transparent conductive metal layer is etched into the pattern of required transparency electrode.Yet, under the demand that the large scale and the resolution of plasma scope day by day increases, the electrode shape of transparency electrode and the required precision of thickness also improve thereupon, and transparency electrode still has bigger resistance value and weakens shortcomings such as brightness, therefore at present disclose a kind of plasma scope that omits transparency electrode, not only can reduce cost of manufacture and improve the technology acceptance rate.

Please refer to Fig. 3, Fig. 3 is the structural representation of existing a kind of modified form plasma scope 40.Plasma scope 40 is that with the difference of existing plasma scope 10 maximums plasma scope 40 omits the transparency electrode that is made on the prebasal plate, and directly metal electrode is produced on the prebasal plate surface, and utilize the metal auxiliary electrode of a fence (fence) structure to replace the metal auxiliary electrode that has elongate in shape now.

As shown in Figure 3, the metal auxiliary electrode that plasma scope 40 includes a fence structure is arranged at a prebasal plate (not being shown among Fig. 3) surface to 42, and a plurality of addressing electrodes 44, its with and the metal auxiliary electrode 42 orthogonal directions are set in parallel between the barrier rib (not being shown among Fig. 3) on a metacoxal plate (not being shown among Fig. 3) surface.The metal auxiliary electrode is to 42 metal electrode 42a and the 42b that include two fence structures that be arranged in parallel again, each

metal electrode

42a and 42b are made of three horizontal electrode 46a are connected horizontal electrode 46a with many vertical electrode 46b respectively, and the width H2 of

metal electrode

42a and 42b equates with the width H1 of transparency electrode 28a among Fig. 2 approximately.Wherein, vertical electrode 46b is mainly used to avoid when

metal electrode

42a and 42b break in manufacturing process or because of improper external force, electric current can be via vertical electrode 46b circulation to avoid producing the phenomenon of short circuit, and vertical electrode 46b can be located on the barrier rib (not being shown among Fig. 3) of its below, to avoid influencing the brightness of plasma scope 40 accordingly.

The existing plasma scope 40 that omits transparency electrode mainly is that metal electrode 42a and the 42b with fence structure directly is made in the prebasal plate surface, has therefore lacked the step of making transparency electrode, can reach the purpose of saving technology cost and reduction process complexity.Yet because the electrode zone of the metal electrode 42a of fence structure and 42b is too big, covered too much region of discharge, therefore significantly reduced the brightness that shows, therefore on the operational applications of reality, effect is also not satisfactory.

In addition, for the plasma scope 40 of above-mentioned omission transparency electrode design, because horizontal electrode 46a and its width of vertical electrode 46b of fence structure are very narrow, so in manufacturing process, the still very easy problem that produces lead rupture and cause not being electrically connected.And, resolution requirements raising along with plasma scope, add the restriction of the minimum feature of photoetching process, also will make that the metal electrode of making the fence structure with small live width can be day by day difficult, if yet the live width of metal electrode is constant, can causes the shading area to increase again and make the problem that brightness descends.

Summary of the invention

Main purpose of the present invention is to provide a kind of electrode pair structure of omitting the plasma scope of transparency electrode.

Secondary objective of the present invention is to provide a kind of polygonal metal electrode of the prebasal plate surface of being located at plasma scope to structure.

Another object of the present invention is to provide a kind of electrode pair structure that can not influence the display brightness of plasma scope and can improve the technology acceptance rate.

The preferred embodiments of the present invention disclose a kind of electrode pair structure of plasma scope.This electrode pair structure is arranged at a prebasal plate (front substrate) surface of this plasma display, this electrode pair structure includes one first metal electrode and is arranged at this prebasal plate surface, this first metal electrode is in series by the metal structure of a plurality of hexagons and hollow, and one second metal electrode and this first metal electrode be arranged at this prebasal plate surface abreast, this second metal electrode is in series by the metal structure of a plurality of hexagons and hollow, wherein the identical and size of the structure of this first metal electrode and this second metal electrode equates, the continuous part of wantonly two adjacent these metal structures is corresponding to be located on the barrier rib of its below and not to exceed the crossover region of described metal electrode and this barrier rib, and described barrier rib is located at the surface of the parallel metacoxal plate that is oppositely arranged with this prebasal plate.

The preferred embodiments of the present invention disclose a kind of electrode pair structure of plasma scope, this electrode pair structure is arranged at a prebasal plate surface of this plasma display, this electrode pair structure comprises: one first metal electrode is arranged at this prebasal plate surface, and this first metal electrode is in series by a plurality of first polygon endless metal structure; And one second metal electrode and this first metal electrode be arranged at this prebasal plate surface abreast, this second metal electrode is in series by a plurality of second polygon endless metal structure, and wherein respectively the discharging gap of this first polygon endless metal structure and corresponding respectively this second polygon endless metal structure is about equally; And on the corresponding barrier rib of being located at its below of the continuous part of wantonly two adjacent these metal structures and do not exceed the crossover region of described metal electrode and this barrier rib, described barrier rib is located at the surface of the parallel metacoxal plate that is oppositely arranged with this prebasal plate.

The preferred embodiments of the present invention disclose a kind of plasma scope, and this plasma display comprises: a metacoxal plate; A plurality of parallel each other barrier ribs are arranged at this metacoxal plate surface along a first direction; One prebasal plate, parallel relatively being arranged on this metacoxal plate; At least one electrode pair structure, be arranged at this prebasal plate surface of this metacoxal plate relatively along a second direction, and this electrode pair structure comprises: one first metal electrode is arranged at this prebasal plate surface, this first metal electrode is in series by a plurality of first polygon endless metal structure, and the continuous part of wantonly two adjacent these first polygon endless metal structures is corresponding to be located on this barrier rib of its below and not to exceed the crossover region of described metal electrode and this barrier rib, and width partly width greater than this barrier rib that should link to each other; And one second metal electrode and this first metal electrode be arranged at this prebasal plate surface abreast, this second metal electrode is in series by a plurality of second polygon endless metal structure, and the continuous part of wantonly two adjacent these second polygon endless metal structures is corresponding to be located on this barrier rib of its below and not to exceed the crossover region of described metal electrode and this barrier rib, and width partly width greater than this barrier rib that should link to each other; Wherein respectively the discharging gap of this first polygon endless metal structure and corresponding respectively this second polygon endless metal structure is about equally.

Plasma scope of the present invention mainly omits a transparency electrode of being located at the prebasal plate surface, and the metal electrode that will be in series by the metal structure of a plurality of polygons and hollow directly is made on the prebasal plate, to replace the existing electrode pair structure of transparency electrode and auxiliary electrode that has, not only can reduce process complexity, reduce the technology cost, and can not influence the display brightness and dark attitude contrast of plasma scope.

Description of drawings

Fig. 1 is the structural representation of existing plasma scope;

Fig. 2 is the generalized section of Fig. 1 along tangent line 2-2 ';

Fig. 3 is the structural representation of existing a kind of modified form plasma scope;

Fig. 4 is the top view of prebasal plate of the plasma scope of the preferred embodiment of the present invention;

Fig. 5 is the upper viewing view of the plasma scope of the preferred embodiment of the present invention;

Fig. 6 is the upper viewing view of the plasma scope of second embodiment of the invention; And

Fig. 7 to 11 is the right schematic diagram of metal electrode of the present invention.

Description of reference numerals in the accompanying drawing is as follows:

10 plasma scopes, 12 prebasal plates

14 metacoxal plates, 16 ionized gases

18 electrode pair 18a electrodes

18b electrode 20 black laminas

22 transparent dielectric layers, 24 protective layers

26 discharging gap 28a keep electrode

28b keeps electrode 30a auxiliary electrode

30b auxiliary electrode 32 addressing electrodes

34 white reflective dielectric layer 36 barrier ribs

The red fluorescent layer 38G of 38R green fluorescent layer

38B blue-fluorescence layer 40 plasma scope

42 metal electrodes are right

42a fence structure metal electrode

42b fence structure metal electrode 44 addressing electrodes

46a horizontal electrode 46b vertical electrode

50 plasma scopes, 52 prebasal plates

54 metal electrodes are to the 54a metal electrode

54b metal electrode 55 electric gaps

The metal structure of 56 hexagons and hollow

58 black lamina 60 barrier ribs

62 continuous part 70 plasma scopes

72 prebasal plates, 74 metal electrodes are right

74a metal electrode 74b metal electrode

75 discharging gaps, 76 hollow metal structures

78 thrusts, 80 barrier ribs

82 continuous part 92 metal electrodes are right

94 metal electrodes are right to 96 metal electrodes

98 metal electrodes are right to 100 metal electrodes

Embodiment

Please refer to Fig. 4 and Fig. 5, Fig. 4 is the top view of prebasal plate 52 of the plasma scope 50 of the preferred embodiment of the present invention, and Fig. 5 is the upper viewing view of the plasma scope 50 of the preferred embodiment of the present invention.As shown in Figure 4, plasma scope 50 of the present invention includes a plurality of opaque metal electrodes to 54 prebasal plate 52 surfaces that are arranged at plasma scope 50.Metal electrode is to be made of two mutual

parallel metal electrode

54a and 54b to 54, has a discharging gap 55 between two metal electrode 54a and the 54b, and

metal electrode

54a and 54b all are in series by the metal structure 56 of a plurality of hexagons and hollow.In addition, plasma scope 50 of the present invention includes a black lamina 58 in addition and is arranged at metal electrode to 54 outer prebasal plate 52 surfaces, and a transparent dielectric layer and a protective layer (all not being shown among Fig. 4) are arranged on the prebasal plate 52 in regular turn.

Generally speaking, the material that forms

metal electrode

54a and 54b is chromium/copper/chromium, and the method that forms

metal electrode

54a and 54b is to carry out a sputtering method or an electron beam evaporation plating method earlier to deposit three-layer metal in regular turn in prebasal plate 52 surfaces, carries out an etch process again to form required pattern.Perhaps, also can utilize the mode of a thick film screen printing that silver electrode paste (paste) directly is printed on prebasal plate 52 surfaces through the half tone with required pattern, to form metal electrode 54a and 54b.Wherein, the internal diameter of the metal structure 56 of each hollow is about between 150 to 180 microns, is preferably 164 microns.

As shown in Figure 5, it is parallel relative with prebasal plate 52 that plasma scope 50 of the present invention includes a metacoxal plate (not being shown among Fig. 5) in addition, and the metacoxal plate surface is provided with a plurality of barrier ribs that are parallel to each other (rib) 60, and its orientation is vertical with the long axis direction of 54b with metal electrode 54a.It should be noted that, the continuous part 62 of adjacent two metal structures 56 of the present invention corresponds on the barrier rib 60 of its below, to avoid influencing the display brightness of plasma scope 50, and the width of continuous part 62 makes that greater than the width of barrier rib 60 region of discharge is able to extend via protruding in barrier rib 60

outer metal electrode

54a and 54b.

Please refer to Fig. 6, Fig. 6 is the upper viewing view of the plasma scope 70 of second embodiment of the invention.As shown in Figure 6, plasma scope 70 of the present invention includes a plurality of opaque metal electrodes to 74 prebasal plate 72 surfaces that are arranged at plasma scope 70.Metal electrode is made of two mutual parallel metal electrode 74a and 74b 74, has a discharging gap 75 between two metal electrode 74a and the 74b, and metal electrode 74a and 74b are in series by the metal structure 76 of a plurality of hexagons and hollow respectively, and has a thrust (protrusion) 78 on the one side in each metal structure 76 outside, thrust 78 is identical with the formation material of metal structure 76, in order to extend the plasma discharge area, make plasma scope 70 can use lower operating voltage owing to have short internal diameter to the outside.Wherein, the width H4 that the width H3 of each metal structure 56 and metal structure 76 add thrust 78 among Fig. 4 about equally, and the internal diameter of each hollow metal structure 76 is about between 90 to 120 microns, is preferably 104 microns, and the width of thrust 78 is about between 50 to 70 microns, is preferably 64 microns.

In addition, it is parallel relative with prebasal plate 72 that plasma scope 70 of the present invention includes a metacoxal plate (not being shown among Fig. 6) in addition, and the metacoxal plate surface is provided with a plurality of barrier ribs that are parallel to each other (rib) 80, and its orientation is vertical with the long axis direction of 74b with metal electrode 74a.It should be noted that, the continuous part 82 of adjacent two metal structures 76 of the present invention corresponds on the barrier rib 80 of its below, to avoid influencing the display brightness of plasma scope 70, and the width of continuous part 82 makes region of discharge to extend via protruding in barrier rib 80 outer metal electrode 74a and 74b greater than the width of barrier rib 80.

Though in the above embodiment of the present invention, with the metal structure 56 and 76 of hexagon and hollow as an illustration, but application of the present invention is not limited to this, any polygon metal structure with hollow polygonal shape, and can keep certain discharging gap 55 and 75, and the coupling part of each polygon metal structure corresponds to the barrier rib top of the metacoxal plate of its below, shown in Fig. 7 to 11, three side ring shape metal electrodes to 92, four side ring shape metal electrodes to 94, five side ring shape metal electrodes are to 96, eight side ring shape metal electrodes to 98 or the semi-round ring shape metal electrode all can be applicable in the plasma scope of the present invention 100 etc.In addition, metal electrode of the present invention is to also being made of the two mutually parallel but metal electrodes hollow polygonal shape that tool is different.

In sum, plasma scope of the present invention mainly is to omit transparency electrode, and the metal electrode that will be in series by the metal structure of a plurality of polygons and hollow is to directly being made in the surface of prebasal plate, owing to electrode pair of the present invention has polygon and is hollow, therefore can reduce the region area of metal electrode, with the raising display brightness, and can reduce discharging current, improve discharging efficiency.And by the thrust of being located at each polygon metal electrode outside, more can be so that region of discharge extend to the electrode zone in the outside by the existence of thrust, and can not influence display brightness and aperture opening ratio, more can reach the purpose of power saving and low operating voltage.

Compare with the electrode pair structure of existing plasma scope, electrode pair structure of the present invention is mutually parallel and replaced the metal electrode of existing rectangular structure or fence structure by the metal electrode that the polygon of a plurality of hollows is in series by two, and omission transparency electrode, therefore not only can reduce process complexity, reduce the technology cost, and can not influence the display brightness and the contrast of plasma scope, with effective raising product fine rate.

The above only is the preferred embodiments of the present invention, and all equalizations of doing according to claims of the present invention change and modify, and all should belong to the covering scope of patent of the present invention.

Claims

1. the electrode pair structure of a plasma scope, this electrode pair structure is arranged at a prebasal plate surface of this plasma display, and this electrode pair structure comprises:

One first metal electrode is arranged at this prebasal plate surface, and this first metal electrode is in series by the metal structure of a plurality of hexagons and hollow; And

One second metal electrode and this first metal electrode are arranged at this prebasal plate surface abreast, and this second metal electrode is in series by the metal structure of a plurality of hexagons and hollow,

Wherein the identical and size of the structure of this first metal electrode and this second metal electrode equates; And

The continuous part of wantonly two adjacent these metal structures is corresponding to be located on the barrier rib of its below and not to exceed the crossover region of described metal electrode and this barrier rib, and described barrier rib is located at the surface of the parallel metacoxal plate that is oppositely arranged with this prebasal plate.

2. electrode pair structure as claimed in claim 1, wherein said barrier rib is parallel each other, and the orientation of this barrier rib is vertical with the long axis direction of this first metal electrode.

3. electrode pair structure as claimed in claim 1, wherein this prebasal plate and this metacoxal plate are a transparent glass substrate.

4. electrode pair structure as claimed in claim 1, the width of the part that wherein should link to each other is greater than the width of this barrier rib.

5. electrode pair structure as claimed in claim 1 does not wherein include a transparency electrode between this first metal electrode and this prebasal plate, and does not also include this transparency electrode between this second metal electrode and this prebasal plate.

6. electrode pair structure as claimed in claim 1, wherein this first metal electrode and this second metal electrode include chromium/copper/chromium or silver.

7. electrode pair structure as claimed in claim 1, wherein the beeline of this first metal electrode and this second metal electrode is the discharging gap of this electrode pair structure.

8. electrode pair structure as claimed in claim 7, wherein respectively this metal structure includes a thrust in addition and is arranged on the one side with respect to this discharging gap outside of this metal structure respectively, in order to extend machining area.

9. electrode pair structure as claimed in claim 7, wherein the discharging gap of respectively this metal structure of respectively this metal structure of this first metal electrode and corresponding this second metal electrode about equally.

10. the electrode pair structure of a plasma scope, this electrode pair structure is arranged at a prebasal plate surface of this plasma display, and this electrode pair structure comprises:

One first metal electrode is arranged at this prebasal plate surface, and this first metal electrode is in series by a plurality of first polygon endless metal structure; And

One second metal electrode and this first metal electrode are arranged at this prebasal plate surface abreast, and this second metal electrode is in series by a plurality of second polygon endless metal structure,

Wherein respectively the discharging gap of this first polygon endless metal structure and corresponding respectively this second polygon endless metal structure is about equally; And

11. electrode pair structure as claimed in claim 10, wherein said barrier rib is parallel each other, and the orientation of this barrier rib is vertical with the long axis direction of this first metal electrode.

12. electrode pair structure as claimed in claim 10, wherein this prebasal plate and this metacoxal plate are a transparent glass substrate.

13. electrode pair structure as claimed in claim 10, the width of the part that wherein should link to each other is greater than the width of this barrier rib.

14. electrode pair structure as claimed in claim 10 does not wherein comprise a transparency electrode between this first metal electrode and this prebasal plate, and does not also comprise this transparency electrode between this second metal electrode and this prebasal plate.

15. electrode pair structure as claimed in claim 10, wherein this first metal electrode and this second metal electrode comprise chromium/copper/chromium or silver.

16. electrode pair structure as claimed in claim 10, wherein the beeline of this first metal electrode and this second metal electrode is the discharging gap of this electrode pair structure.

17. electrode pair structure as claimed in claim 16, wherein respectively this metal structure comprises that in addition a thrust is arranged at respectively this metal structure with respect on this discharging gap outside, in order to extend machining area.

18. electrode pair structure as claimed in claim 10, wherein this first polygon endless metal structure and this second polygon endless metal structure all comprise one or three side ring shape metal structures, one or four side ring shape metal structures, First Five-Year Plan side ring shape metal structure, a hexagon endless metal structure, one or eight side ring shape metal structures or half circular ring metal structure.

19. a plasma scope, this plasma display comprises:

One metacoxal plate;

A plurality of parallel each other barrier ribs are arranged at this metacoxal plate surface along a first direction;

One prebasal plate, parallel relatively being arranged on this metacoxal plate;

At least one electrode pair structure be arranged at this prebasal plate surface of this metacoxal plate relatively along the second direction perpendicular to this first direction, and this electrode pair structure comprises:

One first metal electrode is arranged at this prebasal plate surface, this first metal electrode is in series by a plurality of first polygon endless metal structure, and the continuous part of wantonly two adjacent these first polygon endless metal structures is corresponding to be located on this barrier rib of its below and not to exceed the crossover region of described metal electrode and this barrier rib, and width partly width greater than this barrier rib that should link to each other; And

One second metal electrode and this first metal electrode are arranged at this prebasal plate surface abreast, this second metal electrode is in series by a plurality of second polygon endless metal structure, and the continuous part of wantonly two adjacent these second polygon endless metal structures is corresponding to be located on this barrier rib of its below and not to exceed the crossover region of described metal electrode and this barrier rib, and width partly width greater than this barrier rib that should link to each other;

Wherein respectively the discharging gap of this first polygon endless metal structure and corresponding respectively this second polygon endless metal structure is about equally.

20. plasma scope as claimed in claim 19, wherein this prebasal plate and this metacoxal plate are a transparent glass substrate.

21. plasma scope as claimed in claim 19, wherein this first metal electrode and this second metal electrode are all an opaque electrode.

22. plasma scope as claimed in claim 19, wherein this first metal electrode and this second metal electrode comprise chromium/copper/chromium or silver.

23. plasma scope as claimed in claim 19, wherein this first polygon endless metal structure and this second polygon endless metal structure all comprise one or three side ring shape metal structures, one or four side ring shape metal structures, First Five-Year Plan side ring shape metal structure, a hexagon endless metal structure, one or eight side ring shape metal structures or half circular ring metal structure.

24. plasma scope as claimed in claim 19, wherein respectively this first polygon endless metal structure and this second polygon endless metal structure respectively comprise that all in addition a thrust is arranged at respectively this polygon endless metal structure with respect on this discharging gap outside, in order to the extension machining area.