JP2017073570A - Electro-optic device and electronic equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress an influence of static electricity on power supply wirings VSS, VDD in addition to a signal wiring SL.SOLUTION: A first static electricity protection circuit 301 includes a first n-type transistor and a first p-type transistor, and a second static electricity protection circuit 302 includes at least one of a second n-type transistor and a second p-type transistor. In these transistors, the source is connected to the gate, the gate of the first n-type transistor is electrically connected to a low-potential power supply wiring VSS, the drain of the first n-type transistor is electrically connected to the signal wiring SL, the gate of the first p-type transistor is electrically connected to a high-potential power supply wiring VDD, the drain of the first p-type transistor is electrically connected to a signal wiring SL, and the drain of at least one of the second n-type transistor and the second p-type transistor is electrically connected to the low-potential power supply wiring VSS or the high-potential power supply wiring VDD.SELECTED DRAWING: Figure 5

Description

  The present invention relates to an electrostatic protection circuit, an electro-optical device equipped with the electrostatic protection circuit, and an electronic apparatus.

  An active drive type liquid crystal device as an electro-optical device includes a pixel that modulates light, a semiconductor circuit (such as a scan line drive circuit and a data line drive circuit) that drives the pixel, and the like. In the liquid crystal device, there is a risk that transistors constituting pixels, semiconductor circuits, and the like may be damaged by static electricity that cannot be recovered, and it is important to take measures against static electricity to suppress the influence of static electricity. For example, Patent Document 1 proposes a liquid crystal device provided with an electrostatic protection circuit (electrostatic protection circuit).

  FIG. 16 is a circuit diagram of the electrostatic protection circuit described in Patent Document 1. As shown in FIG. 16, the electrostatic protection circuit 500 described in Patent Document 1 includes a p-type transistor 504 and an n-type transistor 505. The source and gate of the p-type transistor 504 are connected to the high potential wiring 502 and supplied with the potential VH. The source and gate of the n-type transistor 505 are connected to the low potential wiring 503, and a potential VL having a potential lower than the potential VH is supplied. The drain of the p-type transistor 504 and the drain of the n-type transistor 505 are connected to the signal wiring 501.

  When the potential of the signal wiring 501 is in the range of VL to VH, the p-type transistor 504 and the n-type transistor 505 are in an off state, and the signal wiring 501, the high-potential wiring 502, and the low-potential wiring 503 interfere electrically. The liquid crystal device operates normally. When the potential of the signal wiring 501 deviates from the range of VL to VH due to static electricity, one of the p-type transistor 504 and the n-type transistor 505 is turned on (conductive state). For example, when the potential of the signal wiring 501 becomes higher than VH due to static electricity, the p-type transistor 504 is turned on. When the potential of the signal wiring 501 becomes lower than VL due to static electricity, the n-type transistor 505 is turned on. In this manner, when the potential of the signal wiring 501 changes due to static electricity, either the high potential wiring 502 or the low potential wiring 503 is connected to the signal wiring 501. Then, the charge added to the signal wiring 501 due to static electricity is distributed (discharged) to either the high potential wiring 502 or the low potential wiring 503 in a conductive state, and the change in potential of the signal wiring 501 due to static electricity is reduced. . Since the change in the potential of the signal wiring 501 due to static electricity is reduced, irrecoverable electrostatic damage (for example, electrostatic breakdown) is less likely to occur in the semiconductor circuit connected to the signal wiring 501.

JP 2006-18165 A

As described above, the liquid crystal device described in Patent Document 1 includes the electrostatic protection circuit 500 that discharges the charge added to the signal wiring 501 due to static electricity to either the high potential wiring 502 or the low potential wiring 503. Yes.
However, in the static electricity protection circuit 500, when a charge due to static electricity is added to either the high potential wiring 502 or the low potential wiring 503, it is difficult to discharge the charge. Therefore, when a charge due to static electricity is added to the high potential wiring 502, the potential of the high potential wiring 502 fluctuates and is restored to a transistor (eg, a p-type transistor 504) electrically connected to the high potential wiring 502. Impossible electrostatic damage may occur. When a charge due to static electricity is added to the low-potential wiring 503, the potential of the low-potential wiring 503 fluctuates, and a transistor (eg, an n-type transistor 505) that is electrically connected to the low-potential wiring 503 cannot recover. There is a risk of electrical damage.
As described above, the liquid crystal device described in Patent Document 1 has a problem that it is difficult to suppress the influence of static electricity on the high potential wiring 502 or the low potential wiring 503.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following forms or application examples.

  Application Example 1 An electrostatic protection circuit according to this application example is an electrostatic protection circuit electrically connected to a first power supply wiring, a second power supply wiring, and a signal wiring, and the electrostatic protection circuit includes: A first electrostatic protection circuit and a second electrostatic protection circuit, wherein the first electrostatic protection circuit includes a first n-type transistor and a first p-type transistor, and the second electrostatic protection circuit. Comprises at least one of a second n-type transistor and a second p-type transistor, the first n-type transistor, the first p-type transistor, the second n-type transistor and the second p-type transistor. Each of at least one of the p-type transistors has one of a source and a drain connected to a gate, and the gate of the first n-type transistor is electrically connected to the first power supply wiring. The other of the source and drain of the first n-type transistor is electrically connected to the signal wiring, and the gate of the first p-type transistor is electrically connected to the second power supply wiring. And the other of the source and drain of the first p-type transistor is electrically connected to the signal line, and in at least one of the second n-type transistor and the second p-type transistor The other of the source and the drain is electrically connected to the first power supply wiring or the second power supply wiring.

  The first electrostatic protection circuit includes a first n-type transistor and a first p-type transistor. When a positive charge is added to the signal wiring due to static electricity, the gate of the first n-type transistor has a negative potential with respect to the other of the source and the drain, and the first n-type transistor is in a non-conductive state. Thus, the gate of the first p-type transistor has a negative potential with respect to the other of the source and the drain, and the first p-type transistor becomes conductive. For this reason, the positive charge added to the signal wiring due to static electricity is discharged to the second power supply wiring through the first p-type transistor that has become conductive. When a negative charge is added to the signal wiring due to static electricity, the gate of the first n-type transistor has a positive potential with respect to the other of the source and the drain, and the first n-type transistor becomes conductive. The gate of the first p-type transistor has a positive potential with respect to the other of the source and the drain, and the first p-type transistor is turned off. For this reason, the negative charge added to the signal wiring due to static electricity is discharged to the first power supply wiring through the first n-type transistor that has become conductive. That is, the first static electricity protection circuit has a function of discharging the charge added by static electricity to either the first power supply wiring or the second power supply wiring and suppressing the influence of the charge.

  The second electrostatic protection circuit includes at least one of a second n-type transistor and a second p-type transistor, and the other of the source and the drain is electrically connected to the first power supply wiring or the second power supply wiring. It is connected. Static electricity applied to the first power supply wiring or the second power supply wiring by static electricity passes through the other of the source and drain electrically connected to the first power supply wiring or the second power supply wiring, It is discharged to the side of the wiring to which one of the source and drain is connected. That is, the second static electricity protection circuit discharges the charge added to the first power supply wiring or the second power supply wiring due to static electricity, and suppresses the influence of static electricity on the first power supply wiring or the second power supply wiring. Have a role.

  As described above, the electrostatic protection circuit according to this application example includes an electrostatic protection circuit (first electrostatic protection circuit) that suppresses the influence of static electricity on the signal wiring, and static electricity on the first power supply wiring or the second power supply wiring. And an electrostatic protection circuit (second electrostatic protection circuit) for suppressing the influence. Note that the high-potential wiring or the low-potential wiring in the known technique (Japanese Patent Laid-Open No. 2006-18165) corresponds to the first power supply wiring or the second power supply wiring in this application example. Therefore, the problem of the known technique that it is difficult to suppress the influence of static electricity on the high potential wiring or the low potential wiring (first power supply wiring or second power supply wiring) is overcome, and in addition to the signal wiring, the first Static electricity that suppresses the influence of static electricity on the power supply wiring and the second power supply wiring and cannot be recovered by an element (for example, a transistor) electrically connected to the signal wiring, the first power supply wiring, and the second power supply wiring. Electric damage is less likely to occur.

  Application Example 2 In the electrostatic protection circuit according to the application example, the second electrostatic protection circuit includes the second n-type transistor and the second p-type transistor, and the second n-type transistor. The other of the gate of the transistor and the source and drain of the second p-type transistor is electrically connected to the first power supply wiring, the gate of the second p-type transistor, and the second p-type transistor. The other of the source and the drain of the n-type transistor is preferably electrically connected to the second power supply wiring.

  The second electrostatic protection circuit includes a second n-type transistor and a second p-type transistor. When a positive charge is added to the first power supply wiring due to static electricity, the gate of the second n-type transistor has a positive potential with respect to the other of the source and the drain, and the second n-type transistor The second p-type transistor has a negative potential with respect to the other of the source and the drain, and the second p-type transistor is also conductive. Therefore, the positive charge added to the first power supply wiring due to static electricity can be discharged to the second power supply wiring through the second n-type transistor and the second p-type transistor that are turned on. it can.

  When a negative charge is added to the second power supply wiring due to static electricity, the gate of the second n-type transistor has a positive potential with respect to the other of the source and the drain, and the second n-type transistor The second p-type transistor has a negative potential with respect to the other of the source and the drain, and the second p-type transistor is also conductive. Therefore, the negative charge added to the second power supply wiring due to static electricity can be discharged to the first power supply wiring through the second n-type transistor and the second p-type transistor that are turned on. it can.

  Application Example 3 In the electrostatic protection circuit according to the application example, it is preferable that the second electrostatic protection circuit has a higher resistance than the first electrostatic protection circuit.

  The signal wiring is a wiring for supplying a signal for driving the electro-optical device. The first power supply wiring and the second power supply wiring are wirings for supplying power to components (for example, drivers) of the electro-optical device, and a larger current flows than the signal wirings. For this reason, the first power supply wiring and the second power supply wiring need to have a larger wiring capacity than the signal wiring and easily allow a larger current to flow than the signal wiring. For this reason, the area of the first power supply wiring and the second power supply wiring is larger than the area of the signal wiring.

  If a static electricity generation source exists, the first power supply wiring and the second power supply wiring having a large area are more easily charged than the signal wiring having a small area (susceptible to the influence of static electricity). Furthermore, compared with the signal wiring having a small area, the first power supply wiring and the second power supply wiring having a large area have a larger charge amount (charge accumulation amount) due to static electricity. For this reason, compared with the signal wiring, the first power supply wiring and the second power supply wiring increase the amount of charge added by static electricity, so that the charge added by the static electricity is transferred by the second electrostatic protection circuit. In the case of discharging, a large current (excessive current) flows through the second electrostatic protection circuit, and there is a possibility that the transistor constituting the second electrostatic protection circuit is broken. Since the second static electricity protection circuit has a higher resistance than the first static electricity protection circuit, the excessive current is suppressed, and the second static electricity protection circuit is hardly broken. Therefore, the second static electricity protection circuit can be stably operated for a long time.

  Application Example 4 In the electrostatic protection circuit according to the application example described above, the first n-type transistor and the second n-type transistor have substantially the same channel width, and the first p-type transistor and the second n-type transistor have the same channel width. The second p-type transistor has substantially the same channel width, and the channel length of the second n-type transistor includes 120% of the channel length of the first n-type transistor, or is more than 120% Preferably, the channel length of the second p-type transistor includes 120% or more than 120% of the channel length of the first p-type transistor.

The first n-type transistor and the second n-type transistor have substantially the same channel width, and the channel length of the second n-type transistor includes 120% of the channel length of the first n-type transistor, or This is larger than 120% of the channel length of one n-type transistor. Therefore, the second n-type transistor has a higher resistance than the first n-type transistor. Similarly, the first p-type transistor and the second p-type transistor have substantially the same channel width, and the channel length of the second p-type transistor includes 120% of the channel length of the first p-type transistor. Or greater than 120% of the channel length of the first p-type transistor. Therefore, the second p-type transistor has a higher resistance than the first p-type transistor.
Therefore, the second electrostatic protection circuit configured by the second n-type transistor and the second p-type transistor is the first electrostatic protection circuit configured by the first n-type transistor and the first p-type transistor. Higher resistance.

  Application Example 5 An electro-optical device according to this application example includes the electrostatic protection circuit described in the application example.

  Since the electro-optical device according to the application example includes the electrostatic protection circuit described in the application example, the influence of static electricity is suppressed, and resistance to static electricity, that is, reliability of the electro-optical device can be increased.

  Application Example 6 An electronic apparatus according to this application example includes the electrostatic protection circuit described in the application example and / or the electro-optical device described in the application example.

  The electronic apparatus according to this application example includes the electrostatic protection circuit described in the application example and / or the electro-optical device including the electrostatic protection circuit described in the application example. It is possible to increase the resistance to the resistance, that is, the reliability of the electronic device.

FIG. 2 is a schematic plan view showing the structure of the liquid crystal device according to the first embodiment. FIG. 2 is a schematic cross-sectional view taken along line H-H ′ in FIG. 1. FIG. 2 is a circuit diagram illustrating a main circuit configuration of the liquid crystal device according to the first embodiment. FIG. 3 is a schematic cross-sectional view showing the positional relationship between each component constituting a pixel. The circuit diagram of an electrostatic protection circuit. The schematic plan view which shows arrangement | positioning of each structure of an electrostatic protection circuit. FIG. 7 is a schematic cross-sectional view showing the structure of the first electrostatic protection circuit taken along line A-A ′ of FIG. 6. (A) The schematic sectional drawing which shows the structure of the 2nd electrostatic protection circuit along the B-B 'line of FIG. (B) is a schematic sectional drawing which shows the structure of the 2nd electrostatic protection circuit along the C-C 'line of FIG. FIG. 6A is a circuit diagram showing a flow of negative charges NC added to a low potential power wiring VSS. FIG. 6B is a circuit diagram showing a flow of negative charges NC added to the high potential power wiring VDD. (A) is a circuit diagram showing the flow of positive charge PC added to the low potential power supply wiring VSS. FIG. 5B is a circuit diagram showing a flow of positive charges PC added to the high potential power supply wiring VDD. (A) is a circuit diagram showing a flow of negative charge NC added to signal wiring SL. FIG. 4B is a circuit diagram showing a flow of positive charges PC added to the signal wiring SL. Schematic which shows the structure of the projection type display apparatus which concerns on Embodiment 2. FIG. FIG. 7 is a schematic cross-sectional view showing the structure of a first electrostatic protection circuit according to Modification Example 1. (A) is a schematic sectional drawing which shows the structure of the 2nd p-type transistor which concerns on the modification 1. FIG. FIG. 6B is a schematic cross-sectional view of a second n-type transistor according to Modification 1. (A) is a circuit diagram which shows the structure of the electrostatic protection circuit which concerns on the modification 2. FIG. FIG. 6B is a circuit diagram showing a configuration of another electrostatic protection circuit according to Modification 2. The circuit diagram of the electrostatic protection circuit which concerns on a well-known technique.

  Embodiments of the present invention will be described below with reference to the drawings. Such an embodiment shows one aspect of the present invention and does not limit the present invention, and can be arbitrarily changed within the scope of the technical idea of the present invention. In each of the following drawings, the scale of each layer or each part is made different from the actual scale so that each layer or each part can be recognized on the drawing.

(Embodiment 1)
"Outline of LCD device"
The liquid crystal device 100 according to the first embodiment is an example of an electro-optical device, and is a transmissive liquid crystal device including a thin film transistor (hereinafter referred to as TFT) 30.
The liquid crystal device 100 according to the present embodiment can be suitably used as, for example, a light modulation element (light valve) of a projection display device (liquid crystal projector) described later.

  First, an overall configuration of a liquid crystal device 100 as an electro-optical device according to the present embodiment will be described with reference to FIGS. 1 to 3. FIG. 1 is a schematic plan view showing the configuration of the liquid crystal device. FIG. 2 is a schematic cross-sectional view taken along the line H-H ′ of FIG. 1. 3A is a circuit diagram of the liquid crystal device, and FIG. 3B is an equivalent circuit of the pixel.

  As shown in FIGS. 1 and 2, the liquid crystal device 100 according to the present embodiment includes an element substrate 10 and a counter substrate 20 that are arranged to face each other, a liquid crystal layer 50 that is sandwiched between the pair of substrates, and the like.

  The element substrate 10 is larger than the counter substrate 20, and both the substrates are bonded via a seal material 52 arranged in a frame shape, and a liquid crystal having positive or negative dielectric anisotropy is sealed in the gap to form a liquid crystal layer 50. The sealing material 52 is, for example, an adhesive such as a thermosetting or ultraviolet curable epoxy resin, and a spacer (not shown) for keeping the distance between the pair of substrates constant is mixed therein.

  A light shielding film 53 is similarly provided in a frame shape inside the sealing material 52 arranged in a frame shape. The light shielding film 53 is made of, for example, a light shielding metal or metal compound, and the inside of the light shielding film 53 is the display region E. In the display area E, a plurality of pixels P are arranged in a matrix.

A data line driving circuit 101 is provided between the first side on which the plurality of external circuit connection terminals 102 of the element substrate 10 are arranged and the sealing material 52 along the first side. A sampling circuit 7 is provided between the sealing material 52 and the display area E along the first side. A scanning line driving circuit 104 is provided between the other second side and the third side which are orthogonal to the first side and facing each other, and the display region E. Between the seal material 52 and the display area E along the other fourth side facing the first side, a wiring 105 that connects the two scanning line driving circuits 104 is provided. Furthermore, a lead wiring 90 for electrically connecting the data line driving circuit 101, the sampling circuit 7, and the scanning line driving circuit 104 to the external circuit connection terminal 102 is provided.
The data line driving circuit 101 includes a precharge circuit.

  As shown in FIG. 2, the element substrate 10 includes a substrate body 10a, a TFT 30 formed on the surface of the substrate body 10a on the liquid crystal layer 50 side, the pixel electrode 9a, an alignment film 18 that covers the pixel electrode 9a, and the like. ing. The substrate body 10a is made of a transparent material such as quartz or glass. The TFT 30 and the pixel electrode 9a are constituent elements of the pixel P. Details of the pixel P will be described later.

  Further, although not shown here, in addition to the data line driving circuit 101, the sampling circuit 7, and the scanning line driving circuit 104, an electrostatic protection circuit 300 (see FIG. 3) described later is provided on the element substrate 10. . In addition to this, a semiconductor circuit such as an inspection circuit for inspecting the quality, defects and the like of the liquid crystal device 100 during manufacture or at the time of shipment may be provided.

  The counter substrate 20 includes a counter substrate body 20a, a light shielding film 53, an insulating film 22, a counter electrode 23, an alignment film 24, and the like, which are sequentially stacked on the surface of the counter substrate body 20a on the liquid crystal layer 50 side. The counter substrate body 20a is made of a transparent material such as quartz or glass.

  As shown in FIG. 1, the light shielding film 53 overlaps with the sampling circuit 7 and the scanning line driving circuit 104 in a plan view, shields light incident from the counter substrate 20 side, and prevents malfunction due to the light of these circuits. have. Further, unnecessary stray light is shielded from entering the display area E, and high contrast in the display of the display area E is ensured.

  The insulating film 22 is made of, for example, an inorganic material such as silicon oxide, and is provided so as to cover the light shielding film 53 with light transmittance. Further, the insulating film 22 also functions as a planarizing layer that relaxes unevenness generated on the substrate by the light shielding film 53.

  The counter electrode 23 is made of a transparent conductive film such as ITO, for example, covers the insulating film 22 and is formed over the display region E. As shown in FIG. 1, the counter electrode 23 is electrically connected to the wiring on the element substrate 10 side by vertical conduction portions 106 provided at the four corners of the counter substrate 20.

  The alignment film 18 that covers the pixel electrode 9a and the alignment film 24 that covers the counter electrode 23 are set based on the optical design of the liquid crystal device 100, and in this embodiment, an obliquely deposited film of an inorganic material such as silicon oxide ( Inorganic alignment film). The alignment films 18 and 24 may be organic alignment films such as polyimide.

  As shown in FIG. 3A, the scanning line driving circuit 104 is connected to the potential of the low potential power supply VSSY and the high potential power supply VDDY from the external circuit via the external circuit connection terminal 102 and the scanning line driving circuit power supply wiring 94. Is supplied. The potential of the low-potential power supply VSSY is the lowest among the ground potential (reference potential), that is, the potential supplied to the scanning line driving circuit 104. The potential of the high potential power supply VDDY is higher than the potential of the low potential power supply VSSY and is the highest potential among the potentials supplied to the scan line driver circuit 104. Further, the Y clock signal CLY, the inverted Y clock signal CLYB, and the Y start pulse signal DY are supplied to the scanning line driving circuit 104 from the external circuit through the external circuit connection terminal 102 and the scanning line driving circuit signal wiring 95. The The scanning line driving circuit 104 sequentially generates scanning signals G1 to Gm based on these signals and outputs them to the scanning line 11a.

  The data line driving circuit 101 is supplied with the potential of the low potential power supply VSSX and the potential of the high potential power supply VDDX from the external circuit via the external circuit connection terminal 102 and the data line driving circuit power supply wiring 91. The potential of the low potential power supply VSSX is the lowest among the ground potential (reference potential), that is, the potential supplied to the data line driving circuit 101. The potential of the high potential power supply VDDX is higher than the potential of the low potential power supply VSSX and is the highest potential among the potentials supplied to the data line driving circuit 101. Further, the data line driving circuit 101 receives an X clock signal CLX, an inverted X clock signal CLXB, an X start pulse signal DX, a data enable signal from an external circuit via the external circuit connection terminal 102 and the data line driving circuit signal wiring 92. ENBX1, ENBX2, ENBX3, ENBX4, and precharge signal NRG are supplied. When the X start pulse signal DX is input, the data line driving circuit 101 sequentially generates and outputs sampling signals S1 to Sn at a timing based on the X clock signal CLX (and the inverted X clock signal CLXB).

  The common electrode LCCOM is supplied to the counter electrode 23 from the external circuit through the external circuit connection terminal 102 and the common electrode wiring 97. Further, the common potential LCCOM is supplied to one electrode (lower electrode 71) forming the additional capacitor 70 via the common electrode wiring 97 and the capacitor line 60 (see FIG. 3B).

  The sampling circuit 7 includes a sampling transistor 7s that samples the video signals VID1 to VID6 and supplies them to the data line 6a. The data line 6a is connected to the video signal line 96 through the sampling transistor 7s. The sampling circuit 7 is supplied with the potentials of the video signals VID <b> 1 to VID <b> 6 via the external circuit connection terminal 102 and the video signal line 96. Further, the sampling signal S1 to Sn is supplied from the data line driving circuit 101 to the sampling circuit 7 for each sampling transistor 7s. When the sampling signals S1 to Sn are input, the sampling circuit 7 sequentially supplies the video signals VS1 to VSn according to the sampling signals S1 to Sn to the data line 6a corresponding to the sampling transistor 7s.

  As shown in FIG. 3A and FIG. 3B, the display region E has a plurality of scanning lines 11a and a plurality of data lines 6a as signal lines insulated and orthogonal to each other, and the scanning lines 11a. A capacitor line 60 extending in parallel is provided. A pixel electrode 9a, a TFT 30, and an additional capacitor 70 are provided in a region divided by the scanning line 11a and the data line 6a, and these constitute a pixel circuit of the pixel P.

  The data line 6a to which the video signals VS1 to VSn are supplied is electrically connected to the source electrode of the TFT 30. The video signals VS1 to VSn to be written to the data line 6a may be supplied line-sequentially in this order, or may be supplied for each group to a plurality of adjacent data lines 6a. In the present embodiment, the video signals VS1 to VSn are supplied for each group of groups of six data lines 6a corresponding to the video signals VID1 to VID6 that are serial-parallel-developed in six phases. . The number of phase expansion of video signals (that is, the number of video signal sequences that are serial-parallel expanded) is not limited to 6 phases, but is expanded to multiple phases such as 9 phases, 12 phases, and 24 phases, for example. You may comprise so that a video signal may be supplied with respect to the group of the data line 6a which made the number corresponding to the number of phase expansion a set.

  The scanning line 11a to which the scanning signal is supplied is connected to the gate electrode 3a (see FIG. 4) of the TFT 30. The scanning signals G1 to Gm are supplied to the scanning line 11a and the gate electrode 3a in this order in line order. The pixel electrode 9 a is electrically connected to the drain electrode of the TFT 30.

  In the liquid crystal device 100, the TFT 30 as a switching element is turned on for a certain period by the input of the scanning signals G1 to Gm, so that the video signals VS1 to VSn supplied from the data line 6a are turned on at a predetermined timing. Thus, the pixel electrode 9a is written. The video signals VS1 to VSn of a predetermined level written in the liquid crystal layer 50 through the pixel electrode 9a are held for a certain period between the pixel electrode 9a and the counter electrode 23 arranged to face each other through the liquid crystal layer 50. The

  In order to prevent the retained video signals VS1 to VSn from leaking, an additional capacitor 70 is added in parallel with the liquid crystal capacitor formed between the pixel electrode 9a and the counter electrode 23. The additional capacitor 70 is provided between the drain of the TFT 30 and the capacitor line 60. The additional capacitor 70 has an upper electrode 73 connected to the pixel electrode 9 a and a lower electrode 71 connected to the capacitor line 60. As described above, the common potential LCCOM is supplied to the lower electrode 71 via the common electrode wiring 97 and the capacitor line 60.

  Such a liquid crystal device 100 is a transmission type, and the transmittance of the pixel P when the voltage is not applied is larger than the transmittance when the voltage is applied, and a normally white mode where a bright display is obtained, or when no voltage is applied. The normally black mode optical design is adopted in which the transmittance of the pixel P is smaller than the transmittance at the time of voltage application and dark display is achieved. Depending on the optical design, polarizing elements (not shown) are respectively used on the light incident side and the light emitting side.

"Outline of wiring and placement of electrostatic protection circuit"
Next, an outline of wiring provided in the liquid crystal device 100 and an arrangement position of the electrostatic protection circuit 300 that characterizes the present invention will be described with reference to FIG.

As described above, the liquid crystal device 100 includes the data line driving circuit power supply wiring 91 for supplying power to the data line driving circuit 101 and the data line driving circuit for supplying driving signals to the data line driving circuit 101. A signal wiring 92 for scanning, a power wiring 94 for scanning line driving circuit for supplying power to the scanning line driving circuit 104, a signal wiring 95 for scanning line driving circuit for supplying a driving signal to the scanning line driving circuit 104, A video signal line 96 for supplying video signals VID1 to VID6 to the sampling circuit 7, a common electrode wiring 97 for supplying a common potential LCCOM to the common electrode (counter electrode 23, lower electrode 71), and the like are provided. .
Further, the liquid crystal device 100 includes an electrostatic protection circuit 300 that characterizes the present invention.

  One data line drive circuit power supply wiring 91 is supplied with the potential of the low potential power supply VSSX, and the other data line drive circuit power supply wiring 91 is supplied with the potential of the high potential power supply VDDX (high potential). Yes. Further, one scanning line driving circuit power supply wiring 94 is supplied with the potential of the low potential power supply VSSY, and the other scanning line driving circuit power supply wiring 94 is supplied with the potential of the high potential power supply VDDY.

  The data line driving circuit power supply wiring 91 to which the potential of the low potential power supply VSSX is supplied and the scanning line driving circuit power supply wiring 94 to which the potential of the low potential power supply VSSY is supplied are the “first power supply” in the present invention. This is an example of “wiring” and is hereinafter referred to as a low potential power wiring VSS.

  The data line driving circuit power supply wiring 91 supplied with the potential of the high potential power supply VDDX and the scanning line driving circuit power supply wiring 94 supplied with the potential of the high potential power supply VDDY are the “second power supply” in the present invention. This is an example of “wiring” and is hereinafter referred to as high potential power wiring VDD.

  The scanning line driving circuit signal wiring 95 is supplied with a Y clock signal CLY, an inverted Y clock signal CLYB, a Y start pulse signal DY, and the like. The data line driving circuit signal wiring 92 is supplied with an X clock signal CLX, an inverted X clock signal CLXB, an X start pulse signal DX, data enable signals ENBX1, ENBX2, ENBX3, ENBX4, and a precharge signal NRG. Video signals VID <b> 1 to VID <b> 6 are supplied to the video signal line 96. A common potential LCCOM is supplied to the common electrode wiring 97.

These Y clock signal CLY, inverted Y clock signal CLYB, Y start pulse signal DY, X clock signal CLX, inverted X clock signal CLXB, X start pulse signal DX, data enable signals ENBX1, ENBX2, ENBX3, ENBX4, precharge signal NRG The video signals VID1 to VID6 and the common potential LCCOM are between the potential of the low potential power supply line VSS and the potential of the high potential power supply line VDD.
That is, the potentials of the data line driving circuit signal wiring 92, the scanning line driving circuit signal wiring 95, the video signal line 96, and the common electrode wiring 97 are between the potential of the low potential power wiring VSS and the high potential power wiring VDD. It is in.
The data line driving circuit signal wiring 92, the scanning line driving circuit signal wiring 95, the video signal line 96, and the common electrode wiring 97 are examples of the “signal wiring” in the present invention. Call it.

  As shown in FIG. 3, the electrostatic protection circuit 300 is disposed between the external circuit connection terminal 102 and the semiconductor circuit (data line driving circuit 101, sampling circuit 7, scanning line driving circuit 104). The electrostatic protection circuit 300 is disposed in each of the low potential power supply wiring VSS, the high potential power supply wiring VDD, and the signal wiring SL.

  Although details will be described later, the electrostatic protection circuit 300 is electrically connected to the low potential power supply wiring VSS, the high potential power supply wiring VDD, and the signal wiring SL. For example, the electrostatic protection circuit 300 arranged in the low potential power supply wiring VSS in the drawing is also electrically connected to the high potential power supply wiring VDD and the signal wiring SL (not shown). In the drawing, the electrostatic protection circuit 300 arranged on the high potential power supply wiring VDD is also electrically connected to the low potential power supply wiring VSS and the signal wiring SL (not shown). In the figure, the electrostatic protection circuit 300 disposed in the signal wiring SL is also electrically connected to the low potential power wiring VSS and the high potential power wiring VDD (not shown).

`` Pixel configuration ''
FIG. 4 is a schematic cross-sectional view showing the positional relationship of each component constituting the pixel, and is represented on a scale that can be clearly shown. Next, a specific configuration of the pixel P will be described with reference to FIG.

  As shown in FIG. 4, the pixel P includes a first layer including the scanning lines 11a and the like, a second layer including the TFTs 30 and the like, a third layer including the data lines 6a and the like, which are sequentially stacked on the substrate body 10a. And a fifth layer (uppermost layer) including the pixel electrode 9a, the alignment film 18, and the like. The base insulating film 12 is between the first layer and the second layer, the first interlayer insulating film 41 is between the second layer and the third layer, and the third layer is between the third layer and the fourth layer. The second interlayer insulating film 42 is provided with a third interlayer insulating film 43 between the fourth layer and the fifth layer, respectively, and prevents the above-described elements from being short-circuited.

(Structure of the first layer-scanning line, etc.)
In the first layer, a scanning line 11a made of tungsten silicide is provided. As a material constituting the scanning line 11a, for example, titanium nitride or tungsten can be used in addition to tungsten silicide. The scanning line 11a has a light shielding property, blocks light that enters the TFT 30 from below, and suppresses malfunction of the TFT 30 due to light.

(Structure of the second layer-TFT etc.)
Next, the TFT 30 including the gate electrode 3a is provided as the second layer. The TFT 30 includes a gate electrode 3a made of conductive polycrystalline silicon and tungsten silicide, a semiconductor layer 1a made of polycrystalline silicon, and a gate insulating film 2 made of silicon oxide that insulates the gate electrode 3a from the semiconductor layer 1a. Has been. The semiconductor layer 1a includes a high concentration source region 1d, a channel region 1a ′, a high concentration drain region 1e, and a junction region (low concentration source region 1b) formed between the high concentration source region 1d and the channel region 1a ′. ) And a junction region (low-concentration drain region 1c) formed between the channel region 1a ′ and the high-concentration drain region 1e. The gate insulating film 2 is provided so as to cover the semiconductor layer 1 a and the base insulating film 12. The gate electrode 3a is disposed opposite to the channel region 1a ′ of the semiconductor layer 1a with the gate insulating film 2 interposed therebetween.

(Configuration between the first layer and the second layer—underlying insulating film, etc.)
A base insulating film 12 made of silicon oxide is provided between the scanning line 11a and the semiconductor layer 1a. The base insulating film 12 in a region not in contact with the semiconductor layer 1a is covered with the gate insulating film 2. A contact hole 12cv is provided in the base insulating film 12 and the gate insulating film 2 on the scanning line 11a. A gate electrode 3a is provided to fill the contact hole 12cv, and the gate electrode 3a and the scanning line 11a are connected to each other through the contact hole 12cv and have the same potential.

(3rd layer configuration-data lines, etc.)
In the third layer, a data line 6a (source electrode 6a1) and a relay electrode 5a (drain electrode 5a1) are provided. The data line 6a and the relay electrode 5a are made of a conductive material such as a metal and have a two-layer structure of a layer made of aluminum and a layer made of titanium nitride, for example. The data line 6a and the source electrode 6a1 are integrally formed, and the portion in contact with the high concentration source region 1d of the TFT 30 becomes the source electrode 6a1. The relay electrode 5a and the drain electrode 5a1 are integrally formed, and a portion in contact with the high concentration drain region 1e of the TFT 30 becomes the drain electrode 5a1.

(Configuration between the second layer and the third layer-first interlayer insulating film-)
A first interlayer insulating film 41 made of, for example, silicon oxide or silicon nitride is provided between the gate electrode 3a and the data line 6a. In the first interlayer insulating film 41, a contact hole 81 for electrically connecting the high concentration source region 1d of the TFT 30 and the source electrode 6a1, and a high concentration drain region 1e of the TFT 30 and the drain electrode 5a1 are electrically connected. A contact hole 83 for connection is provided.

(Fourth layer configuration-additional capacity, etc.)
An additional capacitor 70 is provided in the fourth layer. The additional capacitor 70 is connected to the pixel electrode 9 a and is connected to the upper electrode 73 as the pixel potential side capacitor electrode, the lower electrode 71 as the fixed potential side capacitor electrode, and the dielectric layer sandwiched between the upper electrode 73 and the lower electrode 71. 72 or the like. According to the additional capacitor 70, the potential holding characteristic of the pixel electrode 9a can be remarkably improved.

The upper electrode 73 is made of a conductive material such as metal, for example, and has a function of relay-connecting the pixel electrode 9a and the relay electrode 5a. The upper electrode 73 is connected to the pixel electrode 9 a through the contact hole 89, and is connected to the high concentration drain region 1 e of the TFT 30 through the contact hole 85, the relay electrode 5 a, and the contact hole 83.
The lower electrode 71 is made of a conductive material such as metal, and has a two-layer structure of a layer made of aluminum and a layer made of titanium nitride, for example. The main line portion of the lower electrode 71 extends in the arrangement direction of the scanning line 11 a and becomes the capacitance line 60. That is, the lower electrode 71 and the capacitor line 60 are at the same potential (fixed potential).

  As the dielectric layer 72, for example, a single layer film such as silicon nitride, silicon oxide, hafnium oxide, aluminum oxide, tantalum oxide or the like, or a multilayer film in which at least two kinds of single layer films among these single layer films are laminated. Can be used.

(Configuration between the third layer and the fourth layer—second interlayer insulating film)
Between the data line 6a and the relay electrode 5a and the additional capacitor 70, a second interlayer insulating film 42 made of, for example, silicon nitride or silicon oxide is provided. The second interlayer insulating film 42 is provided with a contact hole 85 for electrically connecting the relay electrode 5a and the upper electrode 73.

(Fifth layer and the configuration between the fourth layer and the fifth layer-pixel electrode, etc.)
A pixel electrode 9a is provided in the fifth layer. The pixel electrode 9a is formed in an island shape for each pixel P, and an alignment film 18 is provided on the pixel electrode 9a. A third interlayer insulating film 43 made of, for example, silicon nitride or silicon oxide is provided between the pixel electrode 9a and the additional capacitor 70. The third interlayer insulating film 43 is provided with a contact hole 89 for electrically connecting the pixel electrode 9 a and the upper electrode 73.

  Note that the above-described semiconductor circuit (the data line driving circuit 101, the sampling circuit 7, the scanning line driving circuit 104, and the like) and the electrostatic protection circuit 300 have the same wiring layer structure as the pixel P described above, and the same process as the pixel P. Is formed at the same time.

"Overview of ESD protection circuit"
FIG. 5 is a circuit diagram of the electrostatic protection circuit. The outline of the electrostatic protection circuit 300 according to the present embodiment will be described below with reference to FIG.

  As illustrated in FIG. 5, the electrostatic protection circuit 300 includes a first electrostatic protection circuit 301 and a second electrostatic protection circuit 302. Further, the first electrostatic protection circuit 301 includes a first p-type transistor 310-1 and a first n-type transistor 330-1. The second electrostatic protection circuit 302 includes a second p-type transistor 310-2 and a second n-type transistor 330-2.

  The first p-type transistor 310-1 and the first n-type transistor 330-1 included in the first electrostatic protection circuit 301 are electrically connected to the low potential power supply wiring VSS, the high potential power supply wiring VDD, and the signal wiring SL. It is connected. Specifically, the first p-type transistor 310-1 is electrically connected to the signal line SL and the high potential power line VDD. The first n-type transistor 330-1 is electrically connected to the low potential power supply wiring VSS and the signal wiring SL.

  The second p-type transistor 310-2 and the second n-type transistor 330-2 constituting the second electrostatic protection circuit 302 are electrically connected to the low potential power supply line VSS and the high potential power supply line VDD. .

  In the n-type transistors 330-1 and 330-2, the low potential side is the source and the high potential side is the drain. In the following description, of the sources and drains of the n-type transistors 330-1 and 330-2, the side electrically connected to the low potential power supply line VSS is referred to as sources 334-1 and 334-2. Of the sources and drains of the n-type transistors 330-1 and 330-2, the side that is not electrically connected to the low-potential power supply wiring VSS is referred to as drains 335-1 and 335-2.

  In the p-type transistors 310-1 and 310-2, the high potential side is the source, and the low potential side is the drain. In the following description, of the sources and drains of the p-type transistors 310-1 and 310-2, the side electrically connected to the high potential power supply wiring VDD is referred to as sources 314-1 and 314-2. Of the sources and drains of the p-type transistors 310-1 and 310-2, the side that is not electrically connected to the high potential power supply wiring VDD is referred to as drains 315-1 and 315-2.

In the n-type transistors 330-1 and 330-2, the sources 334-1 and 334-2 are connected to the gates 333-1a and 333-2a, and the sources 334-1 and 334-2 and the gates 333-1a and 333-2a are connected. Become the same potential. In the n-type transistors 330-1 and 330-2, the resistance varies depending on the potentials of the gates 333-1a and 333-2a with respect to the drains 335-1 and 335-2. That is, when the gates 333-1a and 333-2a become positive potentials with respect to the drains 335-1 and 335-2, the n-type transistors 330-1 and 330-2 are turned on (on state). When the gates 333-1a and 333-2a have a negative potential with respect to the drains 335-1 and 335-2, the n-type transistors 330-1 and 330-2 are turned off (off state).
The sources 334-1 and 334-2 of the n-type transistors 330-1 and 330-2 are examples of “one of the source and the drain” in the present invention.

In the p-type transistors 310-1 and 310-2, the sources 314-1 and 314-2 are connected to the gates 313-1a and 313-2a, and the sources 314-1 and 314-2 and the gates 313-1a and 313-2a are connected. Become the same potential. In the p-type transistors 310-1 and 310-2, the resistance varies depending on the potential of the gates 313-1a and 313-2a with respect to the drains 315-1 and 315-2. That is, when the gates 313-1a and 313-2a have a negative potential with respect to the drains 315-1 and 315-2, the p-type transistors 310-1 and 310-2 are turned on (on state). When the gates 313-1a and 313-2a become positive potentials with respect to the drains 315-1 and 315-2, the p-type transistors 310-1 and 310-2 are turned off (off state).
The sources 314-1 and 314-2 of the p-type transistors 310-1 and 310-2 are examples of “one of the source and the drain” in the present invention.

The gate 333-1a (source 334-1) of the first n-type transistor 330-1 is electrically connected to the low potential power wiring VSS. The drain 335-1 of the first n-type transistor 330-1 is electrically connected to the signal line SL.
The drain 335-1 of the first n-type transistor 330-1 is an example of “the other of the source and the drain” in the present invention.

The gate 313-1a (source 314-1) of the first p-type transistor 310-1 is electrically connected to the high potential power wiring VDD. The drain 315-1 of the first p-type transistor 310-1 is electrically connected to the signal line SL.
The drain 315-1 of the first p-type transistor 310-1 is an example of “the other of the source and the drain” in the present invention.

The gate 333-2a (source 334-2) of the second n-type transistor 330-2 is electrically connected to the low potential power wiring VSS. The drain 335-2 of the second n-type transistor 330-2 is electrically connected to the high potential power wiring VDD.
The drain 335-2 of the second n-type transistor 330-2 is an example of “the other of the source and the drain” in the present invention.

The gate 313-2a (source 314-2) of the second p-type transistor 310-2 is electrically connected to the high potential power wiring VDD. The drain 315-2 of the second p-type transistor 310-2 is electrically connected to the low potential power wiring VSS.
The drain 315-2 of the second p-type transistor 310-2 is an example of “the other of the source and the drain” in the present invention.

"Configuration of electrostatic protection circuit"
FIG. 6 is a schematic plan view showing the arrangement of each component of the electrostatic protection circuit. FIG. 7 is a schematic cross-sectional view showing the structure of the first electrostatic protection circuit taken along line AA ′ of FIG. FIG. 8A is a schematic cross-sectional view showing the structure of the second electrostatic protection circuit (the region where the second p-type transistor is formed) along the line BB ′ in FIG. FIG. 8B is a schematic cross-sectional view showing the structure of the second electrostatic protection circuit (region where the second n-type transistor is formed) along the line CC ′ of FIG.
First, a planar configuration of the electrostatic protection circuit 300 will be described with reference to FIG.

As shown in FIG. 6, the electrostatic protection circuit 300 includes a first electrostatic protection circuit 301 and a second electrostatic protection circuit 302. In the first electrostatic protection circuit 301, the first n-type transistor 330-1 and the first p-type transistor 310-1 are arranged substantially symmetrically with respect to the signal wiring SL. In the second electrostatic protection circuit 302, the second n-type transistor 330-2 and the second p-type transistor 310-2 are arranged along the low-potential power line VSS and the high-potential power line VDD.
The first electrostatic protection circuit 301 has the same configuration as the electrostatic protection circuit 500 (FIG. 16) of the known technology (Japanese Patent Laid-Open No. 2006-18165), and the second electrostatic protection circuit 302 is the electrostatic protection of the known technology. The circuit 500 has a different configuration.

  In the first n-type transistor 330-1 of the first electrostatic protection circuit 301, the semiconductor layer 331-1 has a rectangular shape, and includes a high concentration drain region 331-1e, a channel region 331-1a, and a high concentration source region 331. -1d. A channel of the first n-type transistor 330-1 is formed in a region where the semiconductor layer 331-1 (channel region 331-1a) and the gate electrode 333-1 (gate 333-1a) overlap. The channel width of the first n-type transistor 330-1 is W1, and the channel length is L1.

  A part of the high-concentration source region 331-1d overlaps with the low-potential power supply line VSS, and a contact hole CTS-1a is disposed in the overlapping part. A part of the high-concentration drain region 331-1e overlaps with the signal wiring SL, and a contact hole CTD-1a is disposed in the overlapping portion. The gate electrode 333-1 is disposed so as to overlap with the channel region 331-1a of the semiconductor layer 331-1 and the low-potential power supply wiring VSS. A portion of the gate electrode 333-1 overlapping with the channel region 331-1a of the semiconductor layer 331-1 becomes the gate 333-1a. The gate electrode 333-1 has a U shape and does not overlap the high concentration source region 331-1d. A contact hole CTG-1a is arranged in a portion where the gate electrode 333-1 and the low potential power wiring VSS overlap.

  In the first p-type transistor 310-1 of the first electrostatic protection circuit 301, the semiconductor layer 311-1 has a rectangular shape, and includes a high concentration drain region 311-1e, a channel region 311-1a, and a high concentration source region 311. -1d. A channel of the first p-type transistor 310-1 is formed in a region where the semiconductor layer 311-1 (channel region 311-1a) and the gate electrode 313-1 (gate 313-1a) overlap. The channel width of the first p-type transistor 310-1 is W1, and the channel length is L1.

  A part of the high-concentration drain region 311-1e overlaps with the signal wiring SL, and a contact hole CTD-1b is disposed in the overlapping part. A part of the high-concentration source region 311-1d overlaps the high-potential power supply wiring VDD, and a contact hole CTS-1b is disposed in the overlapped part. The gate electrode 313-1 is disposed so as to overlap the channel region 311-1a of the semiconductor layer 311-1 and the high-potential power supply wiring VDD. A portion of the gate electrode 313-1 overlapping with the channel region 311-1a of the semiconductor layer 311-1 becomes the gate 313-1a. The gate electrode 313-1 has a U shape and does not overlap the high concentration source region 311-1d. A contact hole CTG-1b is arranged at a portion where the gate electrode 313-1 and the high potential power supply wiring VDD overlap.

  In the second n-type transistor 330-2 of the second electrostatic protection circuit 302, the semiconductor layer 331-2 has a rectangular shape, and includes a high concentration drain region 331-2e, a channel region 331-2a, and a high concentration source region 331. -2d. A channel of the second n-type transistor 330-2 is formed in a region where the semiconductor layer 331-2 (channel region 331-2a) and the gate electrode 333-2 (gate 333-2a) overlap. The channel width of the second n-type transistor 330-2 is W1, and the channel length is L2.

  The second n-type transistor 330-2 and the first n-type transistor 330-1 have the same channel width W1. The channel length L2 of the second n-type transistor 330-2 is larger than the channel length L1 of the first n-type transistor 330-1. Specifically, the channel length L2 of the second n-type transistor 330-2 includes 120% of the channel length L1 of the first n-type transistor 330-1, or the channel length L1 of the first n-type transistor 330-1 It is larger than 120% of the channel length L1. If the channel width is the same, the resistance value of the n-type transistor increases in proportion to the channel length (high resistance). Accordingly, the second n-type transistor 330-2 has a higher resistance than the first n-type transistor 330-1.

  A portion of the high-concentration drain region 331-2e of the second n-type transistor 330-2 overlaps the high-potential power supply wiring VDD, and a contact hole CTD-2a is disposed in the overlapping portion. A part of the high-concentration source region 331-2d overlaps the low-potential power supply wiring VSS, and a contact hole CTS-2a is disposed in the overlapped portion. The gate electrode 333-2 is disposed so as to overlap the channel region 331-2a of the semiconductor layer 331-2 and the low-potential power supply wiring VSS. A portion of the gate electrode 333-2 that overlaps with the channel region 331-2 a of the semiconductor layer 331-2 becomes the gate 333-2 a. The low-potential power supply line VSS extends toward the semiconductor layer 331-2 so as to have a portion overlapping the high-concentration source region 331-2d and the gate electrode 333-2 of the semiconductor layer 331-2 in plan view. . A contact hole CTG-2a is disposed in a portion where the low potential power wiring VSS and the gate electrode 333-2 overlap.

  In the second p-type transistor 310-2 of the second electrostatic protection circuit 302, the semiconductor layer 311-2 has a rectangular shape, and includes a high concentration drain region 311-2e, a channel region 311-2a, and a high concentration source region 311. -2d. A channel of the second p-type transistor 310-2 is formed in a region where the semiconductor layer 311-2 (channel region 311-2a) and the gate electrode 313-2 (gate 313-2a) overlap. The channel width of the second p-type transistor 310-2 is W1, and the channel length is L2.

  The second p-type transistor 310-2 and the first p-type transistor 310-1 have the same channel width W1. The channel length L2 of the second p-type transistor 310-2 is larger than the channel length L1 of the first p-type transistor 310-1. Specifically, the channel length L2 of the second p-type transistor 310-2 includes 120% of the channel length L1 of the first p-type transistor 310-1, or the channel length L1 of the first p-type transistor 310-1 It is larger than 120% of the channel length L1. If the channel width is the same, the resistance value of the p-type transistor increases in proportion to the channel length (high resistance). Therefore, the second p-type transistor 310-2 has a higher resistance than the first p-type transistor 310-1.

  A part of the high-concentration drain region 311-2e overlaps the low-potential power supply wiring VSS, and a contact hole CTD-2b is disposed in the overlapped part. A part of the high-concentration source region 311-2d overlaps the high-potential power supply wiring VDD, and a contact hole CTS-2b is disposed in the overlapping portion. The gate electrode 313-2 is disposed so as to overlap the channel region 311-2a of the semiconductor layer 311-2 and the high-potential power supply wiring VDD. A portion of the gate electrode 313-2 that overlaps the channel region 311-2a of the semiconductor layer 311-2 serves as the gate 313-2a. The high-potential power supply wiring VDD projects to the semiconductor layer 311-2 side so as to have a portion overlapping the high-concentration source region 311-2d and the gate electrode 313-2 of the semiconductor layer 311-2 in plan view. . A contact hole CTG-2b is arranged in a portion where the high potential power supply wiring VDD and the gate electrode 313-2 overlap.

As described above, the second n-type transistor 330-2 has a higher resistance than the first n-type transistor 330-1. The second p-type transistor 310-2 has a higher resistance than the first p-type transistor 310-1.
Therefore, the second static electricity protection circuit 302 has a higher resistance than the first static electricity protection circuit 301.

  Note that the first n-type transistor 330-1, the first p-type transistor 310-1, the second n-type transistor 330-2, and the second p-type transistor 310-2 have the same channel width W1. Although it has, it is not limited to this. For example, the n-type transistors 330-1 and 330-2 and the p-type transistors 310-1 and 310-2 may have different channel widths and channel lengths.

In short, the channel width and the channel length of each transistor may be set so that the resistance value of the second n-type transistor 330-2 is higher than the resistance value of the first n-type transistor 330-1. Similarly, the channel width and the channel length of each transistor may be set so that the resistance value of the second p-type transistor 310-2 is higher than the resistance value of the first p-type transistor 310-1.
In other words, the channel lengths of the transistors constituting the second electrostatic protection circuit 302 and the first electrostatic protection circuit 301 so that the second electrostatic protection circuit 302 has a higher resistance than the first electrostatic protection circuit 301. And the channel width may be set.

Next, the structure of the first electrostatic protection circuit 301 will be described with reference to FIG.
As shown in FIG. 7, the semiconductor layers 311-1 and 331-1 provided on the base insulating film 12 covering the substrate body 10a are covered with the gate insulating film 2. On the gate insulating film 2, gate electrodes 313-1 and 333-1 formed in the same process as the gate electrode 3a are provided. The portions of the gate electrodes 313-1 and 333-1 that face the semiconductor layers 311-1 and 331-1 through the gate insulating film 2 become gates 313-1a and 333-1a. The gate electrodes 313-1 and 333-1 and the gate insulating film 2 are covered with a first interlayer insulating film 41. On the first interlayer insulating film 41, a low-potential power line VSS, a high-potential power line VDD, and a signal line SL formed in the same process as the data line 6a and the relay electrode 5a are provided. A second interlayer insulating film 42 and a third interlayer insulating film 43 are sequentially stacked on the low potential power wiring VSS, the high potential power wiring VDD, and the signal wiring SL.

  Next, with reference to FIG. 8A, the structure of the region where the second p-type transistor 310-2 is provided in the second electrostatic protection circuit 302 will be described.

  As shown in FIG. 8A, the semiconductor layer 311-2 provided on the base insulating film 12 covering the substrate body 10a is covered with the gate insulating film 2. On the gate insulating film 2, a gate electrode 313-2 formed in the same process as the gate electrode 3a is provided. A portion of the gate electrode 313-2 facing the semiconductor layer 311-2 via the gate insulating film 2 serves as the gate 313-2 a. The gate electrode 313-2 and the gate insulating film 2 are covered with a first interlayer insulating film 41. On the first interlayer insulating film 41, a low-potential power line VSS and a high-potential power line VDD formed in the same process as the data line 6a and the relay electrode 5a are provided. A second interlayer insulating film 42 and a third interlayer insulating film 43 are sequentially stacked on the low potential power wiring VSS and the high potential power wiring VDD.

  Next, the structure of the region where the second n-type transistor 330-2 is provided in the second electrostatic protection circuit 302 will be described with reference to FIG.

  As shown in FIG. 8B, the semiconductor layer 331-2 provided on the base insulating film 12 covering the substrate body 10a is covered with the gate insulating film 2. On the gate insulating film 2, a gate electrode 333-2 formed in the same process as the gate electrode 3a is provided. A portion of the gate electrode 333-2 facing the semiconductor layer 331-2 via the gate insulating film 2 becomes the gate 333-2 a. The gate electrode 333-2 and the gate insulating film 2 are covered with the first interlayer insulating film 41. On the first interlayer insulating film 41, a low-potential power line VSS and a high-potential power line VDD formed in the same process as the data line 6a and the relay electrode 5a are provided. A second interlayer insulating film 42 and a third interlayer insulating film 43 are sequentially stacked on the low potential power wiring VSS and the high potential power wiring VDD.

  Note that the low-potential power supply wiring VSS, the high-potential power supply wiring VDD, and the signal wiring SL are connected to a main line portion that is electrically connected to a semiconductor circuit (such as the data line driving circuit 101, the scanning line driving circuit 104, and the sampling circuit 7). And a branch line portion electrically connected to the electrostatic protection circuit 300 (not shown). For example, a branch line portion that is electrically connected to one of the plurality of electrostatic protection circuits 300 and the other electrostatic protection circuit 300 among the plurality of electrostatic protection circuits 300 are electrically connected. The portions corresponding to the branch portions of the low-potential power supply line VSS, the high-potential power supply line VDD, and the signal line SL so that the other branch line portions intersect with each other in plan view are not electrically short-circuited. It has a multilayer wiring structure formed in the same process as the pixel P (not shown). Similarly, portions corresponding to the main line portions of the low potential power supply wiring VSS, the high potential power supply wiring VDD, and the signal wiring SL also have a multilayer wiring structure formed in the same process as the pixel P (not shown). .

  Further, in the first n-type transistor 330-1, the low potential power wiring VSS electrically connects the gate 333-1a (gate electrode 333-1) and the source 334-1 (high concentration source region 331-1d). In the first p-type transistor 310-1, the high potential power supply wiring VDD is connected to the gate 313-1a (gate electrode 313-1) and the source 314-1 (high concentration source region 311-1d). It becomes a relay electrode which electrically connects (refer FIG. 7). In the second n-type transistor 330-2, the low-potential power supply line VSS electrically connects the gate 333-2a (gate electrode 333-2) and the source 334-2 (high concentration source region 331-2d). It becomes a relay electrode (see FIG. 8B). In the second p-type transistor 310-2, the high potential power supply wiring VDD electrically connects the gate 313-2a (gate electrode 313-2) and the source 314-2 (high concentration source region 311-2d). It becomes a relay electrode (see FIG. 8A).

"Operation and effect of electrostatic protection circuit"
9 to 11 are circuit diagrams of the static electricity protection circuit corresponding to FIG. 5, and the flow of charges added by static electricity is indicated by broken lines. Specifically, in FIG. 9A, the flow of the negative charge NC added to the low potential power supply wiring VSS is indicated by a broken line. In FIG. 9B, the flow of the negative charge NC added to the high potential power wiring VDD is indicated by a broken line. In FIG. 10A, the flow of the positive charge PC added to the low potential power supply wiring VSS is indicated by a broken line.
In FIG. 10B, the flow of the positive charge PC added to the high potential power wiring VDD is indicated by a broken line. In FIG. 11A, the flow of the negative charge NC added to the signal line SL is indicated by a broken line. In FIG. 11B, the flow of the positive charge PC added to the signal wiring SL is shown by the wiring.

  During the operation of the liquid crystal device 100, the potential of each wiring increases in the order of the potential of the low potential power supply wiring VSS, the potential of the signal wiring SL, and the potential of the high potential power supply wiring VDD.

  As a result, in the first n-type transistor 330-1, since the gate 333-1a has a negative potential with respect to the drain 335-1, the first n-type transistor 330-1 is turned off. In the first p-type transistor 310-1, since the gate 313-1a has a positive potential with respect to the drain 315-1, the first p-type transistor 310-1 is turned off. In the second n-type transistor 330-2, since the gate 333-2a has a negative potential with respect to the drain 335-2, the second n-type transistor 330-2 is turned off. In the second p-type transistor 310-2, since the gate 313-2a has a positive potential with respect to the drain 315-2, the second p-type transistor 310-2 is turned off.

  That is, during the operation of the liquid crystal device 100, all of the transistors included in the first electrostatic protection circuit 301 and the second electrostatic protection circuit 302 are turned off. Therefore, the low-potential power supply wiring VSS, the high-potential power supply wiring VDD, and the signal wiring SL that are electrically connected to the transistors included in the first electrostatic protection circuit 301 and the second electrostatic protection circuit 302 are electrically connected to each other. The liquid crystal device 100 operates normally without any interference.

  When the liquid crystal device 100 is not operating, the low potential power supply wiring VSS, the high potential power supply wiring VDD, and the signal wiring SL are in a floating state in which the potential is not determined. For example, when positive static electricity acts on the low potential power wiring VSS, the low potential power wiring VSS has a positive potential, and when negative static electricity acts on the low potential power wiring VSS, the low potential power wiring VSS becomes negative. Have a potential of. Similarly, the potentials of the high potential power supply wiring VDD and the signal wiring SL also change due to static electricity acting on the high potential power supply wiring VDD and the signal wiring SL.

  When static electricity acts on a wiring (low potential power wiring VSS, high potential power wiring VDD, signal wiring SL) when the liquid crystal device 100 is not operating, the potential of the wiring fluctuates greatly and is electrically connected to the wiring. There is a risk that unrecoverable electrostatic damage (for example, electrostatic breakdown) may occur in the semiconductor circuits (sampling circuit 7, data line driving circuit 101, scanning line driving circuit 104). Since the liquid crystal device 100 includes the electrostatic protection circuit 300, the influence of static electricity when the liquid crystal device 100 is not in operation is reduced (suppressed), and a semiconductor circuit (sampling circuit 7, data line driving circuit 101, scanning line driving). The circuit 104) is less likely to cause non-recoverable electrostatic damage (for example, electrostatic breakdown).

As described above, the electrostatic protection circuit 300 according to the present embodiment is different from the first electrostatic protection circuit 301 having the same configuration as the known electrostatic protection circuit 500 (see FIG. 16) and the known electrostatic protection circuit 500. And a second electrostatic protection circuit 302 having a configuration. Therefore, the electrostatic protection circuit 300 according to the present embodiment can suppress the influence of static electricity more strongly than the case where only the electrostatic protection circuit 500 according to the known technology is provided.
The details will be described below. In the following description, the electrostatic protection circuit composed of only the first electrostatic protection circuit 301, that is, the electrostatic protection circuit 300 that does not include the second electrostatic protection circuit 302 is referred to as a known electrostatic protection circuit.

  When the negative charge NC is added to the low potential power supply line VSS due to static electricity when the liquid crystal device 100 is not operating, the gate 333-1a of the first n-type transistor 330-1 is negative with respect to the drain 335-1. And the first n-type transistor 330-1 becomes non-conductive. The gate 333-2a of the second n-type transistor 330-2 has a negative potential with respect to the drain 335-2, and the second n-type transistor 330-2 is turned off. The gate 313-2a of the second p-type transistor 310-2 has a positive potential with respect to the drain 315-2, and the second p-type transistor 310-2 becomes non-conductive.

  For this reason, as shown in FIG. 9A, the negative charges NC added to the low-potential power supply wiring VSS by static electricity are the first n-type transistor 330-1, the second n-type transistor 330-2, And the third p-type transistor 310-2 acts in a distributed manner. When a known electrostatic protection circuit is used, the negative charge NC locally acts only on the first n-type transistor 330-1. When the negative charge NC locally acts only on the first n-type transistor 330-1, the first n-type transistor 330-1 cannot recover compared to the case where the negative charge NC acts on three transistors in a distributed manner. Electrostatic damage (for example, electrostatic breakdown) is likely to occur. That is, in the electrostatic protection circuit 300 according to the present embodiment, the influence of the negative charge NC added to the low-potential power line VSS due to static electricity is distributed to the three transistors. As compared with the first n-type transistor 330-1, the second n-type transistor 330-2, and the second p-type transistor 330-2 are less likely to cause irrecoverable electrostatic damage. Therefore, the first static electricity protection circuit 301 and the second static electricity protection circuit 302 are hardly broken by the negative charge NC added to the low-potential power supply wiring VSS due to static electricity, and the first static electricity protection circuit 301 and the second static electricity protection circuit 301 The electrostatic protection circuit 302 can be stably operated for a long time, and the influence of static electricity can be stably suppressed.

  When a negative charge NC is added to the high-potential power supply wiring VDD due to static electricity, the gate 333-2a of the second n-type transistor 330-2 has a positive potential with respect to the drain 335-2, and the second The n-type transistor 330-2 becomes conductive. The gate 313-1a of the first p-type transistor 310-1 has a negative potential with respect to the drain 315-1, and the first p-type transistor 310-1 becomes conductive. The gate 313-2a of the second p-type transistor 310-2 has a negative potential with respect to the drain 315-2, and the second p-type transistor 310-2 becomes conductive.

  For this reason, as shown in FIG. 9B, the negative charge NC added to the high-potential power supply wiring VDD due to static electricity passes through the first p-type transistor 310-1 in a conductive state, thereby causing the signal wiring SL. And is discharged to the low-potential power line VSS via the second n-type transistor 330-2 and the second p-type transistor 310-2 that are in a conductive state. When a known electrostatic protection circuit is used, the negative charge NC is discharged only to the signal wiring SL. In the electrostatic protection circuit 300, the negative charge NC added to the high-potential power supply wiring VDD is discharged to both the signal wiring SL and the low-potential power supply wiring VSS, so that compared with the case where a known electrostatic protection circuit is used. Thus, the semiconductor circuit (sampling circuit 7, data line driving circuit 101, scanning line driving circuit) that is electrically connected to the high potential power supply wiring VDD and strongly suppressing the potential fluctuation of the high potential power supply wiring VDD due to the negative charge NC. 104), unrecoverable electrostatic damage is less likely to occur.

  Although details will be described later, when the negative charge NC added to the high-potential power supply wiring VDD is discharged only to the signal wiring SL, the potential fluctuation of the signal wiring SL increases, and the semiconductor circuit connected to the signal wiring SL. There is a possibility that unrecoverable electrostatic damage may occur in the (sampling circuit 7, data line driving circuit 101, scanning line driving circuit 104) and the like. In the present embodiment, since the negative charge NC added to the high potential power supply wiring VDD is dispersed and discharged to both the signal wiring SL and the low potential power supply VSS, compared with the case of discharging only to the signal wiring SL, The potential fluctuation of the wiring (low potential power supply wiring VSS, signal wiring SL) on the side where the negative charge NC is discharged is reduced, and the semiconductor circuit (sampling circuit 7, data line driving circuit 101, scanning line driving circuit 104) or the like is used. Unrecoverable electrostatic damage is less likely to occur.

  When a positive charge PC is added to the low-potential power supply wiring VSS due to static electricity, the gate 333-1a of the first n-type transistor 330-1 has a positive potential with respect to the drain 335-1, The n-type transistor 330-1 becomes conductive. The gate 333-2a of the second n-type transistor 330-2 has a positive potential with respect to the drain 335-2, and the second n-type transistor 330-2 becomes conductive. The gate 313-2a of the second p-type transistor 310-2 has a negative potential with respect to the drain 315-2, and the second p-type transistor 310-2 becomes conductive.

  For this reason, as shown in FIG. 10A, the positive charge PC added to the low-potential power supply wiring VSS due to static electricity passes through the first n-type transistor 330-1 in the conductive state, and the signal wiring SL. And is discharged to the high-potential power supply wiring VDD through the second n-type transistor 330-2 and the second p-type transistor 310-2 that are in a conductive state. When a known electrostatic protection circuit is used, the positive charge PC is discharged only to the signal wiring SL. In the electrostatic protection circuit 300, the positive charge PC added to the low-potential power supply wiring VSS is discharged to both the signal wiring SL and the high-potential power supply wiring VDD, so that compared with the case where the known electrostatic protection circuit is used. Thus, the semiconductor circuit (sampling circuit 7, data line driving circuit 101) electrically connected to the low-potential power line VSS is strongly suppressed by suppressing the potential fluctuation of the low-potential power line VSS due to positive static electricity (positive charge PC). Thus, the irrecoverable electrostatic damage is less likely to occur in the scanning line driving circuit 104).

  Although details will be described later, when the positive charge PC added to the low-potential power supply line VSS is discharged only to the signal line SL, the potential fluctuation of the signal line SL increases, and the semiconductor circuit connected to the signal line SL. There is a possibility that unrecoverable electrostatic damage may occur in the (sampling circuit 7, data line driving circuit 101, scanning line driving circuit 104) and the like. In the present embodiment, the positive charge PC added to the low potential power line VSS is dispersed and discharged to both the signal line SL and the high potential power line VDD. The potential fluctuation of the wiring (high potential power supply wiring VDD, signal wiring SL) on the side where the positive charge PC is discharged is reduced, and the semiconductor circuit (sampling circuit 7, data line driving circuit 101, scanning line driving circuit 104) or the like is used. Unrecoverable electrostatic damage is less likely to occur.

  When a positive charge PC is added to the high-potential power supply wiring VDD due to static electricity, the gate 313-1a of the first p-type transistor 310-1 has a positive potential with respect to the drain 315-1, The p-type transistor 310-1 is turned off. The gate 333-2a of the second n-type transistor 330-2 has a negative potential with respect to the drain 335-2, and the second n-type transistor 330-2 is turned off. The gate 313-2a of the second p-type transistor 310-2 has a positive potential with respect to the drain 315-2, and the second p-type transistor 310-2 becomes non-conductive.

  For this reason, as shown in FIG. 10B, the positive charges PC added to the high-potential power supply wiring VDD by static electricity are the first p-type transistor 310-1, the second n-type transistor 330-2, And the third p-type transistor 310-2 acts in a distributed manner. When a known electrostatic protection circuit is used, the positive charge PC locally acts only on the first p-type transistor 310-1. When the positive charge PC acts locally only on the first p-type transistor 310-1, it cannot recover to the first p-type transistor 310-1 as compared with the case where the positive charge PC acts in a distributed manner on the three transistors. Electrostatic damage is likely to occur. In the electrostatic protection circuit 300, since the influence of the positive charge PC added to the high-potential power supply wiring VDD due to static electricity is distributed to the three transistors, the first p-type transistor is used when the known electrostatic protection circuit is used. Unrecoverable electrostatic damage is unlikely to occur in 310-1, the second n-type transistor 330-2, and the second p-type transistor 310-2.

  Accordingly, the first electrostatic protection circuit 301 and the second electrostatic protection circuit 302 are not easily broken by the positive charge PC added to the high-potential power supply wiring VDD due to static electricity, and the first electrostatic protection circuit 301 and the second electrostatic protection circuit 301 The electrostatic protection circuit 302 can be stably operated for a long time, and the influence of static electricity can be stably suppressed.

  When a negative charge NC is added to the signal line SL due to static electricity, the gate 333-1a of the first n-type transistor 330-1 has a positive potential with respect to the drain 335-1, and the first n-type The transistor 330-1 becomes conductive. The gate 313-1a of the first p-type transistor 310-1 has a positive potential with respect to the drain 315-1, and the first p-type transistor 310-1 is turned off.

  For this reason, as shown in FIG. 11A, the negative charge NC added to the signal line SL due to static electricity passes through the first n-type transistor 330-1 in a conductive state, and the low potential power supply line VSS. Discharged. Therefore, the negative charge NC added to the signal line SL is discharged to the low potential power supply line VSS via the first n-type transistor 330-1 that is in the conductive state, and thus the signal line due to the negative charge NC. The semiconductor circuit (sampling circuit 7, data line driving circuit 101, scanning line driving circuit 104) and the like that are electrically connected to the signal wiring SL by suppressing the potential fluctuation of SL cannot be recovered from electrostatic damage (for example, static electricity). Electrostatic breakdown is less likely to occur.

  When a positive charge PC is added to the signal line SL due to static electricity, the gate 333-1a of the first n-type transistor 330-1 has a negative potential with respect to the drain 335-1, and the first n-type The transistor 330-1 is turned off. The gate 313-1a of the first p-type transistor 310-1 has a negative potential with respect to the drain 315-1, and the first p-type transistor 310-1 becomes conductive.

  For this reason, as shown in FIG. 11B, the positive charge PC added to the signal wiring SL due to static electricity passes through the first p-type transistor 310-1 which is in a conductive state, and thus the high potential power wiring VDD Discharged. Since the positive charge PC added to the signal line SL is discharged to the high potential power supply line VDD through the first p-type transistor 310-1 which is in a conductive state, the signal line SL of the positive charge PC is discharged. Potential fluctuations are suppressed, and irreparable electrostatic damage is less likely to occur in a semiconductor circuit (sampling circuit 7, data line driving circuit 101, scanning line driving circuit 104) or the like electrically connected to the signal wiring SL.

  The low-potential power supply wiring VSS and the high-potential power supply wiring VDD are wirings that supply power to the semiconductor circuits (sampling circuit 7, data line driving circuit 101, and scanning line driving circuit 104), and the signal wiring SL A wiring for supplying a signal to be driven, and a larger current flows through the low potential power wiring VSS and the high potential power wiring VDD than the signal wiring SL. For this reason, the areas of the low-potential power supply wiring VSS and the high-potential power supply wiring VDD are larger than the area of the signal wiring SL, that is, the wiring capacity of the low-potential power supply wiring VSS and the high-potential power supply wiring VDD is the wiring capacity of the signal wiring SL. The low potential power supply wiring VSS and the high potential power supply wiring VDD are larger than the signal wiring SL.

  If the same amount of charge is applied to the low-potential power line VSS, the high-potential power line VDD, and the signal line SL due to static electricity, the signal line SL having a small area (wiring capacity) has a large area (wiring capacity). Compared with the low potential power supply wiring VSS and the high potential power supply wiring VDD, a large potential fluctuation occurs. Further, the low potential power supply wiring VSS and the high potential power supply wiring VDD having a large wiring capacity cause a small potential fluctuation as compared with the signal wiring SL having a small wiring capacity. Thus, the influence of static electricity is different between the low potential power supply wiring VSS, the high potential power supply wiring VDD, and the signal wiring SL.

As shown in FIGS. 11A and 11B, the negative charge NC or the positive charge PC added to the signal wiring SL due to static electricity is either the low potential power wiring VSS or the high potential power wiring VDD. The potential fluctuation of the signal wiring SL due to static electricity is reduced. The wiring on which the charge is discharged (low potential power supply wiring VSS, high potential power supply wiring VDD) has a larger wiring capacity than the wiring on which charge is added (signal wiring SL). Even if the charge is discharged, the potential fluctuation of the wiring on which the charge is discharged (low potential power supply wiring VSS, high potential power supply wiring VDD) is larger than the potential fluctuation of the charge added side wiring (signal wiring SL). Get smaller.
Therefore, similarly to the wiring on which the charge is added (signal wiring SL), the wiring on which the charge is discharged (low-potential power supply wiring VSS, high-potential power supply wiring VDD) is also defective due to static electricity (unrecoverable). (Electrostatic damage) is suppressed.
As described above, the wiring on the side where charges due to static electricity are discharged is preferably a wiring with a large wiring capacity (low potential power wiring VSS, high potential power wiring VDD) rather than a wiring with a small wiring capacity (signal wiring SL). .

  As shown in FIGS. 9B and 10A, the negative charge NC or the positive charge PC added to the low-potential power line VSS or the high-potential power line VDD due to static electricity is transferred to the signal line SL and the power line. Dispersing and discharging to both (low potential power supply wiring VSS or high potential power supply wiring VDD), the potential fluctuation of the low potential power supply wiring VSS or the high potential power supply wiring VDD due to static electricity is reduced.

  For example, when a known electrostatic protection circuit is used, the negative charge NC or the positive charge PC added to the low potential power line VSS or the high potential power line VDD due to static electricity is discharged only to the signal line SL. become. In this case, since the wiring on which the charge is discharged (signal wiring SL) has a smaller wiring capacity than the wiring on which the charge is added (low potential power supply wiring VSS, high potential power supply wiring VDD), The potential fluctuation of the wiring on which the charge is discharged (signal wiring SL) is larger than the potential fluctuation of the wiring on which the charge is added (low potential power supply wiring VSS, high potential power supply wiring VDD). growing. That is, the negative charge NC or the positive charge PC added to the low potential power supply line VSS or the high potential power supply line VDD due to static electricity is discharged only to the signal line SL, thereby causing a large potential fluctuation in the signal line SL. There is a risk that unrecoverable electrostatic damage may occur in the semiconductor circuits (sampling circuit 7, data line driving circuit 101, scanning line driving circuit 104) electrically connected to the signal wiring SL.

  In the electrostatic protection circuit 300, the negative charge NC or the positive charge PC added to the low potential power supply line VSS or the high potential power supply line VDD due to static electricity is applied to the signal line SL and the power supply line (low potential power supply line VSS or high potential power supply Dispersed and discharged to both of the wiring VDD). Therefore, compared to the case where a known electrostatic protection circuit is used, the potential fluctuation of the wiring (signal wiring SL) on the side where electric charges are discharged is reduced, and the semiconductor circuit electrically connected to the signal wiring SL ( Unrecoverable electrostatic damage is less likely to occur in the sampling circuit 7, the data line driving circuit 101, and the scanning line driving circuit 104).

  Further, the ease of discharging the charge added by static electricity varies depending on the wiring capacity of the wiring on the side where the charge is discharged. Specifically, when the wiring capacity of the wiring on the side where charges are discharged is large, it is easier to discharge the charge added by static electricity than when the wiring capacity of the wiring where charges are discharged is small. Therefore, when the wiring capacity of the wiring from which charges are discharged is large, charges added by static electricity can be discharged more quickly than when the wiring capacity of the wiring from which charges are discharged is small. When the charge added by the static electricity is discharged quickly, the potential fluctuation of the wiring on the side to which the static electricity is added is also reduced.

  When a known electrostatic protection circuit is used, the wiring on the side where electric charges are discharged becomes the signal wiring SL. When the electrostatic protection circuit 300 according to the present embodiment is used, the wiring on the side where charges are discharged is the signal wiring SL and the power wiring (either the low potential power wiring VSS or the high potential power wiring VDD). Therefore, the electrostatic capacity of the electrostatic discharge protection circuit 300 is larger than that of the known electrostatic protection circuit. Therefore, the electrostatic protection circuit 300 can quickly discharge the charge added by static electricity and reduce the potential fluctuation of the wiring on the side where the static electricity is applied, as compared with the known electrostatic protection circuit.

  As described above, in the electrostatic protection circuit 300 according to the present embodiment, the potential fluctuations of both the wiring on the side to which static electricity is applied and the wiring on the side to which static electricity is discharged are smaller than those of the known electrostatic protection circuit. Therefore, it is possible to more strongly suppress problems caused by static electricity (unrecoverable electrostatic damage).

  In the process of manufacturing the liquid crystal device 100, static electricity is generated due to various factors. For example, in processing (cleaning, film formation, etching, etc.) using a plasma atmosphere, plasma becomes a source of static electricity. In transport and handling, static electricity is generated by sliding and friction. Charged members (cassettes, jigs and tools) are also sources of static electricity. Furthermore, even after the liquid crystal device 100 is completed, static electricity is generated due to various factors.

  Such static electricity is more likely to act on the low potential power supply wiring VSS and the high potential power supply wiring VDD having a larger area than the signal wiring SL having a smaller area. That is, a large amount of charge is more likely to be applied to the low-potential power supply line VSS and the high-potential power supply line VDD having a large area by static electricity than the signal wiring SL having a small area. As shown in FIG. 9B or FIG. 10A, a large amount of charge added to the low potential power supply line VSS or the high potential power supply line VDD causes the first electrostatic protection circuit 301 in the conductive state to enter the conductive state. Is discharged to the signal line SL, and is discharged to the power supply line (either the low potential power supply line VSS or the high potential power supply line VDD) via the second electrostatic protection circuit 302 that is in a conductive state.

  As described above, the charge added by static electricity is more likely to flow to the wiring side having a larger wiring capacity than to the wiring side having a smaller wiring capacity. It tends to flow to the second electrostatic protection circuit 302 side rather than the electrostatic protection circuit 301 side. Furthermore, since a large amount of charge is easily added to the low potential power supply line VSS and the high potential power supply line VDD due to static electricity, a large amount of charge (hereinafter referred to as a discharge current) flows through the second electrostatic protection circuit 302. Cheap.

  If the first electrostatic protection circuit 301 and the second electrostatic protection circuit 302 have substantially the same resistance, a large discharge current flows through the second electrostatic protection circuit 302. The current value of the discharge current flowing through the second electrostatic protection circuit 302 is proportional to the amount of charge added to the low potential power supply line VSS and the high potential power supply line VDD due to static electricity. For this reason, if the amount of electric charge added to the low potential power supply wiring VSS and the high potential power supply wiring VDD is increased, an excessive discharge current that may break the second electrostatic protection circuit 302 may flow.

  As described above, since the second static electricity protection circuit 302 has a higher resistance than the first static electricity protection circuit 301, it is possible to suppress an excessive discharge current that would break the second static electricity protection circuit 302. . That is, by making the second electrostatic protection circuit 302 have a higher resistance than the first electrostatic protection circuit 301, the electrostatic protection circuit 302 (electrostatic protection circuit 300) is more resistant to static electricity, and the second electrostatic protection circuit 302. The (electrostatic protection circuit 300) operates stably for a long period of time.

  In order to make the second static electricity protection circuit 302 have a higher resistance than the first static electricity protection circuit 301, the channel length L2 of the second n-type transistor 330-2 is set to be the same as that of the first n-type transistor 330-1. The channel length L1 is larger than that of the first p-type transistor 310-1, and the channel length L2 of the second p-type transistor 310-2 is larger than that of the first p-type transistor 310-1. For this reason, the capacitance formed in the channel region is larger in the second n-type transistor 330-2 than in the first n-type transistor 330-1, and in the second n-type transistor 310-1. The p-type transistor 310-2 is larger. That is, the second n-type transistor 330-2 and the second p-type transistor 310-2 have a larger capacity than the first n-type transistor 330-1 and the first p-type transistor 310-1. Become.

As described above, a large current tends to flow through the low potential power supply wiring VSS and the high potential power supply wiring VDD. Further, when a large current flows through the low potential power supply wiring VSS and the high potential power supply wiring VDD, the potentials of the low potential power supply wiring VSS and the high potential power supply wiring VDD change.
In the present embodiment, the second electrostatic protection circuit 302 (the second n-type transistor 330-2 and the second p-type transistor 310-2) having a large capacitance in the low-potential power line VSS and the high-potential power line VDD. Are electrically connected, the wiring capacity of the low-potential power supply wiring VSS and the high-potential power supply wiring VDD is increased, and the potential fluctuation of the low-potential power supply wiring VSS and the high-potential power supply wiring VDD is small even when a large current flows. Become. Therefore, the stability of the potentials of the low potential power supply wiring VSS and the high potential power supply wiring VDD is improved, and the liquid crystal device 100 can be operated stably.
That is, the second electrostatic protection circuit 302 is configured with a transistor having a larger capacity than the first electrostatic protection circuit 301 (the second electrostatic protection circuit 302 is a transistor having a higher resistance than the first electrostatic protection circuit 301. By configuring), the capacitance of the low potential power supply wiring VSS and the high potential power supply wiring VDD is increased, the stability of the potentials of the low potential power supply wiring VSS and the high potential power supply wiring VDD is increased, and the liquid crystal device 100 is stabilized. In addition to the effect of suppressing the influence of static electricity as described above, a new effect that it can be operated can be achieved.

As described above, the following effects can be obtained in this embodiment.
(1) The electrostatic protection circuit 300 includes a first electrostatic protection circuit 301 having the same configuration as that of the known technology and a second electrostatic protection circuit 302 having a configuration different from that of the known technology. When the electrostatic protection circuit 300 is used, compared to the case where a known electrostatic protection circuit is used, the charge caused by static electricity from the wiring (the low-potential power supply wiring VSS and the high-potential power supply wiring VDD) to which charges are added due to static electricity. Can be quickly discharged to reduce the potential fluctuation of the wiring on the side charged with static electricity, and also to reduce the potential fluctuation of the wiring on the side discharged with static electricity. Therefore, the electrostatic protection circuit 300 suppresses the influence of static electricity on the low-potential power supply wiring VSS and the high-potential power supply wiring VDD more strongly than the known electrostatic protection circuit, and the liquid crystal device 100 is resistant to static electricity (reliability). Can be increased.

  (2) Since the second electrostatic protection circuit 302 has a higher resistance than the first electrostatic protection circuit 301, an excessive discharge current that can break the second electrostatic protection circuit 302 is suppressed, and the electrostatic protection circuit 300. Resistance to static electricity of the (second electrostatic protection circuit 302) can be increased, and the electrostatic protection circuit 300 can be stably operated for a long period of time.

  (3) Since the second electrostatic protection circuit 302 has a larger capacity than the first electrostatic protection circuit 301, the second electrostatic protection circuit 302 is connected to the low potential power supply wiring VSS and the high potential power supply wiring VDD. By electrical connection, the wiring capacity of the low potential power supply wiring VSS and the high potential power supply wiring VDD is increased, and the potential fluctuation of the low potential power supply wiring VSS and the high potential power supply wiring VDD when a large current flows is reduced. be able to. Therefore, the stability of the potentials of the low potential power supply wiring VSS and the high potential power supply wiring VDD is improved, and the liquid crystal device 100 can be operated stably.

(Embodiment 2)
"Electronics"
FIG. 12 is a schematic diagram illustrating a configuration of a projection display device (liquid crystal projector) as an electronic apparatus. As shown in FIG. 12, a projection display apparatus 1000 as an electronic apparatus according to this embodiment includes a polarization illumination apparatus 1100 arranged along the system optical axis L, and two dichroic mirrors 1104 and 1105 as light separation elements. Three reflection mirrors 1106, 1107, 1108, five relay lenses 1201, 1202, 1203, 1204, 1205, three transmissive liquid crystal light valves 1210, 1220, 1230 as light modulation means, and a light combining element As a cross dichroic prism 1206 and a projection lens 1207.

  The polarized light illumination device 1100 is generally configured by a lamp unit 1101 as a light source composed of a white light source such as an ultra-high pressure mercury lamp or a halogen lamp, an integrator lens 1102, and a polarization conversion element 1103.

  The dichroic mirror 1104 reflects red light (R) and transmits green light (G) and blue light (B) among the polarized light beams emitted from the polarization illumination device 1100. Another dichroic mirror 1105 reflects the green light (G) transmitted through the dichroic mirror 1104 and transmits the blue light (B).

The red light (R) reflected by the dichroic mirror 1104 is reflected by the reflection mirror 1106 and then enters the liquid crystal light valve 1210 via the relay lens 1205.
Green light (G) reflected by the dichroic mirror 1105 enters the liquid crystal light valve 1220 via the relay lens 1204.
The blue light (B) transmitted through the dichroic mirror 1105 enters the liquid crystal light valve 1230 via a light guide system including three relay lenses 1201, 1202, 1203 and two reflection mirrors 1107, 1108.

  The liquid crystal light valves 1210, 1220, and 1230 are disposed to face the incident surfaces of the cross dichroic prism 1206 for each color light. The color light incident on the liquid crystal light valves 1210, 1220, and 1230 is modulated based on video information (video signal) and emitted toward the cross dichroic prism 1206. In this prism, four right-angle prisms are bonded together, and a dielectric multilayer film that reflects red light and a dielectric multilayer film that reflects blue light are formed in a cross shape on the inner surface thereof. The three color lights are synthesized by these dielectric multilayer films, and the light representing the color image is synthesized. The synthesized light is projected on the screen 1300 by the projection lens 1207 which is a projection optical system, and the image is enlarged and displayed.

  The liquid crystal device 100 described above is applied to the liquid crystal light valves 1210, 1220, and 1230. The liquid crystal device 100 includes the electrostatic protection circuit 300 according to the first embodiment, and irreparable electrostatic damage (for example, static electricity) to a semiconductor circuit (the data line driving circuit 101, the sampling circuit 7, the scanning line driving circuit 104, or the like). Electrostatic breakdown) is less likely to occur. Therefore, the projection display device 1000 to which the liquid crystal device 100 is applied is not easily affected by static electricity and has high reliability.

The present invention is not limited to the above-described embodiment, and can be appropriately changed without departing from the gist or concept of the invention that can be read from the claims and the entire specification, and a liquid crystal device with such a change, and Electronic equipment to which the liquid crystal device is applied is also included in the technical scope of the present invention.
Various modifications other than the above embodiment are conceivable. Hereinafter, a modification will be described.

(Modification 1)
FIG. 13 is a schematic cross-sectional view corresponding to FIG. 7 and showing the structure of the first electrostatic protection circuit (first P-type transistor, first n-type transistor). FIG. 14A corresponds to FIG. 8A and is a schematic cross-sectional view showing the structure of the second p-type transistor. FIG. 14B corresponds to FIG. 8B and is a schematic cross-sectional view showing the structure of the second n-type transistor. In addition, the same code | symbol is attached | subjected to the same structure as Embodiment 1, and detailed description is abbreviate | omitted.

  The transistor constituting the electrostatic protection circuit 300 according to this modification has an LDD (Lightly Doped Drain) structure in which low-concentration impurity regions (high resistance regions) are arranged on both sides of the channel region of the semiconductor layer. The transistors constituting the electrostatic protection circuit 300 according to the first embodiment do not have such an LDD structure (low concentration impurity region). This is the difference between this modification and the first embodiment.

  Specifically, as shown in FIG. 13, the semiconductor layer 311-1 of the first p-type transistor 310-1 according to this modification includes a high concentration drain region 311-1e, a low concentration drain region 311-1c, The channel region 311-1a, the low concentration source region 311-1b, and the high concentration source region 311-1d are configured. That is, in the first p-type transistor 310-1 according to this modification, the low concentration impurity regions 311-1b and 311-1c (high resistance regions) are arranged on both sides of the channel region 311-1a of the semiconductor layer 311-1. It has an LDD structure.

  The semiconductor layer 331-1 of the first n-type transistor 330-1 according to this modification includes a high concentration drain region 331-1e, a low concentration drain region 331-1c, a channel region 331-1a, and a low concentration source. The region 331-1b and the high concentration source region 331-1d are configured. That is, in the first n-type transistor 330-1 according to this modification, the low concentration impurity regions 331-1b and 331-1c (high resistance regions) are arranged on both sides of the channel region 331-1a of the semiconductor layer 331-1. It has an LDD structure.

  As shown in FIG. 14A, the semiconductor layer 311-2 of the second p-type transistor 310-2 according to this modification includes a high concentration drain region 311-2e, a low concentration drain region 311-2c, The channel region 311-2a, the low concentration source region 311-2b, and the high concentration source region 311-2d are configured. That is, in the second p-type transistor 310-2 according to this modification, the low concentration impurity regions 311-2b and 311-2c (high resistance regions) are arranged on both sides of the channel region 311-2a of the semiconductor layer 311-2. It has an LDD structure.

  As shown in FIG. 14B, the semiconductor layer 331-2 of the second n-type transistor 330-2 according to this modification includes a high concentration drain region 331-2e, a low concentration drain region 331-2c, The channel region 331-2a is composed of a low concentration source region 331-2b and a high concentration source region 331-2d. That is, in the second n-type transistor 330-2 according to this modification, the low concentration impurity regions 331-2b and 331-2c (high resistance regions) are arranged on both sides of the channel region 331-2a of the semiconductor layer 331-2. It has an LDD structure.

  In this modification, the impurity concentration of the LDD region of the transistor that constitutes the second electrostatic protection circuit 302 is made smaller than the impurity concentration of the LDD region of the transistor that constitutes the first electrostatic protection circuit 301, so that the second static electricity The LDD region in the protection circuit 302 has a higher resistance than the LDD region of the first electrostatic protection circuit 301. As a result, the second p-type transistor 310-2 has a higher resistance than the first p-type transistor 310-1, and the second n-type transistor 330-2 is more resistant than the first n-type transistor 330-1. High resistance. Therefore, the second electrostatic protection circuit 302 has a higher resistance than the first electrostatic protection circuit 301.

As described above, in addition to the method of adjusting the channel length and the channel width of the transistors constituting the second electrostatic protection circuit 302 and the first electrostatic protection circuit 301, the second electrostatic protection circuit 302 and the first electrostatic protection circuit The second electrostatic protection circuit 302 may have a higher resistance than the first electrostatic protection circuit 301 by adjusting the impurity concentration (resistance) of the LDD region of the transistor included in the transistor 301.
Further, an offset region (not shown) is provided in the transistors constituting the second electrostatic protection circuit 302 and the first electrostatic protection circuit 301, and the second electrostatic protection circuit 302 is adjusted by adjusting the size of the offset region. The resistance may be higher than that of the first electrostatic protection circuit 301.

(Modification 2)
15 corresponds to FIG. 5 and is a circuit diagram showing a configuration of an electrostatic protection circuit according to Modification 2.
In addition, the same code | symbol is attached | subjected to the same structure as Embodiment 1, and detailed description is abbreviate | omitted.
The difference between the electrostatic protection circuit 300 according to the first embodiment and the electrostatic protection circuit 300 according to this modification is in the configuration of the second electrostatic protection circuit 302.
Specifically, the second electrostatic protection circuit 302 of the first embodiment is configured by a second n-type transistor 330-2 and a second p-type transistor 310-2 (see FIG. 5). As shown in FIG. 15A, the second electrostatic protection circuit 302 of the present modification is configured by a second n-type transistor 330-2. Alternatively, as shown in FIG. 15B, the second electrostatic protection circuit 302 of the present modification is configured by a second p-type transistor 310-2.
This is the difference between this modification and the first embodiment.

Also in the second electrostatic protection circuit 302 configured by either the second n-type transistor 330-2 or the second p-type transistor 310-2, the second n-type transistor 330-2 and the second p-type transistor 330-2 are also included. Similarly to the second electrostatic protection circuit 302 of the first embodiment configured with both the type transistors 310-2, the influence of static electricity on the low potential power wiring VSS and the high potential power wiring VDD can be suppressed.
Furthermore, since the area of the second electrostatic protection circuit 302 according to this modification is smaller than the area of the second electrostatic protection circuit 302 according to the first embodiment, space saving of the electrostatic protection circuit 300 is achieved. Can do.

  As shown in the present modification and the first embodiment, the second electrostatic protection circuit 302 includes at least one of the second n-type transistor 330-2 and the second p-type transistor 310-2. That's fine.

(Modification 3)
The electrostatic protection circuit 300 is not limited to being applied to the liquid crystal device 100, and can be applied to, for example, a light emitting device having an organic electroluminescence element. By applying the static electricity protection circuit 300, a highly reliable light-emitting device which is hardly affected by static electricity can be provided.

  Furthermore, the electrostatic protection circuit 300 may be applied to MEMS (Micro Electro Mechanical Systems) in which a sensor, an actuator, an electronic circuit, or the like is formed over a semiconductor substrate or an insulating substrate, or an electronic device having a semiconductor circuit. For example, an electrostatic protection circuit in an integrated circuit composed of MOS transistors formed on a semiconductor substrate is also within the scope of the present invention.

(Modification 4)
The electrostatic protection circuit 300 is supplied with a wiring to which the lowest potential is supplied (for example, the low-potential power supply wiring VSS), a wiring with a potential higher than the potential of the wiring (for example, the signal wiring SL), and the highest potential. What is necessary is just to be electrically connected to wiring (for example, high potential power supply wiring VDD). Further, if there is a wiring to which such a potential is supplied, the electrostatic protection circuit 300 can be disposed at an arbitrary position of the liquid crystal device (electro-optical device).

  Specifically, the electrostatic protection circuit 300 is disposed in a region between the external circuit connection terminal 102 and the semiconductor circuit (the data line driving circuit 101, the sampling circuit 7, and the scanning line driving circuit 104). It is not limited. For example, the electrostatic protection circuit 300 may be disposed inside the data line driving circuit 101 or the scanning line driving circuit 104, or may be displayed as a semiconductor circuit (data line driving circuit 101, sampling circuit 7, scanning line driving circuit 104). You may arrange | position between the area | regions E.

  Furthermore, in the first embodiment, the electrostatic protection circuit 300 is connected to the low potential power supply wiring VSS, the high potential power supply wiring VDD, and the signal wiring SL. For example, among the plurality of signal wirings SL, the electrostatic protection circuit 300 is connected to the signal wiring SL to which the lowest potential is supplied, the signal wiring SL to which the highest potential is supplied, and the other signal wirings SL. It may be configured to be electrically connected.

(Modification 5)
The electronic apparatus to which the liquid crystal device 100 according to the first embodiment is applied is not limited to the projection display device 1000 according to the second embodiment. For example, in addition to the projection display device 1000, projection type HUD (head-up display), HMD (head-mounted display), electronic book, personal computer, digital still camera, liquid crystal television, viewfinder type or monitor direct view type video The liquid crystal device according to the first embodiment can be applied to an information terminal device such as a recorder, a car navigation system, a POS, and an electronic device such as an electronic notebook.
Further, even in an electronic device equipped with the electrostatic protection circuit 300 according to the first embodiment, the influence of static electricity is suppressed and high reliability is achieved. That is, if the electronic apparatus includes the electrostatic protection circuit 300 and / or the electro-optical device including the electrostatic protection circuit 300, the influence of static electricity is suppressed and the electronic apparatus has high reliability.

  DESCRIPTION OF SYMBOLS 100 ... Liquid crystal device, 300 ... Electrostatic protection circuit, 301 ... 1st electrostatic protection circuit, 310-1 ... 1st p-type transistor, 313-1a ... Gate, 314-1 ... Source, 315-1 ... Drain, 330-1 ... first n-type transistor, 333-1a ... gate, 334-1 ... source, 335-1 ... drain, 302 ... second electrostatic protection circuit, 310-2 ... second p-type transistor, 313-2a ... Gate, 314-2 ... Source, 315-2 ... Drain, 330-2 ... Second n-type transistor, 333-2a ... Gate, 334-2 ... Source, 335-2 ... Drain, VSS ... Low Potential power supply wiring, VDD: high potential power supply wiring, SL: signal wiring.

Claims (6)

An electrostatic protection circuit electrically connected to the first power supply wiring, the second power supply wiring, and the signal wiring,
The static electricity protection circuit includes a first static electricity protection circuit and a second static electricity protection circuit,
The first electrostatic protection circuit includes a first n-type transistor and a first p-type transistor,
The second electrostatic protection circuit includes at least one of a second n-type transistor and a second p-type transistor,
At least one of the first n-type transistor, the first p-type transistor, and the second n-type transistor and the second p-type transistor is connected to the gate at one of the source and the drain. And
A gate of the first n-type transistor is electrically connected to the first power supply wiring;
The other of the source and drain of the first n-type transistor is electrically connected to the signal wiring,
A gate of the first p-type transistor is electrically connected to the second power supply wiring;
The other of the source and drain of the first p-type transistor is electrically connected to the signal wiring,
In at least one of the second n-type transistor and the second p-type transistor, the other of the source and the drain is electrically connected to the first power supply wiring or the second power supply wiring. Features an electrostatic protection circuit. The second electrostatic protection circuit includes the second n-type transistor and the second p-type transistor,
The gate of the second n-type transistor and the other of the source and drain of the second p-type transistor are electrically connected to the first power supply line,
2. The gate of the second p-type transistor and the other of the source and drain of the second n-type transistor are electrically connected to the second power supply wiring. The electrostatic protection circuit described in 1.   The electrostatic protection circuit according to claim 1, wherein the second electrostatic protection circuit has a higher resistance than the first electrostatic protection circuit. The first n-type transistor and the second n-type transistor have substantially the same channel width;
The first p-type transistor and the second p-type transistor have substantially the same channel width;
The channel length of the second n-type transistor includes 120% of the channel length of the first n-type transistor, or is greater than the 120%,
4. The channel length of the second p-type transistor includes 120% of the channel length of the first p-type transistor or is larger than the 120%. The electrostatic protection circuit described in 1.   An electro-optical device comprising the electrostatic protection circuit according to claim 1.   An electronic apparatus comprising the electrostatic protection circuit according to claim 1 and / or the electro-optical device according to claim 5.

Images