KR100967354B1 - Touch panel for a multiplicity of input - Google Patents

Abstract

PURPOSE: A touch panel of complex input way is provided to configure capacitance type touch cell within the touch panel with a pressure type touch cell, thereby detecting all touch input irrelevant to a kind of touch unit and touch input method. CONSTITUTION: A capacitance type touch cell(31) comprises a capacity type switching device(40) of a three terminal type and a touch pad(50). A pressure type touch cell(70) comprises a first conductive pad(46) and a second conductive pad(48). A touch position detector(80) gets a local detection signal from a capacitance type third signal line(36) according to state change of the capacitance switching unit. A touch location detection unit receives a location detection signal from a pressure type second signal line(44) in conduction between a firs conductive pad and a second conductive pad.

Description

Touch panel for a multiplicity of input

The present invention relates to a touch panel, and more particularly, to generate a touch signal by complexly detecting a soft touch such as contact or non-contact of a body without a pressure touch caused by bending of the substrate and a bending of the substrate. The present invention relates to a touch panel having a new structure that can be recognized.

In general, the touch panel is attached to a display device such as a liquid crystal display (LCD), a plasma display panel (PDP), an organic light emitting diode (OLED), an active matrix organic light emitting diode (AMOLED), and a finger or a pen. It is one of the input devices to generate a signal corresponding to the position when the object of contact. Touch panels are used in a wide range of fields, such as small portable terminals, industrial terminals, and digital information devices (DIDs).

Conventional touch panels have been disclosed in various types, but a touch panel of a resistive type having a simple manufacturing process and a low manufacturing cost is most widely used.

1 shows an example of a resistive touch panel. Referring to FIG. 1, a first substrate 3 and a second substrate 5 are disposed to face each other on an upper surface of the display device 1, and an upper surface of the first substrate 3 and a lower surface of the second substrate 5. In each case, a transparent conductor such as indium tin oxide (ITO) is coated to form the conductive layers 7 and 9. A plurality of resistance points 11 are formed on the upper portion of the first substrate 3, and resistance points are formed on the lower portion of the second substrate 5, although not shown.

As illustrated, when an object such as the touch pen 17 contacts the second substrate 5, bending occurs on the second substrate 5 while the conductive layer 9 on the bottom surface of the second substrate 5 is removed. 1 is in contact with the conductive layer 7 on the upper surface of the substrate 3. At this time, the voltage applied to the conductive layers 7 and 9 drops due to the resistance value obtained at the corresponding resistance point 11, and the voltage detected by the change in the resistance value is converted into a digital signal through the AD converter 13. The converted signal is transmitted to the CPU 15 to obtain the coordinate value of the point where the touch is made. Such a resistive touch panel is the most widely used touch panel because of its simple manufacturing process and low cost.

However, in the resistive touch panel, the sheet resistance values of the transparent conductors applied to the conductive layers 7 and 9 should be uniform in order to detect the voltage difference according to the position. It is very difficult to satisfy such a condition, There is a problem that the process cost increases due to the strict control of the thickness. In addition, when the long time use, the conductive layer 9 of the second substrate 5 causes a gradual change in characteristics, such as a weak durability, thereby causing the damage of the conductive layer 9, there is a problem such as a position reading error occurs. .

Another problem of the resistance method is that two substrates 3 and 5 are used, and ITO or the like is applied over the entire area of each substrate 3 and 5. When two substrates 3 and 5 are used in this way and multilayer ITO is applied, the transmittance of the touch panel is lowered, which causes a decrease in display quality of the display device.

Furthermore, the conventional touch panel has a problem in that it cannot recognize a multi-touch in which a plurality of points are simultaneously touched on the panel. For example, in the case of writing with the back of a hand on a blackboard in the copyboard, or when a multi-touch occurs, such as writing in a multi-party at the same time on the copyboard, a problem occurs that the multi-touch is not recognized or the touch panel malfunctions. .

In addition, the conventional resistive touch panel requires an expensive AD converter 13 as a touch is detected as an analog signal, a time delay occurs in the signal processing, and zero adjustment is required for the resistance points. And the large display device 1 have various problems, such as being difficult to apply.

Conventionally, a touch panel of a capacitive type that generates a touch signal by detecting a light contact of a finger or a conductor among other types of touch panels is disclosed. 2 shows a conventional capacitive touch panel.

In the capacitive touch panel illustrated in FIG. 2, a transparent conductive film is formed on upper and lower surfaces of the transparent substrate 10 made of film, plastic, or glass, and a metal electrode for voltage application at each of four corners of the transparent substrate 10. (12) is formed. The transparent conductive film is formed of a transparent metal such as indium tin oxide (ITO) or antimony tin oxide (ATO). The metal electrodes 12 formed at four corners of the transparent conductive film are formed by printing a conductive metal having a low resistivity such as silver (Ag). A resistance network is formed around the metal electrodes 12. The resistance network is formed in a linearization pattern in order to transmit control signals evenly over the entire surface of the transparent conductive film. A protective film is coated on the transparent conductive film including the metal electrode 12.

In the capacitive touch panel as described above, when an alternating current voltage of high frequency is applied to the metal electrode 12, it is spread on the front surface of the transparent substrate 10. At this time, if you lightly touch the transparent conductive film on the upper surface of the transparent substrate 10 with the finger 16 or a conductive material, a certain amount of current is absorbed into the body and the current sensor built in the controller 14 detects the change of current and the four metals The amount of current in each of the electrodes 12 is calculated to recognize the touch point.

Since the capacitive touch panel has a soft touch method, its lifespan is long, and since only one transparent substrate 10 is used, the light transmittance is high. In particular, since the width of the non-operation area is narrow at the edge portion of the panel, the mechanism can be made slim when combined with the display device.

However, a non-conductor such as nails or gloves and a touch pen made of plastic have a disadvantage in that the touch position cannot be detected, and a malfunction is caused by noise such as external static electricity.

In addition, the capacitive touch panel as described above is a method of detecting a small current, and requires an expensive detection device. Furthermore, as in the resistance method, there is a problem in that zero adjustment is required and a problem in which a plurality of points are touched at the same time cannot be recognized.

The present invention has been proposed to solve the problems occurring in the conventional resistive touch panel and the capacitive touch panel, and is a soft touch input in which a body or a touch device having similar conductivity characteristics is lightly touched or approached. And it is configured to detect all of the pressure-type touch input pressing the second substrate with a touch means such as a touch pen or other non-conductor, that is, to obtain a touch signal without limitation on the type and touch input method of the touch means, Both the capacitive touch cell and the pressure touch cell are configured to acquire a touch signal using a digital position detection signal, so that the signal processing is quick and accurate, and there is no need for zero adjustment. Multi-touch can be recognized and signal line of display device when touch panel is installed on top of display device It is an object of the present invention to provide a touch panel of a new composite input method, which can prevent a moiré phenomenon in which a wave pattern appears due to interference between signal lines of the touch panel and the touch panel.

Composite input method touch panel of the present invention for achieving the above object, in the touch panel for detecting the contact or approach of the touch means including the body to generate a coordinate signal corresponding to the position, made of a light transmissive material A first substrate 30 and a second substrate 60 spaced apart from each other by the plurality of spacers 25; A plurality of capacitive first signal lines 32, capacitive second signal lines 34, and capacitive third signal lines disposed on the first substrate 30 or the second substrate 60 for inputting and outputting position detection signals; 36); The capacitive first signal line 32, the capacitive second signal line 34, and the capacitive agent are formed in a plurality of divided regions of the active region 100 where touch is applied on the touch panel. A three-terminal capacitive switching element 40 having a gate terminal and an input / output terminal connected to the three signal lines 36, and a touch pad 50 made of a conductor connected to the gate terminal of the capacitive switching element 40. One capacitive touch cell 31; A plurality of pressure type first signal lines 42 and pressure type second signal lines 44 disposed on the first substrate 30 or the second substrate 60 for inputting and outputting position detection signals; The first conductive pad 46 and the second conductive pad 48 are formed in a plurality of divided regions of the active region 100 where touch is formed on the touch panel, and are spaced apart from each other in the divided regions. When the first conductive pad 46 and the second conductive pad 48 are energized with each other, the pressure outputting the position detection signal obtained through the pressure type first signal line 42 to the pressure type second signal line 44. Type touch cell 70; And a position detection signal is applied to each of the capacitive first signal line 32 and the pressure first signal line 42, and the capacitive touch cell 31 has a capacitance according to a change of state of the capacitive switching element 40. The position detection signal is received from the third signal line 36, and the pressure-type second signal line is applied when the first conductive pad 46 and the second conductive pad 48 are energized in the pressure touch cell 70. And a touch position detector 80 that receives the position detection signal from 44 and obtains the coordinate value of the point where the touch is made.

According to an embodiment of the present invention, the capacitive touch cell 31 and the pressure touch cell 70 are formed in an area separated from each other in the active area 100.

According to another embodiment of the present invention, the capacitive touch cell 31 and the pressure touch cell 70 are formed in an overlapping area in the active area 100.

According to a preferred embodiment, the touch pad 50 of the capacitive touch cell 31 is cut in a predetermined area, at least one pressure touch to be spaced apart from the touch pad 50 in the cut area. A conductive pad of the cell 70 is formed.

According to an embodiment of the present invention, the touch panel is installed on the upper surface of the display device 20 in which the unit pixels are arranged in a matrix form, and the capacitive touch cell 31 is mounted on the unit pixel of the display device 20. The capacitive first signal line 32, the capacitive second signal line 34, and the capacitive third signal line 36 extend at an integer ratio compared to the signal lines of the display device 20. Wiring is done.

According to one embodiment of the invention, the touch panel is installed on the upper surface of the display device 20 in which the unit pixels are arranged in a matrix form, the pressure-type touch cell 70 and the unit pixel of the display device 20 The pressure first signal line 42 and the pressure second signal line 44 are arranged to have the same pitch as the signal line of the display device 20.

According to another embodiment of the present invention, the touch panel is installed on the upper surface of the display device 20 in which the unit pixels are arranged in a matrix form, and the pressure type touch cell 70 is mounted on the unit pixel of the display device 20. Compared to the signal line of the display device 20, the pressure-type first signal line 42 and the pressure-type second signal line 44 are wired at a pitch that is expanded at an integral ratio relative to the signal line of the display device 20.

According to an embodiment of the present invention, the touch panel is installed on an upper surface of the display device 20 in which unit pixels are arranged in a matrix form, and a diffusion sheet is disposed between the display device 20 and the first substrate 30. 90 is further installed.

According to an embodiment of the present invention, the touch panel is installed on the upper surface of the display device 20 in which the unit pixels are arranged in a matrix form, and the capacitive first signal line 32 and the capacitive second signal line 34 are disposed on the touch panel. The capacitive third signal line 36, the pressure first signal line 42, and the pressure second signal line 44 are each wired in an oblique direction with respect to the signal line of the display device.

According to an embodiment of the present invention, the touch position detector 80 further includes a memory means 85 having addresses corresponding to the coordinate values of the capacitive touch cell 31 and the pressure touch cell 70. When the position detection signal is received from the capacitive third signal line 36 and the pressure second signal line 44, the coordinate values of the corresponding touch cell are stored in the corresponding address of the memory means 85.

According to an embodiment of the present invention, the first conductive pad 46 and the second conductive pad 48 are spaced apart from each other on the same substrate, and the touch pad 50 of the capacitive touch cell 31 is touched. When pressure is applied to the touch panel by the means, the first conductive pad 46 and the second conductive pad 48 are disposed on opposing substrates so as to energize the two conductive pads.

According to an embodiment of the present invention, the first conductive pad 46 and the second conductive pad 48 are disposed on opposite substrates, and are energized while being in contact with each other when pressure is applied to the touch panel by the touch means. do.

According to an embodiment of the present invention, the first conductive pads 46 and the second conductive pads 48 are spaced apart from each other on the same substrate, and when the pressure is applied to the touch panel by the touch means on the opposite substrate, A transparent conductive layer 62 is formed in contact with the first conductive pad 46 and the second conductive pad 48 to conduct the two conductive pads.

According to a preferred embodiment, the transparent conductive layer 62 is formed by partitioning to cover at least one or more pressure-type touch cell 70 on any one substrate.

According to a more preferred embodiment, the first conductive pad 46 and the second conductive pad 48 are disposed in the same diagonal direction, the transparent conductive layer 62 is the first conductive pad 46 and the second conductive It is formed in the diagonal direction crossing the pad 48.

According to an embodiment of the present invention, the first conductive pad 46 and the second conductive pad 48 are spaced apart from each other on the same substrate, and the spacer 25 is formed of the first conductive pad 46 and the first conductive pad 46. One end is fixedly installed on the side of the substrate facing the substrate on which the two conductive pads 48 are formed, and the other end is spaced apart from the first conductive pads 46 and the second conductive pads 48, and is touched by the touch panel. And a conductive spacer 25c having a conductive layer 65 that contacts the first conductive pad 46 and the second conductive pad 48 to energize the two conductive pads when pressure is applied thereto.

According to a preferred embodiment, the first conductive pad 46 and the second conductive pad 48 are each formed in a concave-convex shape in which the concave portion 52 and the convex portion 54 are continuous, and each pressure-type touch cell ( In the 70, the first conductive pad 46 and the second conductive pad 48 are arranged such that the concave portion 52 and the convex portion 54 engage with each other.

According to an embodiment of the present invention, the pressure type touch cell 70 has a first conductive pad 46 connected to the pressure type first signal line 42, and a second conductivity type on the pressure type second signal line 44. The pad 48 is configured to be connected.

According to a preferred embodiment, the pressure touch cell 70 is provided between the pressure-type first signal line 42 and the first conductive pad 46 or the pressure-type second signal line 44 and the second conductive pad 48. It further comprises a pressure switching device 41 installed between).

According to a more preferred embodiment, a plurality of pressure auxiliary signal lines 49 are further disposed on the first substrate 30 or the second substrate 60, and the pressure switching element 41 is the pressure auxiliary signal line. A three-terminal switching element having a gate terminal connected to 49 is turned on / off by a signal applied through the pressure auxiliary signal line 49.

According to a preferred embodiment, the pressure type touch cell 70 is a pressure-type first switching element 41a and a pressure-type second installed between the pressure-type first signal line 42 and the first conductive pad 46. And a pressure-type second switching element 41b disposed between the signal line 44 and the second conductive pad 48.

According to a more preferred embodiment, a plurality of pressure auxiliary signal lines 49 are further disposed on the first substrate 30 or the second substrate 60, and the pressure-type first switching element 41a and the pressure-type first substrate 30 are further disposed. The two-switching element 41b is a three-terminal switching element having a gate terminal connected to the pressure auxiliary signal line 49 and turned on / off by a signal applied through the pressure auxiliary signal line 49.

According to an embodiment of the present invention, the capacitive touch cell 31 further includes a capacitive auxiliary switching element 40a installed between the capacitive first signal line 32 and the capacitive switching element 40. Include.

According to a preferred embodiment, a plurality of capacitive auxiliary signal lines 37 are further disposed on the first substrate 30 or the second substrate 60, and the capacitive auxiliary switching element 40a is the capacitive auxiliary signal line. A three-terminal switching element connected to a gate terminal at 37 is turned on / off by a signal applied through the capacitive auxiliary signal line 37.

According to a preferred embodiment, a plurality of capacitive first auxiliary signal lines 37a and capacitive second auxiliary signal lines 37b are further disposed on the first substrate 30 or the second substrate 60. The auxiliary switching device 40a is a three-terminal switching device in which a gate terminal is connected to the capacitive first auxiliary signal line 37a, and is turned on / off by a signal applied through the capacitive first auxiliary signal line 37a. A capacitor 55 is further connected between the gate terminal of the capacitive switching element 40 and the capacitive second auxiliary signal line 37b.

According to a more preferred embodiment, the first substrate 30 or the second substrate 60 is formed in the same manner as the capacitive touch cell 31, but the reference time measurement cell 120 without the touch pad is further formed. do.

According to a more preferred embodiment, the reference time measurement cell 120 is formed in a non active area of the first substrate 30 or the second substrate 60.

According to one embodiment of the present invention, only the capacitive touch cell 31 or the pressure touch cell 70 is installed in a portion of the active area 100.

According to an embodiment of the present invention, only the capacitive touch cell 31 is installed in a portion of the active area 100, and the capacitive touch cell 31 is disposed on the upper surface of the first substrate 30. The second substrate 60 is formed to face the region in which only the capacitive touch cell 31 is provided alone.

According to a preferred embodiment, the transparent insulating film is coated on the surface of the capacitive touch cell 31 in a region where only the capacitive touch cell 31 is installed alone.

According to one embodiment of the present invention, a plurality of pressure auxiliary signal lines 49 are further disposed on the first substrate 30 or the second substrate 60, and the pressure type touch cell 70 is the pressure type. It further includes a three-terminal pressure switching element 41 connected to the first signal line 42 and the second pressure-type signal line 44, respectively, the input terminal and the output terminal, each of the two in each pressure touch cell (70) One of the conductive pads 46 and 48 is connected to the gate terminal of the pressure switching element 41 and the other conductive pad is connected to the pressure auxiliary signal line 49.

According to a preferred embodiment, a signal blocking switching element 41c is further installed at any one of the three terminals of the pressure switching element 41.

According to a more preferred embodiment, a plurality of signal blocking gate signal lines 49c are further disposed on the first substrate 30 or the second substrate 60, and the signal blocking switching element 41c is the signal blocking member. As a three-terminal switching element in which a gate terminal is connected to the gate signal line 49c, the signal is turned on / off by a signal applied through the signal blocking gate signal line 49c.

According to the touch panel of the complex input method of the present invention, by configuring the capacitive touch cell and the pressure touch cell together in the touch panel, all touch inputs can be detected regardless of the type of touch means and the touch input method. Although the actual functions and functions are different, the manufacturing process of LCD and AMOLED is similar to that of TFT substrates, which have already been proven to be reliable and mass-produced. A more stable manufacturing process can be secured and high product reliability can be expected. By detecting the two different touch inputs using a digital signal, the signal processing is very fast and there is no need to go through the zero adjustment process. Drive ICs can be installed to make the product slim It can be made, and can be easily applied regardless of the type of application such as the display screen of a large display device and a portable device.

In addition, according to the present invention, since the capacitive touch cell and the pressure touch cell cover the overlapping area, both touch inputs can be effectively detected at any point on the active area.

Further, according to the present invention, by arranging each touch cell at a resolution corresponding to the unit pixel of the display device, not only can the touch panel be manufactured using a large portion of the manufacturing process of the display device but also a wave pattern due to interference of signal lines. It is effective to prevent the appearance of the moire phenomenon.

In addition, according to the present invention, by installing the diffusion sheet on the lower portion of the first substrate, there is an effect that can prevent the moiré phenomenon caused by the interference of the signal lines when the touch panel is installed on the upper surface of the display device.

In addition, according to the present invention, by arranging the signal lines in an oblique direction, the signal lines of the display device and the signal lines of the touch panel are alternated, thereby preventing the moiré phenomenon caused by the interference of the signal lines.

In addition, according to the present invention, in the construction of the pressure-sensitive touch cell by placing the first conductive pad and the second conductive pad on the mutually opposing substrate, and when the pressure-sensitive touch occurs, the two conductive pads are in contact with each other to conduct electricity, There is no need to separately configure a current supply means for energizing the touch cell, there is an effect that can greatly improve the transmittance of the touch panel.

In addition, according to the present invention, the transparent conductive layer is formed by partitioning to cover one or more pressure-type touch cells, thereby improving transmittance of the touch panel and electrically isolating each pressure-type touch cell to enable multi-touch recognition. It works.

In addition, according to the present invention, by forming the conductive pads and the transparent conductive layer of the pressure-sensitive touch cell in an oblique direction crossing each other, when the transparent conductive layer is formed to form a stable touch signal without having to precisely position the effect There is.

In addition, according to the present invention, the two conductive pads of the pressure type touch cell are energized by using a plurality of spacers for energizing, so that the thickness of the second substrate does not have to be made too thin, thereby greatly improving the durability of the second substrate. By electrically isolating the pressure touch cells, there is an effect capable of recognizing multi-touch.

In addition, according to the present invention, when the conductive spacer is used, the two conductive pads are disposed so as to be mutually meshed with each other in a tooth shape, so that the position of the conductive spacer does not need to be precisely arranged in the unit pressure type touch cell, and the number of the conductive spacers is used. This can greatly reduce the effect.

In addition, according to the present invention, by installing at least one pressure switching element in the pressure touch cell to prevent the reverse flow of the signal and electrically isolated each pressure touch cell, there is an effect that enables the recognition of multi-touch have.

In addition, according to the present invention, by installing a capacitive auxiliary switching element in the capacitive touch cell, there is an effect to prevent the interference between signals and to more stably recognize the multi-touch.

In addition, according to the present invention, by adding a capacitor in the capacitive touch cell, the capacitance of the capacitor is appropriately selected to adjust the output wave slope of the capacitive touch cell due to the charge sharing effect between the added capacitor and the virtual capacitor. It can be effective.

Further, according to the present invention, a touch signal is applied to the capacitive touch cell by forming a reference time measuring cell, which is configured in the same manner as the capacitive touch cell in the non-operation area on the substrate, excluding the touch pad. The absence of wiring resistance and parasitic capacitors can easily identify the waveform characteristics.

In addition, according to the present invention, only a capacitive touch cell or a pressure touch cell is installed alone in a part of the active area, so that the resolution of the touch cell can be partially increased, and in the case of the capacitive touch cell, the detection sensitivity can be increased. It works.

In addition, according to the present invention, when the pressure touch cell is configured to detect the pressure touch input in accordance with the change of the state of the pressure switching device, each pressure touch cell is electrically isolated using the switching device for signal blocking. By doing so, it is possible to more stably recognize the multi-touch.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings and embodiments.

First of all, the present invention relates to a touch panel that is installed in addition to the upper surface of a display device such as an LCD, a PDP, an OLED, an AMOLED, or used alone, and detects contact or approach of a finger or a touch means having a similar conductive property. Capacitive touch input (or soft touch input) for acquiring a touch signal, and pressure touch input for acquiring a touch signal when two substrates come into contact with each other by touch pressure of the touch means. The present invention relates to a touch panel of a complex input method capable of detecting and recognizing multi-touch. To this end, the composite input touch panel according to the present invention basically includes two touch cells of different types. One of the two types of touch cells is a capacitive touch cell consisting of a three-terminal switching element and a touch pad connected to the gate terminal of the switching element, and the other is a pressure touch cell consisting of two conductive pads spaced apart from each other. .

The capacitive touch cell is formed in a region in which a plurality of active areas where actual touch is made in the touch panel is divided, and each divided region has a three-terminal capacitive switching element and a gate of the capacitive switching element. Touch pads connected to the terminals are arranged to constitute a unit touch cell. The gate terminal, the source terminal (hereinafter referred to as "input terminal"), and the drain terminal (hereinafter referred to as "output terminal") of the capacitive switching element are connected to the capacitive first signal line, second signal line, and third signal line, respectively. When the state of the capacitive switching element is changed by a virtual capacitance generated when a finger or a touch device having similar conductivity characteristics to the touch pad is lightly touched or approached, the touch pad is sensed to obtain a touch signal.

The pressure type touch cell is also formed in a plurality of regions in which active touches are actually touched on the touch panel, and in each of the divided regions, a unit touch cell is formed by pairing a first conductive pad and a second conductive pad spaced apart from each other. Configure. The first conductive pad and the second conductive pad are connected to the pressure type first signal line and the second signal line, respectively. When the two substrates constituting the touch panel come into contact with each other by touch means such as a touch pen, the first conductive pad and the second conductive pad are energized with each other to obtain a touch signal.

In the present invention, two different types of touch cells have the basic structure as mentioned above. Hereinafter, the detailed configuration and various embodiments of each touch cell will be described in detail with reference to the drawings. On the other hand, in the embodiments described below, the switching element may be replaced with "TFT", and the same reference numerals are used for the switching element and the TFT.

Figure 3 is a perspective view showing the external structure of the touch panel according to the present invention. Referring to this, the touch panel of the present invention is installed on the upper surface of the display device 20, and the first and second substrates 30 and 60 are disposed to face each other. The first substrate 30 and the second substrate 60 are made of a light transmissive material such as transparent glass, film, plastic, and the like. The drive IC 81 is formed at an edge of the first substrate 30 or the second substrate 60. ) Is mounted in the form of Chip On Film (COF) or Chip On Glass (COG). Alternatively, the drive IC 81 may be mounted inside the panel with polysilicon (P-Si) using a low temperature polyprocess. The drive ICs 81 are ICs for applying and obtaining a position detection signal and a gate signal to signal lines described later. According to a preferred embodiment of the present invention, a diffusion sheet 90 is further provided between the display device 20 and the first substrate 30, which will be described later.

Meanwhile, in the embodiment of FIG. 3, the first substrate 30 and the second substrate 60 are illustrated on the upper surface of the display device 20, but the two substrates may be installed inside the display device 20. It may be. For example, in the case of LCD, the first substrate 30 and the second substrate 60 are laminated on a liquid crystal panel on which a TFT substrate and a color filter substrate are bonded, and then installed in a housing of a BLU (Back Light Unit). By doing so, the touch panel of the present invention may be embedded in the display device 20.

4 is a schematic view showing a basic configuration of the present invention. Referring to this, the capacitive touch cell 31 and the pressure touch cell 70 are arranged in a matrix in the active area 100 where actual touch is made on the touch panel. Although the illustrated example illustrates that the capacitive touch cell 31 is arranged at a resolution of 2 * 2 and the pressure touch cell 70 is arranged at a resolution of 4 * 4, this is merely to help understand the present invention. Only for illustrative purposes, each touch cell is actually arranged at a higher resolution.

The capacitive touch cell 31 and the pressure touch cell 70 may be formed in areas separated from each other in the active area. When the two touch cells 70 are separated and formed as described above, pads may be mounted in a larger area in forming each touch cell, and a process of connecting the pads to signal lines may be facilitated. This method can only detect the touch input selected from the pressure type touch input and the soft touch input at a predetermined point on the active area 100, but is very useful for the purpose of partitioning the area for the touch input.

In another embodiment, as illustrated in FIG. 4, the capacitive touch cell 31 and the pressure touch cell 70 are formed to overlap at least a portion of the active area. In FIG. 4, one capacitive touch cell 31 is formed in an area covering four pressure touch cells 70. As such, when the two touch cells 31 are formed in the overlapped area, two touch inputs can be effectively detected at any point on the active area 100. Of course, FIG. 4 is only one embodiment, and some capacitive touch cells 31 or pressure touch cells 70 are not as in the embodiment shown in FIG. 24 (the detailed description will be described later). The active area 100 may be installed independently.

First, the basic configuration of the capacitive touch cell 31 will be described with reference to FIG. 4.

A plurality of capacitive first signal lines 32, capacitive second signal lines 34, and capacitive third signal lines 36 are disposed on the first substrate 30 or the second substrate 60 for inputting and outputting position detection signals. do. In the illustrated example, the capacitive first signal line 32 is horizontally wired, and the capacitive second signal line 34 and the third signal line 36 are vertically wired. However, this is only one embodiment, The signal lines are wired on the substrate irrespective of their wiring directions such as longitudinal, transverse and oblique directions.

4 illustrates a basic structure of the capacitive touch cell 31, and each of the capacitive touch cells 31 includes at least one three-terminal capacitive switching element 40 and a touch pad 50. The capacitive switching element 40 is preferably a TFT, and in each capacitive touch cell 31, the capacitive TFT 40 is connected with a gate terminal to the capacitive first signal line 32 as shown, An input terminal and an output terminal are respectively connected to the capacitive second signal line 34 and the third signal line 36. A touch pad 50 made of a conductor is connected to the gate terminal of the capacitive TFT 40.

The gate terminal turns on / off the switching element by a virtual capacitance generated during contact or approach of a touch means having a body or similar conductive characteristics. More specifically, the touch position detector 80 applies a position detection signal to the capacitive first signal line 32 and the capacitive second signal line 34, and applies the position detection signal to the virtual capacitance generated by the touch pad 50. When the capacitive TFT 40 is turned on, the position detection signal is received from the capacitive third signal line 36 to detect the touch position. However, such a signal input / output method is only an embodiment of the present invention, and transmits and receives a position detection signal to one of the three capacitive signal lines 32, 34, and 36, and the other one of the capacitive signal lines. The gate signal may be applied to the gate terminal of the capacitive TFT 40 by a signal signal line, and the impedance signal may be applied to the input terminal or output terminal of the capacitive TFT 40 by another capacitive signal line.

5 clearly illustrates that a virtual capacitance is formed in the touch pad 50 of the capacitive touch cell 31. Referring to FIG. 5, if the finger 26 and the touch pad 50 have a distance d when the human finger 26 approaches the touch pad 50, the finger 26 is shown in the equivalent circuit on the right. And the capacitance C exists between the touch pad 50 and the touch pad 50. This is because the earth acts as a virtual ground. Usually, when the body contacts the conductor, there is a few tens of pF of capacitance with the earth as the virtual ground, and when the body approaches the conductor in a non-contact state, the number of dielectric constants e in between is approximately a few. The capacitance of pF can be present. Therefore, the capacitive TFT 40 can be turned on / off by using the capacitance characteristics of the body.

As an exemplary embodiment for detecting a soft touch with one capacitive TFT 40 as shown in FIG. 4, the capacitive first signal line 32 is provided to detect a voltage formed in a virtual capacitor formed in the touch pad 50. For example, it becomes high resistance and enlarges a discharge constant. However, more preferably, at least two capacitive TFTs are provided in each capacitive touch cell 31 to further stabilize the signal processing without making the capacitive first signal line 32 high resistance. This will be described later.

Next, a basic configuration of the pressure type touch cell 70 will be described with reference to FIG. 4.

A plurality of pressure type first signal lines 42 and pressure type second signal lines 44 for inputting and outputting position detection signals are disposed on the first substrate 30 or the second substrate 60. In the illustrated example, the pressure-type first signal line 42 is horizontally wired and the pressure-type second signal line 44 is vertically wired, but as with the capacitive signal lines, this is only one embodiment and each signal line They are wired on the substrate irrespective of the wiring direction such as the longitudinal direction, the transverse direction, the oblique direction and the like.

Unlike the capacitive touch cell 31, each of the pressure type touch cells 70 includes a first conductive pad 46 and a second conductive pad 48 arranged in pairs and spaced apart from each other. The first conductive pad 46 is connected to the pressure first signal line 42, and the second conductive pad 48 is connected to the pressure second signal line 44.

When the pressure type touch cell 70 is pressed by the second substrate 60 by the pressure touch of a touch means such as a touch pen, the pair of conductive pads 46 and 48 are energized and the touch signal is applied. Is configured to obtain. For example, the position detection signal originated from the drive IC 81 of the touch position detector 80 is applied to the pressure-type first signal line 42, and the two conductive pads 46 and 48 are applied to the specific pressure-type touch cell 70. When the energization of is generated is transmitted to the pressure-type second signal line (44). The touch position detector 80 reads a signal obtained by the pressure-type second signal line 44 to obtain a coordinate value of the pressure-type touch cell 70. Such a signal input / output method is just an embodiment of the present invention, and transmits and receives a position detection signal by one of the two pressure signal lines 42 and 44, and an impedance signal by the other pressure signal line. It can also be applied.

The touch panel according to the present invention includes a capacitive touch cell 31 and a pressure touch cell 70 having different input methods, but both input and output states of the position detection signal are high and low. The touch signal can be detected. This means that the signal control method of the two input methods is different from each other and the same control IC can be used, unlike a different type of controller. That is, in the present invention, as shown in FIG. 4, the drive IC 81 for transmitting and receiving a position detection signal to the capacitive touch cell 31 and the pressure touch cell 70 may be integrated into a single IC. .

More specifically, as shown in FIG. 4, the touch position detector 80 includes a drive IC 81 for transmitting and receiving a position detection signal, a timing controller 82 for generating a time division signal, and a timing controller 82. The signal processing unit 83 provides a time division position detection signal to the drive IC 81 side according to the clock provided by the signal processing unit, and processes the signal received from the drive IC 81 to read the touch position, and the capacitive touch cell 31. And a memory means 85 having addresses corresponding to the coordinate values of the pressure touch cell 70, respectively, but may include a power supply unit. The operation relationship of the touch position detector 80 will be described later together with the waveform diagram.

FIG. 6 is a plan view showing an example in which touch cells are disposed on a first substrate, and FIG. 7 is a cross-sectional view showing an embodiment of the present invention, and shows a layer structure of each touch cell 31, 70.

Referring to FIG. 6, the capacitive touch cell 31 is formed at a resolution of 2 * 2, and the pressure type touch cell 70 is formed at a resolution of 4 * 4 as in FIG. 4. As shown in FIG. 6, both touch cells 31 and 70 may be formed on the first substrate 30. As such, when both touch cells 31 and 70 are formed on the first substrate 30, the second substrate 60 is energized by the two conductive pads 46 and 48 of the pressure type touch cell 70. An energization means is installed. As will be described later, the transparent conductive layer 62 or the conductive spacer 25c is formed on the second substrate 60 so that the two conductive pads 46 and 48 can be energized.

In the embodiment of FIG. 6, the capacitive touch cell 31 and the pressure touch cell 70 are formed to cover overlapping areas, but the touch pad 50 and the pressure touch cell ( The two conductive pads 46 and 48 of 70 are formed so as not to overlap as shown for isolation. More specifically, referring to FIG. 6, a predetermined area is cut inside the touch pad 50 of the capacitive touch cell 31, and the pressure type touch cell 70 is spaced apart from the touch pad 50 in the cut area. It can be seen that two conductive pads 46 and 48 are formed. Of course, only one conductive pad of the pressure type touch cell 70 may be formed in the cutout region of the touch pad 50, and another conductive pad may be formed on the opposing substrate. According to such a configuration, while the capacitive touch cell 31 and the pressure touch cell 70 are formed together on the overlapped area of the first substrate 30, two touch inputs can be independently detected in the same area. have.

As the capacitive touch cell 31 and the pressure touch cell 70 cover the overlapped areas, when the pressure of the body or the conductive material occurs, it can be predicted that both the touch cells 31 and 70 react. . Therefore, if both value touch signals are detected, a method of processing them is required. As a solution for such a situation, for example, when both touch signals are detected at a certain point, there is a method of recognizing the touch signal of the high-pressure touch cell 31 as a valid touch input. That is, two types of touch inputs may be processed by giving priority to signals sensed by the pressure type touch cell 31.

On the other hand, in order for the capacitive touch input to be effective, the touch pad 50 of the capacitive touch cell 31 should have a width of several mm or more. Therefore, in the capacitive touch input, high-resolution touch input such as text or picture is difficult. On the other hand, the pressure-type touch cell 70 can not only touch input of a non-conductor such as a touch pen, gloves or nails, but can also place the pressure-type touch cell 70 at intervals of several hundred um to enable high-resolution touch input. . For example, the capacitive touch cell 31 has a unit touch cell of 8 mm * 8 mm, and the pressure touch cell 70 has a unit touch cell of 0.8 mm * 0.8 mm. Accordingly, 100 capacitive touch cells 70 may be included in one capacitive touch cell 31. That is, again, the example of FIG. 6 is merely an example to help understanding of the present invention, and in reality, the pressure-type touch cell 70 is disposed at a resolution 100 times higher than the resolution of the capacitive touch cell 31. Can be.

Referring to the cross-sectional view of FIG. 7, the first substrate 30 and the second substrate 60 are spaced apart by a plurality of spacers 25. The spacer 25 is made of an insulator, and is formed of a ball spacer 25a which is cloud-contacted between the first and second substrates 30 and 60, and is also made of an insulator, and one end is patterned and fixed to a substrate on either side. The other end includes a pattern spacer 25b that is in contact with or bonded to the opposing substrate. The ball spacer 25a is compressively deformed when bending occurs in the second substrate 60, and supports the periphery of the point where the substrate is bent. The pattern space 25b is fixed between the two substrates 30 and 60 and is provided at the boundary between the touch cells 31 and 70. As shown, the two spacers 25a and 25b can be used together.

7 shows that the capacitive touch cell 31 and the pressure touch cell 70 are formed together on the upper surface of the first substrate 30 as in FIG. 6. 7 shows an example in which a capacitive touch cell 31 is formed, and an example in which a pressure touch cell 70 is formed on a right side. As such, when both touch cells 31 and 70 are formed on any one substrate, an electrification means for energizing the two conductive pads 46 and 48 of the pressure type touch cell 70 is required for the opposing substrate. In the example of FIG. 7, the energizing means is a transparent conductive layer 62 formed on the lower surface of the second substrate 30.

In an embodiment different from FIG. 7, the two touch cells 31 and 70 may be formed on different substrates, in which case the touch pad 50 of the capacitive touch cell 31 is a pressure-type touch cell 70. The two conductive pads (46, 48) of the can act as an energization means for energizing. In addition, the two conductive pads 46 and 48 may be formed on different substrates to be energized by mutual contact. For example, two conductive pads 46 and 48 may be formed on opposite substrates, respectively, and may be formed by partitioning each of the pressure-sensitive touch cells 70. In this case, it will be very important to form the alignment of the conductive pads 46 and 48 so that the two conductive pads 46 and 48 can stably contact each other. As another example, one conductive pad is formed by partitioning every pressure touch cell 70, and the other conductive pad is formed over the entire surface of the opposing substrate (similar to that in which the transparent conductive layer is formed in FIG. 7). May be. In this case, it is possible to expect stable contact between the conductive pads without having to align the conductive pads in the correct position.

Although conceptually depicted in FIG. 4, preferably, the touch pad 50, the first conductive pad 46, and the second conductive pad 48 are formed on the first substrate 30 so as to overlap each signal line. . This is to form the area of the touch pad 50 and the two conductive pads 46 and 48 as wide as possible and to improve the transmittance.

6 and 7, in the capacitive switching element 40, the gate electrode 56 is connected to the capacitive first signal line 32, and the source electrode 57 is connected to the capacitive second signal line 34. The drain electrode 58 is connected to the capacitive third signal line 36. An active layer 28 overlapping the gate electrode 56 and forming a channel between the source electrode 57 and the drain electrode 58 is provided. The active layer 28 is formed so that the source electrode 57 and the drain electrode 58 overlap each other. An ohmic contact layer 29 for ohmic contact between the source electrode 57 and the drain electrode 58 is further formed on the active layer 28. The active layer 28 is formed of amorphous silicon (A-Si) or polysilicon (P-Si).

In this case, the gate insulating layer 45 is disposed on the gate electrode 56, and the insulating layer 47 is formed on the source electrode 57 and the drain electrode 58. The touch pad 50 and the two conductive pads 46 and 48 are formed using ITO, ATO, or Indium Zinc Oxide (IZO), Carbon Nano Tube, or the like. In addition, a connection point 39 of a contact process using ITO or the like is used to connect the touch pad 50 and the two conductive pads 46 and 48 to the signal lines. In the drawing, reference numeral 51 denotes a planarization layer 51 coated with an insulating material for planarization of the first substrate 30, which may not be used if necessary.

Although not shown, the capacitive TFT 40 may be provided with a layer for blocking light. The light blocking layer may be formed using a source metal or a gate metal. Forming a light blocking layer on the upper surface of the capacitive TFT 40 is to prevent the capacitive TFT 40 from malfunctioning in response to light. In the embodiments described below, a plurality of TFTs and the like are additionally used, and light blocking layers may be formed in all of these devices.

4 to 7 illustrate the basic configuration of the present invention. The operation relationship of the present invention by the basic configuration will be described below.

In the touch panel of the present invention, the two touch cells 31 and 70 have different input methods, and the reaction mechanism for recognizing the coordinates in response to the touch input from each touch cell 31 and 70 is also different. As described above, although the capacitive touch cell 31 and the pressure touch cell 70 operate separately, the drive IC 81 of the touch position detector 80 integrates and controls these signals. The signal lines of the capacitive touch cell 31 and the signal lines of the pressure touch cell 70 are disposed independently of each other, but the single drive IC 81 transmits and receives a position detection signal to each signal line. The signal lines of the capacitive touch cell 31 and the signal lines of the pressure touch cell 70 may be operated as signals that are individually asynchronous, but preferably as synchronized signals.

The touch position detector 80 provides a sequential scan pulse to each of the capacitive first signal line 32 and the pressure first signal line 42 through the drive IC 81. When scan pulses are supplied over the entire area of the touch panel, scan pulses are sequentially supplied to all signal lines after a short pause. The time taken to supply one cycle of the scan pulse to all the signal lines is approximately tens to hundreds of ms in one embodiment. Therefore, each unit touch cell 31, 70 receives a position detection signal at a very short period.

First, in each capacitive touch cell 31, the capacitive TFT 40 is turned on when a high voltage of the position detection signal is applied through the capacitive first signal line 32, and then the position detection signal is set low. When shut off, the capacitive TFT 40 is turned off. However, if a touch input for approaching the touch pad 50 with a finger in a capacitive touch cell 31 occurs, the virtual capacitor formed between the finger and the touch pad 50 is charged. Thereafter, when the position detection signal is blocked at the gate terminal of the capacitive TFT 40 and the high resistance state described above is reached, a discharge operation occurs in the virtual capacitor, and the turn-off time of the capacitive TFT 40 is delayed. Therefore, the touch position detector 80 measures the delay time of the signal output to the capacitive third signal line 36 to obtain a touch signal in the corresponding touch cell.

If the second substrate 60 is pressed by touch means such as a touch pen or a nail, the transparent conductive layer 62 on the bottom surface of the second substrate 60 is pressurized while the second substrate 60 is bent downward. The two conductive pads 46 and 48 of the type touch cell 70 will be energized with each other. In this case, the position detection signal applied through the pressure-type first signal line 42 is transmitted to the second conductive pad 48 through the first conductive pad 46, and is connected to the second conductive pad 48. It is supplied to the drive IC 81 along the two signal lines 44. Therefore, the touch position detector 80 reads the signal output to the pressure-type second signal line 44 to obtain a touch signal from the corresponding touch cell.

8 is a waveform diagram illustrating an example of recognizing a touch signal in the embodiment of FIG. 4, and FIG. 9 is a block diagram conceptually illustrating an embodiment of a memory unit in the present invention.

Referring to the waveform diagram of FIG. 8, the drive IC 81 applies a time-divided position detection signal of DC1 and DC2 to the capacitive first signal line 32, and also applies DP1, DP2, to the pressure first signal line 42. The time-divided position detection signals of DP3 and DP4 are applied. The period of the pulse applied to each of the pressure-type first signal lines 42 is "T1". The period of the pulse applied to each of the capacitive first signal lines 32 is " T2 " and includes the high period and the observation time after the high period of the pulse.

The addresses of the memory means 85 shown in the block diagram of FIG. 9 correspond to the positions of each touch cell 31, 70 in the embodiment of FIG. In FIG. 4, the capacitive touch cell 31 on the upper left side corresponds to the M1 address in the block diagram of FIG. 9, and the pressure type touch cell 70 on the upper left side corresponds to the M3 address in the block diagram of FIG. 9. In this way, in the block diagram of FIG. 9, M1, M2, M11, and M12 are addresses corresponding to respective positions of the capacitive touch cell 31 in the embodiment of FIG. 4, and M3 to M10 and M13 to M20 are pressure type. The addresses correspond to the respective positions of the touch cell 70.

If a body or a conductive object approaches and a soft touch input occurs in the capacitive touch cell 31 at the upper left in FIG. 4, that is, the capacitive touch cell 31 at a position corresponding to the M1 address, the capacitive touch cell 31 The turn-off of the capacitive TFT 40 is delayed due to the timing when the application of the position detection signal is terminated in the touch cell 31, that is, the charge accumulated by the capacitance at the point t3, and the gate voltage turns during the observation time. It is in the on state. The touch position detector 80 acquires a touch signal corresponding to the M1 point when the signal received through the capacitive third signal line 36 connected to the capacitive touch cell 31 is delayed as described above. The touch signal is transmitted to a CPU (not shown), and the obtained touch signal is stored in the M1 address of the memory means 85.

If the touch means (or touch by a part of the body) may be included, such as a touch pen, the pressure touch cell 70 at the lower right in FIG. 4, that is, the pressure touch cell at a position corresponding to the M20 address When the pressure type touch input is generated at 70, when the DP4 signal is applied to the pressure type first signal line 42, the position detection signal SP4 may be obtained through the pressure type second signal line 44 at a time t5 to t6. . The touch position detector 80 determines a timing of a signal received through the pressure-type second signal line 44 connected to the pressure-type touch cell 70 to obtain a touch signal corresponding to the M20 point. The touch signal is transmitted to the CPU, and the obtained touch signal is stored in the M20 address of the memory means 85.

On the other hand, as described above, when the soft touch input in the capacitive touch cell 31 and the pressure touch input in the pressure touch cell 70 occur together in the same area, the pressure touch input is selected as a valid signal. It is preferable to be. However, in some cases, two types of touch inputs detected in the same area may be given priority to the touch inputs in the capacitive touch cell 31, and both signals may be processed as valid signals. will be.

As described above, storing the obtained touch signal in the memory means 85 does not recognize the acquired touch signal when the state of the touch position detection unit 80 or the CPU is in the "Busy" state in the course of processing a large number of signals. This is because it can often happen. In order to prevent this, as shown in FIG. 9, the memory means 85 has an absolute address corresponding to the coordinate value of each of the capacitive touch cell 31 and the pressure touch cell 70. The touch position detector 80 transmits the acquired touch signal to the CPU and temporarily stores the touch signal at the designated address of the memory means 85. The touch position detection unit 80 scans the position detection signal once for the entire active area 100 and then calls up the memory means 85 to determine whether there is a lost signal during the rest period, and if there is a lost signal, reproduces it. .

The above embodiment has been described with respect to the basic configuration and operation of the present invention. By the way, the basic configuration as above is to wire the signal lines in the active region 100, the capacitive touch cell 31 and the pressure touch cell 70 are arranged in a matrix form, each TFT is installed in the touch cell, It has a structure similar to that of the display device 20 such as LCD or AMOLED. Therefore, it can be manufactured using the TFT substrate manufacturing process of the display device which has already been verified product reliability and mass production. However, when the touch panel of the present invention is installed on the upper surface of the display device, a moiré phenomenon may occur in which a wave pattern appears due to interference between the signal line of the display device 20 and the signal line of the touch panel.

The present invention provides several solutions for preventing this moiré phenomenon.

Each of the capacitive touch cell 31 and the pressure touch cell 70 is arranged in a matrix form in the same way that the unit pixels are arranged in a matrix form in the display device 20 such as an LCD. Accordingly, the size of the capacitive touch cell 31 and the pressure type touch cell 70 correspond to the unit pixel size of the display device 20 at an integer ratio, and the signal lines of the touch panel are connected to the signal lines (gate lines) of the display device 20. And a data line) and a virtual vertical line, the interference of signals between the signal lines can be greatly reduced.

While the unit pixels of the display device 20 are designed with very high resolution, as mentioned above, since the capacitive touch cell 31 has to have an area of the touch pad 50 several mm or more, the unit pixel resolution It must be arranged lower than. Therefore, the capacitive touch cell 31 is disposed at a resolution reduced by an integer ratio compared to the unit pixels of the display device 20, and the capacitive signal lines 32, 34, and 36 are disposed on the signal lines of the display device 20. In comparison, the wires are expanded at an integer ratio. Meanwhile, since the pressure touch cell 70 may be arranged at a very high resolution, the pressure touch cells 70 may be arranged in the same manner as the unit pixels of the display device 20, and the pressure signal lines 42 and 44 may be arranged in the display device 20. Can be wired at the same pitch as the signal line. Of course, the pressure type touch cell 70 is also arranged at a resolution reduced by an integer ratio compared to the unit pixels of the display device 20 as in the capacitive type, and the pressure signal lines 42 and 44 are arranged in the signal line of the display device 20. It can also be wired at an extended pitch compared to. For example, if the unit pixel applies the touch panel of the present invention to a 22-inch LCD having a resolution of 1366 * 768, the capacitive touch cell 31 is configured with a resolution of 136 * 76, and the pressure touch cell 70 is It can be arranged with a resolution of 1366 * 768. After the signal lines of the touch panel and the signal lines of the display device are wired according to the same rule, the touch panel and the display device are aligned such that both signal lines are positioned on the same vertical line, and thus, between the signal lines in the same direction between the display device and the touch panel. Moiré phenomenon due to interference can be prevented.

Another example of preventing moiré is to further install a diffusion sheet 90 between the second substrate 60 and the display device 20 as shown in FIG. As such, when the diffusion sheet 90 is disposed below the second substrate 60, the diffusion lines 90 do not have to be vertically aligned with the signal lines of the display device 20 and the signal lines of the touch panel. The moiré phenomenon can be prevented by this.

Another example of preventing the moiré phenomenon is not shown, but the capacitive first signal line 32, the capacitive second signal line 34, the capacitive third signal line 36, the pressure-type first signal line 42 and the pressure The second signal lines 44 are all wired diagonally. In the display device 20, signal lines such as gate lines and data lines are vertically and horizontally wired. Therefore, when the signal lines of the touch panel are wired in an oblique direction, the signal lines of the display device and the signal lines of the touch panel are staggered, so that signal interference is greatly reduced, thereby preventing the moiré phenomenon.

Hereinafter, various modified embodiments of the touch panel of the complex input method according to the present invention will be described.

Referring to FIG. 7, it is illustrated that the transparent conductive layer 62 is formed on the bottom surface of the second substrate 60 as the current carrying means for energizing the two conductive pads 46 and 48 of the pressure type touch cell 70. However, when the transparent conductive layer 62 is formed over the entire lower surface of the second substrate 60 as shown in FIG. 7, the transmittance of the touch panel may be lowered. Therefore, in order to improve transmittance of the touch panel, the transparent conductive layer 62 is preferably formed to cover at least one or more pressure-type touch cells 70. In this case, each of the transparent conductive layers 62 may be applied only to a minimum local area capable of energizing the two conductive pads 46 and 48 corresponding to each pressure-type touch cell 70. However, too locally forming the transparent conductive layer 62 may result in a more complicated manufacturing process of the touch panel. Accordingly, the touch panel of the present invention provides a method of forming the pressure type touch cell 70 and the transparent conductive layer 62 while simplifying the manufacturing process.

10 to 12 show examples in which the transparent conductive layer is formed in the present invention. The capacitive touch cell 31 is disposed at a resolution of 4 * 4, and 2 * 2 of each capacitive touch cell 31 is disposed. Illustrates that the pressure type touch cell 70 is disposed at a resolution. 10 to 12 are all for showing the configuration of the pressure-type touch cell 70 in the present invention, the capacitive touch cell 31 is not shown for each configuration, only the region is shown in a grid pattern. In addition, the pressure type touch cell 70 conceptually illustrates two conductive pads 46 and 48 and a transparent conductive layer 62 is formed thereon.

Referring to FIG. 10, two conductive pads 46 and 48 of the pressure touch cell 70 are disposed in the same diagonal direction, and the transparent conductive layer 62 is in a diagonal direction crossing the two conductive pads 46 and 48. Is formed. When the pressure type touch cell 70 and the transparent conductive layer 62 are configured as described above, a region in which the transparent conductive layer 62 is formed can be greatly reduced. In addition, it is possible to safely ensure that the two conductive pads 46 and 48 are energized by the transparent conductive layer 62 without precisely positioning the transparent conductive layer 62. In addition, it is not only easy to arrange the pressure signal lines diagonally, but also has the advantage of preventing the moiré phenomenon.

Referring to FIG. 11, it can be seen that the diagonal lines of the transparent conductive layer 62 partitioned in the diagonal direction are partially cut off. Cutting the diagonal transparent conductive layer 62 in this manner can be carried out in a simple process, it is possible to partition the pressure-type touch cell 70 by region.

Furthermore, referring to the embodiment shown in FIG. 12, it can be seen that the transparent conductive layer 62 is partitioned by unit touch cell. When the transparent conductive layer 62 is partitioned for each unit touch cell as described above, although the manufacturing process may be more complicated, the transmittance of the touch panel is greatly improved. First of all, it is possible to obtain an effect of completely insulating each of the pressure-sensitive touch cells 70 electrically. Therefore, the touch input in each of the pressure-type touch cells 70 can be processed independently, which ultimately enables multi-touch.

Meanwhile, as mentioned above, the two conductive pads 46 and 48 of the pressure touch cell 70 are formed on different substrates, and when the bending occurs in the substrate, the two conductive pads 46 and 48 contact each other. It may be configured to be energized. In this embodiment, only one conductive pad is formed in each pressure-type touch cell 70 on the first substrate 30, and the other conductive pad is formed on the second substrate 60 in FIGS. 10 to 12. It may be formed as (62).

According to a preferred embodiment of the present invention, the first substrate 30 is composed of a glass substrate. It wires the signal lines using the manufacturing process of the display device 20 as it is, installs the capacitive switching element 40, the touch pad 50, and the two conductive pads 46 and 48, and connects the signal lines to the respective pads. It is because the process to make it easy. If all the components are mounted on the first substrate 30 as in the above-described embodiment, since only the transparent conductive layer 62 is formed on the second substrate 60, the film is excellent in flexibility because there is no burden on component mounting. It may be made of a material. However, the film substrate has a problem in that the surface strength is weak and the scratch is easily caused by a sharp object such as a pen. When the glass substrate is selected as the second substrate 60, it is difficult to secure flexibility. If the glass substrate is made too thin, the flexibility is improved, but the weakness of the impact is caused.

The embodiment of FIG. 13 shows an example for solving the above problem. That is, when the glass substrate is selected as the second substrate 60, the two conductive pads 46 and 48 can be stably energized in the pressure touch cell 70 without making the thickness of the glass substrate too thin. To provide.

Referring to the cross-sectional view of FIG. 13, other configurations are the same as the cross-sectional view of FIG. 7, but it can be seen that a transparent conductive layer is not formed on the lower surface of the second substrate 60. Instead of this, a plurality of spacers 25c for electricity transmission are installed on the lower surface of the second substrate 60. As shown in the drawing, the conductive spacer 25c is patterned such that one end is fixed to the bottom surface of the second substrate 60. The other end of the conductive spacer 25c is coated with ITO to form a conductive layer 65, which is spaced apart from the two conductive pads 46 and 48 in each pressure-sensitive touch cell 70. It is deployed. More preferably, a plurality of power supply spacers 25c are provided in correspondence with the unit pressure type touch cell 70.

FIG. 14 illustrates a case in which a pressure touch input occurs on the second substrate 60 in the embodiment of FIG. 13. Referring to this, when the second substrate 60 is pressed by the finger 26 as shown, bending occurs in the second substrate 60. At this time, the conductive layer 65 at the end of the conductive spacer 25c is Both conductive pads 46 and 48 are energized. Accordingly, even when the second substrate 60 is gently curved, the two conductive pads 46 and 48 of the pressure type touch cell 70 can be stably energized. This means that when the glass substrate is used as the second substrate 60, the glass substrate does not need to be too thinly polished or etched.

As such, when the two conductive pads 46 and 48 of the pressure touch cell 70 are energized by using the conductive spacer 25c, the installation position of the conductive spacers 25c serves as a very important factor. However, the embodiment of FIG. 15 shows a structure of energizing the two conductive pads 46 and 48 more stably without applying the spacer 25c for precisely applying the embodiment of FIG. 13. In the embodiment shown in FIG. 15, the first conductive pad 46 and the second conductive pad 48 are each formed in a concave-convex shape in which the concave portion 52 and the convex portion 54 are continuous. The first conductive pads 46 and the second conductive pads 48 in each of the pressure-type touch cells 70 are engaged with each other while keeping the recess 52 and the convex portion 54 spaced apart from each other by a predetermined interval. Is placed. Accordingly, as shown in FIG. 2, the conductive spacers 25c may be stably energized between the two conductive pads 46 and 48 even if the spacer 25c is disposed on any of the upper portions of the two conductive pads 46 and 48.

In the above embodiments, the energizing means for energizing the two conductive pads 46 and 48 of the pressure touch cell 70 has been described. Referring to the cross-sectional view of FIG. 7, an example in which the transparent conductive layer 62 is formed over the entire lower surface of the second substrate 60 to energize the two conductive pads 46 and 48, is described with reference to FIGS. 10 to 12. An example in which the transparent conductive layer 62 is formed by partitioning the pressure-sensitive touch cells 70 and an example in which the two conductive pads 46 and 48 and the transparent conductive layer 62 cross each other are arranged in diagonal directions. 13 to 15, an example in which two conductive pads 46 and 48 are energized by using a spacer 25c for conducting electricity instead of forming a transparent conductive layer on the second substrate 60 is described.

These embodiments are merely one embodiment of the present invention, and the touch panel of the present invention may energize the two conductive pads 46 and 48 of the pressure touch cell 70 in a different manner. For example, although not shown, the capacitive touch cell 31 may be installed on the first substrate 30, and the pressure type touch cell 70 may be installed on the second substrate 60. Thus, while installing the two touch cells 31 on the mutually opposing substrate, the touch pad 50 of the capacitive touch cell 31 energizes the two conductive pads 46 and 48 of the pressure touch cell 70. In this case, the two conductive pads 46 and 48 of the pressure touch cell 70 can be energized with respect to the pressure touch input without using the transparent conductive layer 62 and the conductive spacer 25c as described above. As another example, the pressure-type first signal line 42 and the first conductive pad 46 are formed on the first substrate 30, and the pressure-type second signal line 44 and the second conductivity are formed on the second substrate 60. After the pad 48 is formed, the first conductive pad 46 and the second conductive pad 48 may be energized while being in contact with each other when a pressure type touch input occurs. As such, the two conductive pads 46 and 48 of the pressure touch cell 70 may be energized by various energization means with respect to the pressure touch input.

Next, embodiments of recognizing multi-touch using the touch panel of the present invention will be described.

The touch panel of the present invention includes a capacitive touch cell 31 and a pressure touch cell 70 of different input methods. At this time, the capacitive touch cell 31 is provided with a capacitive switching element 40, by using the capacitive switching element 40 can block the input and output of signals in each touch cell, which is a capacitive touch cell It is possible to recognize the multi-touch in (31). However, the basic structure of the pressure type touch cell 70 is difficult to recognize the multi-touch. For example, when the transparent conductive layer 62 is formed over the entire area of the lower surface of the second substrate 60, when the touch input is made at the pressure touch cells 70 at several points at the same time, the transparent conductive layer 62 may be used for various purposes. As the pressure type touch cells 70 are electrically connected, an error occurs in acquiring the touch signal. Among the above embodiments, the transparent conductive layer 62 is divided into unit pressure-type touch cells 70 and the example of energizing the pressure-type touch cell 70 using the spacer 25c for conducting the above error. Multi-touch recognition is possible without However, in some environments (for example, when a touch panel is applied to a small display device such as a mobile phone LCD screen), the transparent conductive layer 62 may be formed by partitioning the pressure-sensitive touch cell 70, or the electricity supply spacer 25c may be used. It can be difficult to install. Accordingly, the present invention provides a method for more stable multi-touch recognition in the pressure type touch cell 70.

Referring to FIG. 16, in comparison with the configuration of FIG. 4, each of the pressure type touch cells 70 is a pressure switching element 41 disposed between the pressure type second signal line 44 and the second conductive pad 48. It further includes. The pressure switching element 41 is to switch the connection of the pressure signal line and any one of the conductive pads in each pressure touch cell 70, unlike the embodiment of FIG. 16, each pressure touch cell 70 It may be provided between the pressure-type first signal line 42 and the first conductive pad 46. In addition, a pressure-type first switching element 41a is provided between the pressure-type first signal line 42 and the first conductive pad 46, and between the pressure-type second signal line 44 and the second conductive pad 48. A plurality of pressure switching elements 41 may be used as in the case where the pressure type second switching elements 41b are provided.

Various switching elements may be used as the pressure switching element 41. For example, a diode It can be configured to prevent the position detection signal from flowing backward. However, more preferably, the pressure switching element 41 is a three-terminal switching element such as a TFT. Such a three-terminal switching device can be turned on / off using a pulse applied to the gate terminal, thereby stably preventing backflow and blocking of the signal. In addition, the TFT has the advantage that the device has already been verified in the manufacturing of the display device 20 such as LCD and AMOLED.

In the embodiment shown in FIG. 16, the pressure TFT 41 has an input terminal connected to the second conductive pad 48 in each pressure touch cell 70 and an output terminal connected to the pressure second signal line 44. Self-connecting. A plurality of pressure auxiliary signal lines 49 are further disposed on the first substrate 30, and the gate terminal of the pressure TFT 41 is connected to the pressure auxiliary signal lines 49. The pressure auxiliary signal line 49 is connected to the drive IC 81 and controlled by the drive IC 81. The drive IC 81 sequentially applies a scan pulse to each of the pressure auxiliary signal lines 49.

According to this configuration, when the gate signal applied to the pressure auxiliary signal line 49 is Off, energization occurs between the first conductive pad 46 and the second conductive pad 48 in the pressure touch cell 70. Also, the position detection signal may not be shipped through the pressure-type second signal line 44. That is, the pressure type touch input can be effectively recognized only when the gate signal applied through the pressure type auxiliary signal line 49 is turned on. Therefore, by controlling the turn on / off of the pressure type TFT 41 in each pressure type touch cell 70, the multi-touch can be recognized.

FIG. 17 shows an embodiment in which the structure of the capacitive touch cell 31 is reinforced in the embodiment of FIG. 16. In FIG. 16, since the capacitive touch cells 31 in the lateral direction are all connected to the common capacitive first signal line 32, the touch pads 50 in the lateral direction are also the common capacitive first signal line ( 32). In this structure, when a touch input occurs in one capacitive touch cell 31, the capacitive touch cell 31 may affect other capacitive touch cells 31 connected to the common capacitive first signal line 32. This phenomenon may be solved by separately installing the capacitive first signal line for each capacitive unit touch cell 31. However, this method has a problem in that the transmittance of the substrate is lowered due to the increase in the capacitive first signal line. Thus, a more reliable solution is to disconnect the touch pad 50 of the capacitive touch cell 31 from the common capacitive first signal line 32, and FIG. 17 shows this embodiment.

Referring to FIG. 17, in addition to the embodiment of FIG. 16, a capacitive auxiliary switching device 40a is connected between the capacitive first signal line 32 and the gate terminal of the capacitive TFT 40. When the TFT is used as the capacitive auxiliary switching device 40a, since it has a RDS (on) resistance of about 10 Mohm, the signals between the touch pads 50 are blocked, and the RDS (on) resistance is used when soft touch occurs. It serves to determine the discharge constant of the voltage formed in the virtual capacitor between the touch pad 50 and the body. The capacitive auxiliary switching element 40a may be composed of various switching elements like the pressure switching element 41, but is preferably composed of a three-terminal switching element such as a TFT.

The capacitive auxiliary TFT 40a has an input terminal connected to the capacitive first signal line 32 in each capacitive touch cell 31 and an output terminal connected to the gate terminal of the capacitive TFT 40. A plurality of capacitive auxiliary signal lines 37 are further disposed on the first substrate 30, and the gate terminal of the capacitive auxiliary TFT 40a is connected to the added capacitive auxiliary signal line 37. The capacitive auxiliary signal line 37 is also connected to the drive IC 81 and controlled by the drive IC 81. The drive IC 81 may sequentially apply scan pulses to each of the capacitive auxiliary signal lines 37 and may apply a turn-on voltage at all times.

As a preferred embodiment in such a configuration, when the gate signal applied to the capacitive auxiliary signal line 37 is turned off, the capacitive auxiliary TFT 40a is turned off, and at this point, the pressure type touch signal is detected, and When the gate signal applied to the auxiliary signal line 49 is turned off, the pressure switching element 41 is turned off, and at this point, the capacitive touch signal is detected. Therefore, since the detection time of the capacitive touch cell 31 and the detection time of the pressure type touch cell 70 are different from each other, it is possible to stably prevent the influence of each other.

 18 is a waveform diagram illustrating an example of recognizing a touch signal in the embodiment of FIG. 17. An operation relationship according to the embodiment of FIG. 17 will be described with reference to the following.

In the section table shown in the lower part of FIG. 18, "area 1" is an area for detecting whether the pressure touch cell 70 is touched, and "area 2" is for detecting whether the capacitive touch cell 31 is touched. It is an area for. "Area 3" and "Area 4" are repetition sections of Area 1 and Area 2, respectively. In addition, each signal shown in the waveform diagram will be described. A signal applied to the capacitive first signal line 32 is DCn, a signal applied to the capacitive second signal line 34 is AUXn, and a capacitive third signal. The signal supplied to the signal line 36 is SCn, the gate signal applied to the capacitive auxiliary signal line 37 is GCn, the signal applied to the pressure first signal line 42 is DPn, and the pressure second signal line 44 is The acquired signal is SPn and the gate signal applied to the pressure auxiliary signal line 49 is GPn.

In Fig. 18, when the signal of the area 2 for detecting the capacitive touch input is advanced, it is preferable that the signal of the area 1 for detecting the pressure type touch input is not given. That is, the signal DPn applied to the pressure-type first signal line 42 in the region 2 and the region 4 should be high impedance or floating. In FIG. 18, the pressure-type first signal line in the region 2 and the region 4 The signal DPn applied to 42 is shown as being a low signal, but this is a high impedance or floating section. This is because when the DPn is still applied in the area 2, a pressure type touch input is generated, and when a detection voltage corresponding to the pressure type touch input is applied to the transparent conductive layer 62 of the second substrate 60, the electric field thus formed is generated. This is because the capacitance between the touch pad 50 and the body is difficult to form.

Similarly, in the region 1 which is the pressure type touch input detection section, it is preferable that the touch pad 50 of the capacitive touch cell 31 is high impedance or floated. In the region 1, the detection voltage is applied to the transparent conductive layer 62 of the second substrate 60 by the pressure type touch input. If the capacitive touch cell 31 operates, the transparent conductive layer 62 and the capacitance are applied. This is because the touch pad 50 of the type touch cell 31 may be in contact with each other, resulting in over current due to a short. That is, by blocking the input and output of the signal of the capacitive touch cell 31 in the region 1, even if the contact between the transparent conductive layer 62 and the touch pad 50 of the second substrate 60 occurs, no current consumption occurs. The noise of DPn, which is a detection voltage of the pressure type touch input, can be reduced and operated with a stable signal. As shown in FIG. 1, when the GCn used as the gate voltage of the capacitive auxiliary TFT 40a is turned off in the region 1, the DCn and the capacitive second signal line applied to the capacitive first signal line 32 in the region 1 are therefore turned off. Regardless of the state of AUXn applied to 34, the touch pad 50 of the capacitive touch cells 31 is determined to be in a high impedance state.

Referring to FIG. 18, the touch position detector 80 sequentially applies a scan pulse to the pressure auxiliary signal line 49 and the pressure first signal line 42 in the region 1 and the region 3, which are the detection sections of the pressure type touch input. to provide. As shown, when the gate signal of any one of the plurality of gate signals GPn is turned on, the remaining gate signals remain in the off state. If the GP3 signal is turned on, all of the other gate signals GP1, GP2, and GP4 remain off. When the GP3 signal is turned on, the TFT On voltage is supplied to the gate terminal of the pressure TFT 41 connected to the third pressure auxiliary signal line 49. The TFT Off voltage is supplied to the gate terminal of the pressure TFT 41 connected to the other pressure auxiliary signal line 49. As an example, the TFT On voltage of GPn is 12-18V, and the TFT Off voltage is -5-10V. In addition, the DPn applied to the pressure-type first signal line 42 for the stable switching operation of the pressure-type TFT 41 is lower than the threshold voltage of the TFT by more than the GPn corresponding to the gate signal of the pressure-type TFT 41. Use voltage. As an example, 5V is used as DPn.

Referring to FIG. 18, the touch position detector 80 sequentially applies a scan pulse to each of the capacitive auxiliary signal line 37 and the capacitive first signal line 32 in areas 2 and 4, which are detection sections of the capacitive touch input. to provide. As shown, the gate signal GCn may be applied to several capacitive auxiliary signal lines 37 simultaneously. However, in order to prevent mutual interference of SCn, which is a signal output from the capacitive touch cell 31, when one DCn is applied, the other DCn maintains the Off state regardless of the gate signal GCn. For example, when DC1 is applied, DC2 remains Off even when GC2 is applied, thereby causing the capacitive TFT 40 connected to DC2 to be in the Off state. As an example, the TFT On voltage of GCn is 12-18V, and the TFT Off voltage is -5-10V. DCn, which is the input signal of the capacitive auxiliary TFT 40a, is preferably lower than the threshold voltage of the TFT than the gate voltage GCn. For example, 12V is used as DCn. The signal AUXn applied to the capacitive second signal line 34 as an input signal of the capacitive TFT 40 is preferably lower than the threshold voltage of the TFT by DCn, which is the gate voltage of the capacitive TFT 40, for example, AUXn. 5V is used.

As shown, after the On voltage of the gate signal GCn applied to the capacitive touch cell 31 is applied to detect the capacitive touch input, there is sufficient observation time between successive signals. This is to allow sufficient time to measure the signal discharged from the virtual capacitor formed by the finger 26 and the touch pad 50 by the approach of the body.

It is desirable to have a pause between each signal for the processing of stable signals and to prevent overlapping of the signals.

A process of obtaining a touch signal from the capacitive touch cell 31 in the embodiment of FIG. 17 will be described with reference to the waveform diagram of FIG. 18 as follows.

In SCn, which is the output waveform of the capacitive touch cell 31, since the wiring resistance and the parasitic capacitor exist in the capacitive third signal line 36 to which the signal is obtained, the section rising to the Hi level and Low as shown in the figure. You will have a curve in the section that descends to the level. If touch between the body and the touch pad 50 does not occur, the gate voltage of the capacitive TFT 40 is drastically lowered immediately after the signal transmission is completed by GCn and changed to the observation time, and the SCn is lowered to 50% level. Let's call it "T1". However, in this waveform diagram, the time delay generated in the output signal SCn and the transient response characteristics at the time of touch with the body are ignored in comparison with the gate signal GCn and the input signals DCn and AUXn.

If a touch input occurs to the body's approach to the upper left capacitive touch cell 31 of FIG. 17 at a certain point in time, the capacitive touch cell 31 at the corresponding point may have a finger 26 and a touch pad 50 of the body. The capacitance is formed in between. As shown in the waveform diagram of FIG. 18, if a touch has occurred at the time of the region 2, the discharge of the voltage charged by the capacitance will be started in the observation time mode of the region 2, that is, at the time when DC1 becomes the low level. . Accordingly, the gate voltage of the capacitive TFT 40 gradually decreases, and the output waveform of the capacitive TFT 40 exhibits a unique waveform reflecting the threshold voltage characteristic of the TFT as shown by the waveform of SC1. At this time, if the time taken until the waveform of SC1 falls to the 50% level is "T2", this T2 is considerably larger than T1.

Therefore, the touch position detector 80 reads the time taken for the waveform of SCn, which is a signal obtained through the capacitive third signal line 36, to fall to a predetermined level at the observation time, or the magnitude of the voltage dropped at a predetermined time point. A touch signal can be obtained.

A timer may be used to measure T2, which is a falling time delayed by the capacitance formed between the finger 26 and the touch pad 50 of the body, and a reference voltage may be used to read the magnitude of the voltage dropped at a predetermined time. Reference voltage may be used. The reference voltage may be generated by a power supply unit (not shown) installed in the touch position detection unit 80. The rising time or falling time, which is a unique output waveform of SCn when the capacitive touch input does not occur, may be used as a reference time of the timer.

However, the reference time of the above timer may be changed due to the wiring resistance of the signal lines or the parasitic capacitors, and may be changed by the coupling state of the touch panel and the display device 20. That is, the reference time of the timer may vary depending on the manufacturing state of the touch panel. This means that much time and effort is required to accurately measure the reference time and there is a chance that it will be measured incorrectly from time to time.

19 shows an embodiment for solving the above problem. 19 illustrates a frame 110 of a hand held device such as a mobile phone, and the touch panel of the present invention is mounted below the frame 11. As shown, a plurality of reference time measurement cells 120 may be formed in the touch panel coupled to the lower portion of the frame 110 of the mobile device, and FIG. 19 shows that the reference time measurement cells 120 formed in the touch panel It is a form projected onto the frame 11. The reference time measurement cell 120 is preferably formed on a non active area of the first substrate 30 or the second substrate 60, but may also be formed on the active area. In addition, the reference time measurement cell 120 has the same structure as the capacitive touch cell 31, but the touch pad 50 is configured to exclude the response to the touch. The reference time measurement cell 120 is to determine the waveform characteristics due to the difference in the presence and size of the wiring resistance and the parasitic capacitor in the capacitive touch cell 31. That is, the reference time measurement cell 120 is for capturing waveform characteristics of the capacitive touch cell 31 in which the touch pad 50 does not participate in signal detection, and touches the reference time measurement cell 120. The pad 50 is omitted.

The reference time measurement cell 120 is used as follows. The reference time measurement cell 120 has the same structure as the capacitive touch cell 31 (except the touch pad), and a method of acquiring a touch signal from the capacitive touch cell 31 in the manufacturing process of the touch panel. In the same manner, a signal is applied to the reference time measurement cell 120 and the signal output from the reference time measurement cell 120 is read. Then, T1 shown in the waveform diagram of FIG. 18 is measured from the signal output from the reference time measurement cell 120. The measured T1 is used to detect the touch input at the capacitive touch cell 31.

Referring to the example of FIG. 19, the reference time measurement cell 120 is installed in each of the touch panel regions below the points P1, P2, and P3 on the frame 110 of the mobile device. The reference time measured by the reference time measurement cell 120 at the point P1 is used as a reference time for obtaining a touch signal of the capacitive touch cell 31 located in the area A. Similarly, the reference time at the points P2 and P3 is used. The measurement cell 120 provides a reference time for acquiring touch signals of the capacitive touch cells 31 located in the B area and the C area, respectively. The reference time measured at each point P1, P2, or P3 may vary due to differences in wiring resistance or parasitic capacitors. Therefore, the detection sensitivity of the capacitive touch input can be increased by using the plurality of reference time measurement cells 120 as described above. The more places of installation of the reference time measurement cell 120, the higher the detection sensitivity of the capacitive touch input will be.

Meanwhile, in addition to the example described with reference to the waveform diagram of FIG. 18, it is possible to obtain a touch signal from the capacitive touch cell 31 in other ways. For example, all the capacitive TFTs 40 in a state where all of the signals DPn applied to the pressure touch cell 70 are turned off at a certain time, that is, in a state in which all operations of the pressure touch cell 70 are turned off. At the same time, the gate signal GCn is turned on simultaneously, and a charge is induced to a virtual capacitor formed between the body and the touch pad 50 at an arbitrary point, and then a signal is sequentially applied to the capacitive second signal line 34 to generate the capacitance. The waveform output from the third signal line 36 is observed. In addition, those skilled in the art will be able to detect the capacitive touch input in various ways using the technical idea of the present invention.

FIG. 20 shows an example in which the pressure touch cell 70 is configured differently than the embodiment of FIG. 17. In the embodiment of FIG. 20, a pressure TFT 41 is provided between the pressure-type first signal line 42 and the first conductive pad 46 in each pressure-type touch cell 70. The gate terminal of the pressure TFT 41 is connected to the pressure auxiliary signal line 49, and the input terminal and the output terminal are connected to the pressure first signal line 42 and the first conductive pad 46, respectively. As such, when the pressure TFT 41 switches the connection between the pressure-type first signal line 42 and the first conductive pad 46, the pressure-type TFT 41 is applied to any one of the pressure-type first signal line 42 by static electricity or disturbance. It is possible to prevent the signal from affecting other pressure-type first signal lines 42.

However, the embodiment of FIG. 20 selectively switches the connection of the pressure-type first signal line 42 in each pressure-type touch cell 70, and at the time of energization, the position detection signal of the second substrate is changed to a transparent conductor ( Since it may be applied to the second conductive pad 48 of the arbitrary pressure type touch cell 70 through 62, it is difficult to recognize the multi-touch.

21 illustrates a possible embodiment of stable multi-touch recognition by more completely isolating each of the pressure-sensitive touch cells 70 despite the presence of the transparent conductive layer 62. Referring to FIG. 21, each pressure touch cell 70 includes two pressure switching elements 41. A pressure-type first switching element 41a is provided between the pressure-type first signal line 42 and the first conductive pad 46, and a pressure is provided between the pressure-type second signal line 44 and the second conductive pad 48. The second switching element 41b is provided. Preferably, the pressure type first switching element 41a and the pressure type second switching element 41b are both composed of TFTs, and the gate terminals of both TFTs are commonly connected to the pressure auxiliary signal line 49.

In this configuration, when the gate signal applied to the pressure auxiliary signal line 49 is turned off, the pressure touch cells 70 of the line are completely isolated from the signal lines. Therefore, it is possible to completely prevent the signal from flowing backward through the conductive pads 46 and 48 in contact with the transparent conductive layer 62, and to prevent the malfunction in the pressure-type first signal line 42 due to static electricity or disturbance. have. However, in the embodiment of FIG. 21, the burden of installing two TFTs for each pressure type touch cell 70 is generated.

FIG. 22 shows an example in which the capacitive touch cell 31 is configured differently than FIG. 17. Referring to FIG. 22, in addition to the embodiment of FIG. 17, a plurality of capacitive first auxiliary signal lines 37a and a capacitive second auxiliary signal line 37b are disposed on the first substrate 30. A capacitive auxiliary switching element 40a is provided in each capacitive touch cell 31, and the capacitive auxiliary switching element 40a is composed of TFTs as in the embodiment of FIG. The capacitive auxiliary TFT 40a has an input terminal connected to the capacitive first signal line 32, an output terminal connected to a gate terminal of the capacitive TFT 40, and a gate terminal connected to the capacitive first auxiliary signal line 37a. Is connected.

In addition to this configuration, the embodiment of FIG. 22 further includes a capacitor 55 in each capacitive touch cell 31. As illustrated, a capacitor 55 is further connected between the gate terminal of the capacitive switching element 40 and the capacitive second auxiliary signal line 37b in each capacitive touch cell 31.

FIG. 23 is a waveform diagram illustrating an example of recognizing a touch signal in the embodiment of FIG. 22. The waveform diagram of FIG. 23 is similar to the waveform diagram of FIG. 18, and the operation and waveform of acquiring the touch signal in the pressure type touch cell 70 are the same as those of FIG. 18. Accordingly, a basic description of the operation of the pressure type touch cell 70 is omitted in the waveform diagram of FIG. 23.

As an embodiment of capacitive touch signal acquisition, the On voltage of GCn is 18V, and the Hi level potential of DCn is about 12V as a voltage for turning on the capacitive TFT 40. The capacitive second auxiliary signal line AUX2-n connected to the other end of the capacitor 55 is a signal line for observation and may have a zero potential in one embodiment.

In the embodiment of FIG. 22, an additional capacitor 55 is further installed in each capacitive touch cell 31 as compared to the embodiment of FIG. 17. This additional capacitor 55, in conjunction with a virtual capacitor formed between the body and the touch pad 50, serves to delay the time it takes for the waveform of the SCn signal to fall. If no capacitive touch input occurs, as in the SC1 signal in the region 4, the waveform of the signal output to the capacitive third signal line 36 falls to the falling time of T1. If the finger 26 approaches one of the capacitive touch cells 31, a virtual capacitor is formed between the body and the touch pad 50, which is added to the capacitor 55 as in the SC1 signal in area 2. ) And extend the falling time to T2. Accordingly, the touch position detector 80 may detect the time difference between T1 and T2 to obtain a touch signal.

Meanwhile, the embodiment of FIG. 22 may obtain a touch signal from the capacitive touch cell 31 in another manner. For example, before the touch input occurs, the charging of the capacitor 55 is completed in advance. As such, after the charging of the capacitor 55 is completed, when a soft touch input occurs, the charge charged in the capacitor 55 is charged sharing with the virtual capacitor, and the falling time is equal to T1 as in the SC2 signal of the region 4. It can be seen that it has a reduced T4. That is, in the method of detecting the touch input after precharging the capacitor 55, the time taken for the output waveform of SCn to fall by charge sharing is shorter than the reference time, and the touch position detector 80 is the T1 and T4. The touch difference may be obtained by detecting a time difference of.

As described above, the embodiment of FIG. 22 may adjust the voltage applied to the gate side of the capacitive TFT 40 by variously adjusting the capacitance of the additional capacitor 55. Therefore, by appropriately selecting the capacitance of the capacitor 55, the falling slope of the SCn signal can be selected when the touch is made, which makes it possible to more stably detect the capacitive touch.

24 shows an example in which some capacitive touch cells 31 are installed alone. Referring to FIG. 24, three capacitive touch cells 31 disposed below are not formed to overlap with the pressure type touch cell 70, but may be formed in an independent area. As such, when the capacitive touch cell 31 is formed alone, the second substrate 60 may be partially removed at the corresponding position. This is because the capacitive touch cell 31 detects a soft touch input such as contact or approach of a body, and all components can be installed on one substrate. As such, when the second substrate 60 is removed from the region where only the capacitive touch cell 31 is formed, the distance d between the finger 26 and the touch pad 50 becomes small, which increases the sensitivity of the capacitive touch signal. Have an effect. In this case, however, it is necessary to protect the capacitive touch cell 31 by applying a transparent insulator to the surface of the capacitive touch cell 31.

However, if the capacitive touch cell 31 is installed on the second substrate 60, it is not necessary to remove the first substrate 30 in the region where only the capacitive touch cell 31 is formed in FIG. Since the touch cell 31 is formed on the lower surface of the second substrate 60, it is not necessary to apply a transparent insulator to the capacitive touch cell 31. Nevertheless, it will have an effect of increasing the sensitivity of the capacitive touch signal by reducing the distance d between the finger 26 and the touch pad 50 as above.

Meanwhile, unlike the embodiment of FIG. 24, only the pressure type touch cells 70 may be installed in some regions on the touch panel. As such, in the region where only the pressure type touch cell 70 is installed, the correlation with the touch pad 50 may not be considered in the process of forming the two conductive pads 46 and 48. Thus, the pressure touch cells 70 can be integrated at high resolution.

That is, the touch panel of the present invention increases the touch sensitivity of the capacitive touch cell 31, or when a high resolution touch input is partially required on the touch panel. Alternatively, the pressure-sensitive touch cell 70 may be formed in a modified form.

25 and below show examples in which the pressure touch cell 70 is configured differently, and a method of detecting a touch input from the pressure touch cell 70 by a state change of the pressure switching element 41. Show the configurations. These embodiments show a slight difference in circuit configuration and operating mechanism compared to the configuration of the pressure touch cell 70 mentioned above.

Referring to FIG. 25, a plurality of pressure auxiliary signal lines 49 are further disposed on the first substrate 30. The pressure touch cell 70 further includes a three-terminal pressure switching element 41 connected to an input terminal and an output terminal, respectively, to the pressure first signal line 42 and the pressure second signal line 44. Within each pressure touch cell 70, one of the two conductive pads 46 and 48 is connected to the gate terminal of the pressure switching element 41, and the other conductive pad is connected to the pressure auxiliary signal line 49. ) In the illustrated example, the first conductive pad 46 is connected to the gate terminal of the pressure switching element 41, and the second conductive pad 48 is connected to the pressure auxiliary signal line 49. The pressure switching element 41 in this embodiment is preferably a TFT.

In the above embodiment, the pressure auxiliary signal line 49 is a scan signal line for turning on / off the pressure TFT 41, and an on voltage is applied to a signal line for detecting a touch signal, and an off voltage is applied to other signal lines. At this time, the always-off voltage applied to the pressure auxiliary signal line 49 is -5 to -10V and the turn-on voltage is, for example, 12 to 18V.

According to this configuration, if a touch input occurs in any pressure touch cell 70 while all the pressure TFTs 41 are turned off, a time point at which a scan pulse is applied to the pressure touch cell 70 is applied. The pressure TFT 41 is turned on. The position detection signal applied to the pressure type first signal line 42 is output to the pressure type second signal line 44 by the pressure type TFT 41. The touch position detector 80 detects this to obtain a touch signal.

26 to 28 show a configuration in which the signal blocking switching element 41c is further installed in addition to the embodiment of FIG. 25, and illustrates only a circuit configuration of the unit pressure type touch cell 70 for better understanding.

The signal blocking switching element 41c may be composed of a diode or the like, similarly to the switching elements for preventing and blocking the reverse flow of the aforementioned signal, but is preferably composed of a TFT. As shown in the drawing, the switching element 41c for signal blocking is provided at any one of three terminals of the pressure type TFT 41 in each pressure type touch cell 70. A plurality of signal blocking gate signal lines 49c are further disposed on the first substrate 30 to turn on / off the signal blocking switching element 41c.

FIG. 26 shows that the signal blocking TFT 41c is provided in the gate terminal of the pressure type TFT 41. The gate terminal is connected to the signal blocking gate signal line 49c, and the second conductive pad 48 and the pressure TFT are shown in FIG. In this embodiment, the input terminal and the output terminal are connected to the gate terminal of (41), respectively. FIG. 27 shows that the signal blocking TFT 41c is provided at the input terminal of the pressure type TFT 41, the gate terminal is connected to the signal blocking gate signal line 49c, and the pressure type first signal line 42 and the pressure type. In this embodiment, the input terminal and the output terminal are connected to the input terminal of the TFT 41, respectively. Fig. 28 shows that the signal blocking TFT 41c is provided at the output terminal of the pressure type TFT 41, the gate terminal is connected to the signal blocking gate signal line 49c, and the output terminal and the pressure of the pressure type TFT 41 are connected. In the second signal line 44, an input terminal and an output terminal are respectively connected to each other.

In the embodiments shown in FIGS. 26 to 28, the signal blocking TFT 41c, which is added in addition, blocks the flow of signals in each pressure touch cell 70 to prevent signal interference, and each pressure touch cell 70. ) Can be energized only when desired. Accordingly, the multi-touch input is stable in the pressure type touch cell 70.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the technical field of the present invention without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

1 is a cross-sectional view showing a conventional resistive touch panel

2 is a perspective view illustrating a conventional capacitive touch panel

3 is an exploded perspective view showing the appearance of the touch panel according to the present invention;

4 is a schematic view showing a basic configuration of the present invention

5 is a diagram conceptually representing a method using the body's capacitance

6 is a plan view showing an example in which a touch cell is disposed on a first substrate;

Figure 7 is a cross-sectional view showing an embodiment of the present invention

8 is a waveform diagram illustrating an example of recognizing a touch signal in the embodiment of FIG. 4.

9 is a block diagram conceptually showing one embodiment of a memory means;

10 is a plan view showing an example in which the transparent conductive layer is formed by partitioning

11 is a plan view showing another example in which the transparent conductive layer is formed by partitioning

12 is a plan view showing another example in which the transparent conductive layer is formed by partitioning

13 is a cross-sectional view showing an example in which the spacer for power transmission in the present invention is applied

14 is a cross-sectional view showing a state in which the second substrate is pressed in the embodiment of FIG.

15 is a plan view showing a configuration example of two conductive pads of a pressure touch cell;

16 is a schematic view showing another example of a pressure touch cell;

17 is a configuration diagram schematically showing another example of a capacitive touch cell

18 is a waveform diagram illustrating an example of recognizing a touch signal in the embodiment of FIG. 17.

19 is a front view showing an example of a reference time measurement cell

20 is a configuration diagram illustrating an example in which the pressure touch cell is different from the embodiment of FIG. 17.

FIG. 21 is a view illustrating an example in which the pressure touch cell is different from the embodiment of FIG. 17.

FIG. 22 is a diagram illustrating an example in which a capacitive touch cell is configured differently from the embodiment of FIG. 17; FIG.

FIG. 23 is a waveform diagram illustrating an example of recognizing a touch signal in the embodiment of FIG. 22.

24 is a configuration diagram showing an example in which only a capacitive touch cell is installed alone in some areas;

25 is a configuration diagram showing another example of a pressure type touch cell

FIG. 26 is a view illustrating an example in which the pressure touch cell is different from the embodiment of FIG. 25.

FIG. 27 is a diagram illustrating an example in which the pressure touch cell is different from the embodiment of FIG. 25.

FIG. 28 is a view illustrating an example in which the pressure touch cell is different from the embodiment of FIG. 25;

<Explanation of symbols for the main parts of the drawings>

20: display device 25: spacer

25a: Ball spacer 25b: Pattern spacer

25c: power supply spacer 26: finger

28: active layer 29: ohmic contact layer

30: first substrate 32: capacitive first signal line

34: capacitive second signal line 36: capacitive third signal line

37: capacitive auxiliary signal line 37a: capacitive first auxiliary signal line

37b: capacitive second auxiliary signal line 39: connection point

40: capacitive switching element 40a: capacitive auxiliary switching element

41: pressure switching element 41a: pressure type first switching element

41b: second pressure switching device 41c: switching device for signal blocking

42: pressure-type first signal line 44: pressure-type second signal line

45: gate insulating film 46: first conductive pad

47: insulating film 48: second conductive pad

49: pressure auxiliary signal line 49c: signal blocking gate signal line

50: touch pad 51: planarization layer

52: concave portion 54: convex portion

55 capacitor 56 gate electrode

57: source electrode 58: drain electrode

60: second substrate 62: transparent conductive layer

65: conductive layer 70: pressure touch cell

80: touch position detector 81: drive IC

82: timing controller 83: signal processor

85: memory means 90: diffusion sheet

100: active area 120: reference time measurement cell

Claims (33)

In the touch panel for detecting the contact or approach of the touch means including the body to generate a coordinate signal corresponding to the corresponding position, A first substrate 30 and a second substrate 60 made of a light transmissive material and spaced apart from each other by the plurality of spacers 25; A plurality of capacitive first signal lines 32, capacitive second signal lines 34, and capacitive third signal lines disposed on the first substrate 30 or the second substrate 60 for inputting and outputting position detection signals; 36); The capacitive first signal line 32, the capacitive second signal line 34, and the capacitive agent are formed in a plurality of divided regions of the active region 100 where touch is applied on the touch panel. A three-terminal capacitive switching element 40 having a gate terminal and an input / output terminal connected to the three signal lines 36, and a touch pad 50 made of a conductor connected to the gate terminal of the capacitive switching element 40. One capacitive touch cell 31; A plurality of pressure type first signal lines 42 and pressure type second signal lines 44 disposed on the first substrate 30 or the second substrate 60 for inputting and outputting position detection signals; The first conductive pad 46 and the second conductive pad 48 are formed in a plurality of divided regions of the active region 100 where touch is formed on the touch panel, and are spaced apart from each other in the divided regions. When the first conductive pad 46 and the second conductive pad 48 are energized with each other, the pressure outputting the position detection signal obtained through the pressure type first signal line 42 to the pressure type second signal line 44. Type touch cell 70; And A position detection signal is applied to each of the capacitive first signal line 32 and the pressure first signal line 42, and the capacitive touch cell 31 is capacitive according to a change of state of the capacitive switching element 40. The position detection signal is obtained from the third signal line 36, and the pressure-type second signal line 44 is applied when the pressure-sensitive touch cell 70 is energized between the first conductive pad 46 and the second conductive pad 48. And a touch position detector (80) for receiving a position detection signal from the touch panel and obtaining a coordinate value of the touched point. The method of claim 1, The capacitive touch cell 31 and the pressure type touch cell 70 are formed in a region separated from each other in the active region 100, the touch panel of the composite input method. The method of claim 1, The capacitive touch cell 31 and the pressure touch cell 70 are formed in the overlapping area in the active area 100, characterized in that the touch panel of the composite input method. The method of claim 3, wherein The touch pad 50 of the capacitive touch cell 31 is cut in a predetermined area, and at least one of the pressure-type touch cells 70 is spaced apart from the touch pad 50 in the cut area. Composite input method touch panel, characterized in that the pad is formed. The method of claim 1, The touch panel is installed on an upper surface of the display device 20 in which unit pixels are arranged in a matrix form, and the capacitive touch cell 31 is disposed at a reduced resolution compared to the unit pixels of the display device 20. The capacitive first signal line 32, the capacitive second signal line 34, and the capacitive third signal line 36 are wired at a pitch that is extended in an integer ratio relative to the signal line of the display device 20. Composite input touch panel. The method of claim 1, The touch panel is installed on an upper surface of the display device 20 in which the unit pixels are arranged in a matrix form, and the pressure type touch cell 70 is disposed at the same resolution as the unit pixel of the display device 20. The first input signal line 42 and the second pressure-type signal line 44 are wired to have the same pitch as the signal line of the display device 20. The method of claim 1, The touch panel is installed on the upper surface of the display device 20 in which the unit pixels are arranged in a matrix form, and the pressure type touch cell 70 is disposed at a reduced resolution compared to the unit pixels of the display device 20. And the pressure-type first signal line (42) and the pressure-type second signal line (44) are wired at an extended pitch with an integer ratio compared to the signal lines of the display device (20). The method of claim 1, The touch panel is installed on an upper surface of the display device 20 in which unit pixels are arranged in a matrix form, and a diffusion sheet 90 is further provided between the display device 20 and the first substrate 30. Composite input method touch panel. The method of claim 1, The touch panel is disposed on an upper surface of the display device 20 in which unit pixels are arranged in a matrix form, and the capacitive first signal line 32, the capacitive second signal line 34, and the capacitive third signal line 36 are disposed on the upper surface of the display device 20. And the pressure-type first signal line 42 and the pressure-type second signal line 44 are each wired in an oblique direction with respect to the signal line of the display device. The method of claim 1, The touch position detector 80 further includes a memory means 85 having addresses corresponding to coordinate values of the capacitive touch cell 31 and the pressure touch cell 70, wherein the capacitive third signal line ( 36) and when the position detection signal is received from the pressure-type second signal line 44, the coordinate value of the corresponding touch cell is stored in the corresponding address of the memory means (85). The method of claim 1, The first conductive pad 46 and the second conductive pad 48 are spaced apart from each other on the same substrate, and the touch pad 50 of the capacitive touch cell 31 is applied with pressure to the touch panel by touch means. And the first conductive pad 46 and the second conductive pad 48 are disposed on opposing substrates so as to energize the two conductive pads. The method of claim 1, The first conductive pad 46 and the second conductive pad 48 are disposed on mutually opposing substrates, and are energized while being in contact with each other when pressure is applied to the touch panel by the touch means. Touch panel. The method of claim 1, The first conductive pads 46 and the second conductive pads 48 are spaced apart from each other on the same substrate, and the first conductive pads 46 and the first conductive pads 46 and the second conductive pads 48 are pressed when the pressure is applied to the touch panel by the touch means. 2. A touch panel of a complex input method, characterized in that a transparent conductive layer 62 is formed in contact with the conductive pads 48 to conduct two conductive pads. The method of claim 13, The transparent conductive layer (62) is a complex input method of the touch panel, characterized in that formed on the substrate to cover at least one or more of the pressure-sensitive touch cell (70). 15. The method of claim 14, The first conductive pad 46 and the second conductive pad 48 are disposed in the same diagonal direction, and the transparent conductive layer 62 intersects the first conductive pad 46 and the second conductive pad 48. Composite input method touch panel characterized in that formed in an oblique direction. The method of claim 1, The first conductive pad 46 and the second conductive pad 48 are spaced apart from each other on the same substrate, and the spacer 25 is a substrate on which the first conductive pad 46 and the second conductive pad 48 are formed. One end is fixedly installed on the side of the substrate facing the other side, and the other end is spaced apart from the first conductive pad 46 and the second conductive pad 48, but when the pressure is applied to the touch panel by the touch means, the first conductive pad And a conductive input spacer (25c) having a conductive layer (65) in contact with the second conductive pad (48) and the second conductive pad (48). The method of claim 16, The first conductive pad 46 and the second conductive pad 48 are each formed in a concave-convex shape in which the concave portion 52 and the convex portion 54 are continuous. The conductive pad 46 and the second conductive pad 48 are disposed so that the mutual concave portion 52 and the convex portion 54 are engaged with each other. The method of claim 1, The pressure touch cell 70 is configured such that the first conductive pad 46 is connected to the pressure first signal line 42 and the second conductive pad 48 is connected to the pressure second signal line 44. A composite input method touch panel. The method of claim 18, The pressure touch cell 70 is a pressure installed between the pressure-type first signal line 42 and the first conductive pad 46 or between the pressure-type second signal line 44 and the second conductive pad 48. The touch panel of the complex input method further comprises a switching device (41). The method of claim 19, A plurality of pressure auxiliary signal lines 49 are further disposed on the first substrate 30 or the second substrate 60, and the pressure switching element 41 has a gate terminal connected to the pressure auxiliary signal lines 49. A three-terminal switching element to be connected, which is turned on / off by a signal applied through a pressure auxiliary signal line (49). The method of claim 18, The pressure type touch cell 70 includes a pressure type first switching element 41a and a pressure type second signal line 44 provided between the pressure type first signal line 42 and the first conductive pad 46. The touch panel of the composite input method further comprises a pressure-type second switching element (41b) provided between the two conductive pads (48). The method of claim 21, A plurality of pressure auxiliary signal lines 49 are further disposed on the first substrate 30 or the second substrate 60, and the pressure type first switching element 41a and the pressure type second switching element 41b are And a three-terminal switching element having a gate terminal connected to the pressure auxiliary signal line (49), which is turned on / off by a signal applied through the pressure auxiliary signal line (49). The method of claim 1, The capacitive touch cell 31 further includes a capacitive auxiliary switching element 40a disposed between the capacitive first signal line 32 and the capacitive switching element 40. Touch panel. 24. The method of claim 23, A plurality of capacitive auxiliary signal lines 37 are further disposed on the first substrate 30 or the second substrate 60, and the capacitive auxiliary switching element 40a has a gate terminal on the capacitive auxiliary signal line 37. The three-terminal switching device is connected to the touch panel of the complex input method, characterized in that turned on / off by a signal applied through the capacitive auxiliary signal line (37). 24. The method of claim 23, A plurality of capacitive first auxiliary signal lines 37a and capacitive second auxiliary signal lines 37b are further disposed on the first substrate 30 or the second substrate 60, and the capacitive auxiliary switching element 40a is provided. Is a three-terminal switching device having a gate terminal connected to the capacitive first auxiliary signal line 37a, and is turned on / off by a signal applied through the capacitive first auxiliary signal line 37a. And a capacitor (55) is further connected between the gate terminal of (40) and the capacitive second auxiliary signal line (37b). The method according to any one of claims 23 to 25, The first and second substrates 30 and 60 are configured in the same manner as the capacitive touch cell 31, but the reference input time measuring cell 120 excluding the touch pad is further provided. Touch panel. The method of claim 26, The reference time measuring cell 120 is a composite input touch panel, characterized in that formed in a non active area (non active area) of the first substrate (30) or the second substrate (60). The method of claim 1, The touch panel of the complex input method, wherein only the capacitive touch cell 31 or the pressure touch cell 70 is installed in a portion of the active area 100. The method of claim 1, Only the capacitive touch cell 31 is installed alone in a portion of the active area 100, and the capacitive touch cell 31 is formed on an upper surface of the first substrate 30, and the capacitive touch cell ( 31) The touch panel of the complex input method, wherein the second substrate 60 facing the area provided solely is removed. The method of claim 29, Touch panel of the composite input method, characterized in that the transparent insulating film is coated on the surface of the capacitive touch cell 31 in a region where only the capacitive touch cell 31 is installed alone. The method of claim 1, A plurality of pressure auxiliary signal lines 49 may be further disposed on the first substrate 30 or the second substrate 60, and the pressure type touch cell 70 may include the pressure type first signal line 42 and the pressure type. The second signal line 44 further includes a three-terminal pressure switching element 41 connected to an input terminal and an output terminal, respectively, and includes any one of two conductive pads 46 and 48 within each pressure-type touch cell 70. One touch pad is connected to the gate terminal of the pressure switching element (41) and the other conductive pad is connected to the pressure auxiliary signal line (49). The method of claim 31, wherein The touch panel of the composite input method, characterized in that the signal blocking switching device (41c) is further installed at any one of the three terminals of the pressure switching device (41). 33. The method of claim 32, A plurality of signal blocking gate signal lines 49c are further disposed on the first substrate 30 or the second substrate 60, and the signal blocking switching elements 41c are disposed on the signal blocking gate signal lines 49c. A three-terminal switching device to which a gate terminal is connected, the touch panel of a complex input method, which is turned on / off by a signal applied through a signal blocking gate signal line (49c).

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