WO2018101385A1 - Electronic device - Google Patents

Abstract

Provided is an electronic device capable of suppressing erroneous detection in an organic EL element panel having a touch sensor function. The electronic device includes: a flexible printed circuit; and a plurality of organic EL element panels, each having a touch sensor function. A first wiring, which is connected to a touch detection electrode of a first organic EL element panel, and a touch detection electrode of a second organic EL element panel do not have portions overlapping with each other in the lamination direction of the flexible printed circuit.

Description

Electronics

The present invention relates to an electronic device including an organic electroluminescence element panel with a touch sensor connected to a flexible printed circuit (FPC).

Recently, as a planar light source body, an LED (light emitting diode) using a light guide plate and an organic electroluminescence (EL) element (Organic light emitting diode; OLED) have been attracting attention. The light guide plate LED is used not only for general illumination but also for various scenes and applications such as a backlight for LCD (liquid crystal display).

Also, the planar light source body is applied to various electronic devices. For example, since around 2008, the production volume of smart devices (smartphones, tablets) has increased, and light guide plate LEDs are mainly used as backlights for main displays (LCD). In addition to the main display, a light guide plate LED is often incorporated as a backlight for a common function key button at the bottom of the device. Common function key buttons are mainly used in three types: home (displayed with a square mark, etc.), back (displayed with an arrow mark, etc.), and search (displayed with a magnifying glass mark, etc.) (for example, patent documents). 1).

The common function key button generally prints the pattern of the mark to be displayed on the cover glass, installs the light guide plate LED above the cover glass, causes the LED to emit light according to the required scene, By guiding light through a light guide plate (film), light is extracted to the display side through a dot-shaped diffusion member printed on the pattern portion.

On the other hand, for further thinning and low power consumption of electronic devices such as smart devices, it is proposed to apply an organic electroluminescence (EL) element panel (OLED panel) having a touch sensor function to a common function key button. (For example, refer to Patent Document 2). Usually, in a smart device or the like, an OLED panel is mounted on a flexible printed circuit (FPC). An expensive material such as polyimide is used for the FPC in order to ensure reliability. Further, since the space for incorporating the OLED panel is limited, it is necessary to minimize the FPC. Accordingly, in the FPC, the wiring is laid out immediately below or in the vicinity of the OLED panel.

US Patent Application Publication No. 2008/0259037 International Publication No. 2015/182001

However, in an OLED panel having a touch sensor function, sensing for detection of the touch sensor is performed using an anode or a cathode of an organic EL element. For this reason, in the configuration in which various wirings of the FPC are laid out in the vicinity of the OLED panel, touch detection is performed when noise is generated between each electrode of the organic EL element and the various wirings of the FPC laid out in the vicinity of the OLED panel. A false positive occurs.

In order to solve the above-described problems, the present invention provides an electronic device capable of suppressing the occurrence of erroneous detection in an organic electroluminescence element panel having a touch sensor function.

An electronic device of the present invention includes a flexible printed wiring board and a plurality of organic electroluminescence element panels having a touch sensor function, and a first wiring connected to a touch detection electrode of the first organic electroluminescence element panel; The touch detection electrode of the second organic electroluminescence element panel does not have a portion overlapping in the stacking direction of the flexible printed wiring board.

According to the present invention, it is possible to provide an electronic device capable of suppressing the occurrence of erroneous detection in an organic electroluminescence element panel having a touch sensor function.

It is a top view of a smart device. FIG. 2 is a cross-sectional view taken along line AA of the smart device shown in FIG. It is a schematic sectional drawing which shows the structure of the OLED panel which has a touch sensor function. It is a figure which shows the drive circuit figure of the OLED panel which has a touch sensor function. It is a figure which shows the timing chart of the light emission period and sensing period of an OLED panel which has a touch sensor function. It is a circuit operation | movement figure of the light emission period (LT) of the OLED panel which has a touch sensor function. It is a circuit operation | movement figure of the sensing period (ST) of the OLED panel which has a touch sensor function. FIG. 10 is a plan layout view of an OLED panel mounted on an FPC (conventional). FIG. 9 is a sectional view taken along line BB of the OLED panel mounted on the FPC shown in FIG. It is a figure which shows the state by which the OLED panel was touched with the finger | toe. It is an equivalent circuit diagram of a touch detection circuit unit. FIG. 2 is a plan layout view of an OLED panel mounted on an FPC (first embodiment). It is CC sectional view taken on the line of the OLED panel mounted in FPC shown in FIG. FIG. 6 is a plan layout view of an OLED panel mounted on an FPC (second embodiment).

Hereinafter, although the example of the form for implementing this invention is demonstrated, this invention is not limited to the following examples.
The description will be given in the following order.
1. 1. Outline of electronic equipment Embodiment of electronic device (first embodiment)
3. Embodiment of electronic device (second embodiment)

<1. Overview of electronic devices>
Prior to the description of an embodiment of an electronic apparatus including a plurality of organic electroluminescence element panels (OLED panels) having a touch sensor function, an outline of an electronic apparatus including a plurality of OLED panels having a touch sensor function will be described.

[Configuration of electronic equipment]
FIG. 1 shows a plan view of a smart device as an example of a general electronic device. FIG. 2 is a cross-sectional view of the smart device shown in FIG. The smart device 10 illustrated in FIGS. 1 and 2 is, for example, a smartphone or a tablet computer. In FIGS. 1 and 2, only the main components used in the description of the present embodiment are shown, and the description of other components such as the power supply unit is omitted.

As shown in FIG. 1, the smart device 10 is provided with a plurality of common function keys 13 in the icon display section 12 below the main display screen 11. The common function key 13 is displayed by an icon 14. An OLED panel having a touch sensor function (not shown) is mounted below the common function key 13 displayed by these icons 14, and touch detection of the OLED panel having the touch sensor function is turned ON by touching the icon 14, and the smart device. 10 functions can be switched.

As shown in FIG. 2, the smart device 10 includes a housing 18 that forms the bottom and side surfaces of the smart device 10, each element disposed inside the housing 18, and each element. The cover 18 covers the upper part inside the housing 18 and is provided on the entire surface of the smart device 10 on the surface side.

In the housing 18, a main display panel 19 including a liquid crystal panel for configuring the main display screen 11, an OLED panel 20 having a touch sensor function for configuring the icon display unit 12, and the smart device 10. A printed circuit board (PCB) 15 on which various circuits are formed, and a flexible printed circuit (FPC) 16 and 40 for connecting the main display panel 19 or the OLED panel 20 and the PCB 15 are provided. It has been.
The main display panel 19, the OLED panel 20 and the PCB 15, and the FPCs 16 and 40 are pressure-bonded and connected by an anisotropic conductive film (ACF) or the like (not shown).

As shown in FIG. 2, the main display panel 19 and the OLED panel 20 are connected to the PCB 15 via the FPCs 16 and 40, and are connected to various control units and various circuits provided on the PCB 15. In addition, the main display panel 19 and the OLED panel 20 are generally supplied with power from a power supply circuit provided in the PCB 15.

[Configuration of organic EL element with touch sensor]
Next, the OLED panel 20 having a touch sensor function mounted on the smart device 10 will be described. FIG. 3 is a schematic cross-sectional view showing an example of the configuration of an OLED panel having a touch sensor function in which the anode electrode is a touch detection electrode.

In the OLED panel 20 shown in FIG. 3, an anode electrode 24 and, for example, a hole injection layer, a hole transport layer, a light emitting layer, an electron transport layer, an electron injection layer, and the like are formed on the transparent base material 23. A light emitting unit 25 and a cathode electrode 26 are stacked. Further, the outer peripheral portions of the transparent base material 23, the light emitting unit 25, and the cathode electrode 26 are sealed with a sealing resin 27, and a sealing member 28 is disposed on the sealing resin 27, whereby the organic EL element 30 is configured. Has been. In the OLED panel 20, the surface of the transparent base 23 opposite to the surface on which the organic EL element 30 is formed is sealed with a sealing resin 27 in a state separated from the organic EL element 30, and the upper surface portion thereof. A cover glass 21 is provided.

In the OLED panel 20, a light emitting element drive circuit unit 22 is connected between an anode electrode 24 and a cathode electrode 26, which are a pair of electrodes. The light emitting element driving circuit unit 22 is provided with a light emitting element driving circuit unit capable of controlling light emission of the organic EL element 30.

Further, in the configuration of the OLED panel 20 having a touch sensor function, the anode electrode 24 functions as a counter electrode that causes the organic EL element 30 to emit light, and also functions as a detection electrode that is a touch detection electrode. For this reason, the anode electrode 24 that is a touch detection electrode is provided with a capacitive touch detection circuit unit 29 that can detect a touch (finger touch). In the above description, the configuration in which the anode electrode 24 also serves as the touch detection electrode is shown, but the cathode electrode 26 may serve as the touch detection electrode.

[Drive circuit diagram]
Next, FIG. 4 shows an example of a drive circuit diagram of the OLED panel 20 having the touch sensor function shown in FIG. In the following description of the drive circuit diagram, symbols corresponding to the respective components shown in FIG.
In the drive circuit diagram of the OLED panel 20 shown in FIG. 4, the organic EL element 30 shown in the center has the anode electrode 24 connected to the anode electrode wiring 35 and the cathode electrode 26 connected to the cathode electrode wiring 36. The organic EL element 30 functions as a diode 32 serving as a light emitting element and a capacitor 31 serving as a capacitive element between the cathode electrode 26 and the anode electrode wiring 35.

The organic EL element 30 is connected to the light emitting element driving circuit unit 22 by an anode electrode wiring 35 and a cathode electrode wiring 36.
The light emitting element driving circuit unit 22 includes a light emitting element driving circuit unit 33. The light emitting element driving circuit unit 33 incorporates a constant current driving circuit or a constant voltage driving circuit, controls the light emission timing of the organic EL element 30, and applies reverse bias (reverse applied voltage) as necessary. The light emitting element driving circuit unit 22 includes an anode electrode wiring 35, a switch 1 (SW1), a light emitting element driving circuit unit 33, a switch 2 (SW2), and a cathode electrode wiring 36, as indicated by a broken line in FIG. The circuit range that is being used. In FIG. 4, the light emitting element drive circuit unit 33 and SW1 and SW2 are shown as independent structures. However, if necessary, the light emitting element drive circuit unit 33 includes SW1 and / or SW2. It may be.

In the light emitting element driving circuit unit 22, the anode electrode wiring 35 led out from the anode electrode 24 is connected to the light emitting element driving circuit unit 33 through the switch 1 (SW 1). Further, the cathode electrode wiring 36 drawn from the cathode electrode 26 is connected to the light emitting element driving circuit unit 33 via the switch 2 (SW2). Further, the light emitting element driving circuit unit 33 is connected to the ground 37. The ground 37 is specifically called a signal ground.

The organic EL element 30 is connected to the touch detection circuit unit 29 by an anode electrode wiring 35 drawn from the anode electrode 24 that functions as a touch detection electrode. In the touch detection circuit unit 29, the anode electrode wiring 35 drawn from the anode electrode 24 is connected to the touch detection circuit unit 34 via the switch 3 (SW3). The touch detection circuit unit 34 is connected to the ground 37. A configuration in which the switch 3 (SW3) is incorporated in the touch detection circuit unit 34 may be employed.

The light emitting element drive circuit unit 33 includes a step-up or step-down DC-DC converter circuit, a switch element control circuit of the DC-DC converter, a current value feedback circuit, and the like. For example, the detection resistance is R ₁ , the comparison potential is V _ref, and the anode potential of the organic EL element 30 is boosted by the DC-DC converter circuit so that the current I _OLED flowing through the organic EL element 30 becomes V _ref / R _1. Alternatively, by reducing the voltage, the light emitting element driving circuit unit 33 can be a constant current circuit. Here, the feedback circuit _applies feedback to the output V _out of the DC-DC converter circuit so that V _X = V _ref .

The configuration of the light emitting element driving circuit unit 33 is not particularly limited, and a conventionally known light emitting element driving circuit unit (organic EL element driving circuit) can be applied. In general, the light emitting element driving circuit emits light from an organic EL element, which is a light emitting element, between an anode electrode and a cathode electrode according to a preset light emitting pattern of the light emitting element as shown in FIG. It has a function of applying a current according to the amount of light. As this light emitting element driving circuit, a constant current circuit including a step-up or step-down DC-DC converter circuit, a current value feedback circuit, a DC-DC converter switch control circuit, and the like is known. As the light emitting element driving circuit unit 33, the light emitting element driving circuits described in JP 2002-156944 A, JP 2005-265937 A, JP 2010-040246 A, and the like can be referred to.

The configuration of the touch detection circuit unit 34 is not particularly limited, and a conventional known touch detection circuit can be applied. In general, the touch detection circuit includes an amplifier, a filter, an AD converter, a rectifying / smoothing circuit, a comparator, and the like. Typical examples of the touch detection circuit unit 34 include a self-capacitance detection method, a series capacitance division comparison method (OMRON method), and the like. As the touch detection circuit unit 34, touch detection circuits described in JP 2012-073783 A, JP 2013-088932 A, JP 2014-053000 A, and the like can be referred to.

The switches 1 to 3 (SW1 to SW3) are not particularly limited as long as they have a switching function such as a field effect transistor (FET) and a thin film transistor (TFT).

[Timing chart]
Next, a time-series operation of the light emission period and the sensing period (touch detection period) of the OLED panel 20 having the touch sensor function shown in FIG. 4 will be described using a timing chart. FIG. 5 shows a timing chart showing an example of the light emission period and the sensing period.

The OLED panel 20 having the touch sensor function shown in FIG. 4 is controlled by the light emission period of the OLED panel 20 controlled by the light emitting element driving circuit unit 22 and the touch detection circuit unit 29 by ON / OFF control of each switch. The sensing period is driven separately. Thereby, the light emission in the OLED panel 20 which has a touch sensor function, and a touch sensor function can be expressed.

5 is a chart showing the ON / OFF operation timing of SW1 in the light emitting element driving circuit unit 22. The uppermost column in FIG. And each column below this is a chart which similarly shows the operation timing of SW2 and SW3.

The bottom column is a chart showing a voltage application state to the organic EL element (OLED). When SW1 and SW2 are in the “ON” state, the voltage rises from the OFF voltage of the organic EL element, and light emission of the organic EL element is started when the voltage becomes a voltage necessary for light emission. Next, when SW1 and SW2 are turned “OFF”, the current supply to the organic EL element is stopped and the organic EL element is turned off. However, even if SW1 and SW2 are set to “OFF”, they are not turned off instantaneously, and are turned off after a certain time (t1) according to the OLED charge / discharge time constant τ.

On the other hand, SW3 is a switch for controlling the driving of the touch detection circuit unit 29. When SW1 and SW2 are “ON”, SW3 is set to “OFF”, and SW1 and SW2 are set to “OFF”. Touch detection is performed by setting SW3 to the “ON” state. However, the timing for setting SW3 to the “ON” state is after a predetermined standby time (t1) has elapsed from the above-described SW1 and SW2 to “OFF”. This standby period (t1) is preferably in the range of about 0τ to 5τ of the charge / discharge time constant τ of the organic EL element.

In the timing chart shown in FIG. 5, the period from when SW1 and SW2 are turned “ON” to when it is turned “OFF” is the light emission period (LT), and after SW1 and SW2 are turned “OFF”, SW3 is turned “OFF”. Is a sensing period (ST) in which touch detection is performed. Note that the total period (LT + ST) of one light emission period (LT) and one sensing period (ST) is referred to as one frame period (1FT) in the timing chart.

There is no restriction | limiting in particular as a light emission period (LT) in the OLED panel 20 which has a touch sensor function, a sensing period (ST), and 1 frame period (1FT), The conditions suitable for the environment to apply can be selected suitably. For example, the light emission period (LT) can be 0.1 to 2.0 ms, the sensing period (ST) can be 0.05 to 0.3 ms, and the one frame period (1FT) can be 0.15 to 2.3 ms. One frame period (1FT) is preferably 60 Hz or more for the purpose of reducing flicker.

[Touch detection operation]
Next, the circuit operation in the light emission period (LT) and the circuit operation in the sensing period (ST) in the OLED panel 20 having the touch sensor function will be described. FIG. 6 shows an example of a circuit operation diagram in the light emission period (LT). FIG. 7 shows an example of a circuit operation diagram in the sensing period (ST).

As shown in FIG. 6, in the light emission period (LT), SW1 and SW2 are turned on. Then, the light emission driving condition is controlled by the light emitting element driving circuit unit 33, and the organic EL element 30 is caused to emit light according to the light emission control information route 38. At this time, SW3 connected to the touch detection circuit unit 29 is set to the “OFF” state.

Next, as shown in FIG. 7, SW1 and SW2 of the light emitting element driving circuit unit 22 are set to “OFF” to open the light emitting element driving circuit, and the switch 3 (SW3) of the touch detection circuit unit 29 is set to “ON”. " In this state, when the upper surface of the crow substrate of the anode electrode 24 that is the detection electrode that constitutes the organic EL element 30 is touched with a finger (F), the finger (F) and the anode electrode 24 that is the detection electrode are placed between them. Parasitic capacitance (Cf) is generated. The parasitic capacitance (Cf) is connected to the ground (GND). At this time, SW1 and SW2 are in the “OFF” state, and the pair of electrodes are in a floating potential state in which the electric capacitance of the OLED panel 20 is not detected, so that the parasitic capacitance is in a state of Cf> Cel. Accordingly, touch detection by the touch detection circuit unit 34 can be performed in accordance with the touch detection information route 39 which is a touch detection information route at the time of sensing.

[Reason for false detection]
Next, in the OLED panel having the touch sensor function having the above-described configuration, noise generated between the OLED panel and various wirings of the FPC laid out in the vicinity of the OLED panel, and touch detection error due to the generated noise. The detection will be described.

FIG. 8 shows a plan layout of the FPC and the OLED panel mounted on the FPC. FIG. 9 shows a cross-sectional view of the FPC and the OLED panel mounted on the FPC. FIG. 9 is a view corresponding to a cross section taken along line BB in FIG.

As shown in FIG. 8, three common function keys are provided in the icon display section of the smart device (see FIG. 1), and a first OLED panel for displaying three icons corresponding to the three common function keys. 20A, the second OLED panel 20B, and the third OLED panel 20C are arranged in the FPC 40. In FIG. 8, regions where the first to third OLED panels 20A, 20B, and 20C are arranged are indicated by broken lines. In addition to the regions where the first to third OLED panels 20A, 20B, 20C are disposed, the regions where the anode electrodes 24A, 24B, 24C are disposed are indicated by solid lines.

The FPC 40 has a configuration in which a base film 41 and conductive layers formed on both main surfaces of the base film 41 are laminated. As shown in FIGS. 8 and 9, the FPC 40 is provided with wirings 42, 43, 44 that penetrate both main surfaces of the base film 41 and the base film 41. The wirings 42, 43, and 44 are connected to the respective electrodes of the first to third OLED panels 20A, 20B, and 20C on the first main surface (front surface) side of the base film 41 in a predetermined layout. Further, the wirings 42 and 43 are led out to the second main surface (back surface) side of the base film 41 through the through electrodes. The wiring 44 is provided on the first main surface (front surface) side of the base film 41.

Specifically, the wiring 42 is connected to the cathode electrode or the anode electrode of the first organic electroluminescence element panel (OLED panel) 20A, and is drawn out to the external connection terminal of the FPC 40. Further, the wiring 42 is connected to the cathode electrode or the anode electrode of the first OLED panel 20A on the first surface side of the base film 41, and is led out to the second surface side through the through electrode. The wiring 42 passes through the overlapping area in the stacking direction of the second and third OLED panels 20B and 20C and the FPC 40, and is led out to the external connection terminal. At this time, a part of the wiring 42 provided on the second surface side passes through a region overlapping with the anode electrode 24B of the second OLED panel 20B before reaching the external connection terminal of the FPC 40. Therefore, as shown in FIG. 9, the wiring 42 has a portion that overlaps with the anode electrode 24 </ b> B of the second OLED panel 20 </ b> B in the stacking direction of the FPC 40.

Similarly, the wiring 43 is connected to the cathode electrode or the anode electrode of the second OLED panel 20B and led out to the external connection terminal of the FPC 40. Further, the wiring 43 is connected to the cathode electrode or the anode electrode of the second OLED panel 20B on the first surface side of the base film 41, and is led out to the second surface side through the through electrode. The wiring 43 passes through a region overlapping in the stacking direction of the third OLED panel 20C and the FPC 40, and is drawn out to the external connection terminal. At this time, a part of the wiring 43 provided on the second surface side passes through a region overlapping with the anode electrode 24C of the third OLED panel 20C until reaching the external connection terminal of the FPC 40. Therefore, as shown in FIG. 9, the wiring 43 has a portion that overlaps the anode electrode 24 </ b> C of the third OLED panel 20 </ b> C in the stacking direction of the FPC 40.

When the second OLED panel 20B is touched with the finger (F) in the first to third OLED panels 20A, 20B, 20C having the above-described configuration and the FPC 40, as shown in FIG. 9, the second OLED panel 20B A parasitic capacitance (Cf) is generated between the finger (F) and the anode electrode 24B as the detection electrode. In addition, since the wiring 42 has a portion that overlaps with the anode electrode 24B of the second OLED panel 20B in the stacking direction, the parasitic capacitance is also generated in the portion where the wiring 42 and the anode electrode 24B overlap with the generation of the parasitic capacitance (Cf). (Cp1) is generated.

The generation of parasitic capacitance (Cf) and parasitic capacitance (Cp1) will be described with reference to FIG. FIG. 10 shows a state where the second OLED panel 20B mounted on the FPC 40 is touched with a finger (F). The second OLED panel 20B in FIG. 10 has the same configuration as the OLED panel 20 shown in FIG. 3 described above, and the sealing member 28 side of the second OLED panel 20B is disposed on the first main surface of the FPC 40. ing. Further, the wiring 43 is connected to the anode electrode 24B of the second OLED panel 20B, and is led out to the second main surface side of the FPC 40 through the through electrode.

As shown in FIG. 10, when the second OLED panel 20B mounted on the FPC 40 is touched with a finger (F), the finger (F) and the anode electrode 24 that is a detection electrode are touched on the second OLED panel 20B. A parasitic capacitance (Cf) is generated between them. Thereby, the touch detection in the touch detection circuit unit 29B becomes possible by the touch detection operation described above. Accordingly, a touch on the second OLED panel 20B is detected.

Also, as shown in FIG. 10, when the second OLED panel 20B mounted on the FPC 40 is touched with a finger (F), a parasitic capacitance (Cp1) is generated at a portion where the wiring 42 and the anode electrode 24B overlap. . Here, the parasitic capacitance (Cf) generated between the finger (F) and the anode electrode 24 serving as the detection electrode, and the parasitic capacitance (Cp1) generated in the portion where the wiring 42 and the anode electrode 24B overlap each other are: Since the capacitive element in which (F), the anode electrode 24, and the wiring 42 are connected in series, a combined capacitance (Ct) is generated.

In the first and second OLED panels 20A and 20B having the touch sensor function, the parasitic capacitance (Cf), the parasitic capacitance (Cp1), the touch detection circuit unit 34A of the first OLED panel 20A, and the second OLED panel 20B FIG. 11 shows an equivalent circuit of the touch detection circuit unit 34B.

As shown in FIG. 11, the combined capacitance (Ct) viewed from the touch detection circuit unit 34B of the second OLED panel 20B is a parasitic capacitance (Cf). Whether or not a touch is possible in each OLED panel is determined by whether or not the combined capacitance (Ct) viewed from each touch detection circuit unit exceeds a threshold value. For this reason, when the parasitic capacitance (Cf) exceeding the threshold value is generated in the anode electrode 24B that is the touch detection electrode of the second OLED panel 20B, the touch is detected by the touch detection circuit unit 34B.

On the other hand, the combined capacitance (Ct) seen from the touch detection circuit unit 34A of the first OLED panel 20A is [Ct = (Cf + Cp1) / () because the parasitic capacitance (Cf) and the parasitic capacitance (Cp1) are connected in series. Cf × Cp1)]. At this time, since the parasitic capacitance (Cf) is much larger than the parasitic capacitance (Cp1), [Cf >> Cp1] is satisfied. Therefore, the combined capacity (Ct) obtained by the above formula is [Ct = Cf]. Accordingly, the combined capacitance (Ct) viewed from the touch detection circuit unit 34A of the first OLED panel 20A becomes the parasitic capacitance (Cf).

Therefore, a parasitic capacitance (Cf) exceeding a threshold value is generated in the wiring 42 connected to the anode electrode 24A that is the touch detection electrode of the first OLED panel 20A, and the first OLED panel connected to the anode electrode 24A. The 20A touch detection circuit unit 34A detects a touch. Thereby, although the first OLED panel 20A is not touched, the touch is detected also in the touch detection circuit unit 34A of the first OLED panel 20A, and erroneous detection occurs.

In the electronic device having the above-described configuration, the anode electrode 24C that is the touch detection electrode of the third OLED panel 20C and the wiring 43 that is connected to the anode electrode 24B that is the touch detection electrode of the second OLED panel 20B include: It has a region overlapping in the stacking direction. For this reason, the same erroneous detection as described above may occur in the second OLED panel 20B when the third OLED panel 20C is touched. As described above, in the configuration in which the wiring connected to the touch detection electrode of the OLED panel passes through the region where the touch detection electrode of another OLED panel is formed and has portions overlapping each other in the stacking direction of the FPC 40, Misdetection of detection may occur.

<2. Embodiment of Electronic Device (First Embodiment)>
Hereinafter, an embodiment (first embodiment) of an electronic device including an OLED panel having a touch sensor function capable of suppressing the above-described erroneous detection will be described. In addition, the structure of the electronic device in the following embodiment can apply the structure similar to description of the above-mentioned electronic device except the layout of the wiring provided in FPC. Therefore, in the following description, only the configuration related to the layout of the wiring provided in the FPC will be described, and detailed description of the other configuration will be omitted.

[Configuration of electronic equipment]
FIG. 12 shows a planar layout of the FPC and the OLED panel mounted on the FPC in the embodiment. FIG. 13 shows a cross-sectional view of the FPC and the OLED panel mounted on the FPC. FIG. 13 is a view corresponding to a cross section taken along the line CC in FIG.

As shown in FIG. 12, three common function keys are provided in the icon display section of the smart device (see FIG. 1), and first to third icons for displaying three icons corresponding to the three common function keys. OLED panels 20A, 20B, and 20C are arranged in the FPC 40. The first to third OLED panels 20A, 20B, and 20C are arranged in the order of the third OLED panel 20C, the second OLED panel 20B, and the first OLED panel 20A from the external connection terminal side. In FIG. 12, regions where the first to third OLED panels 20A, 20B, and 20C are arranged are indicated by broken lines. In addition to the regions where the first to third OLED panels 20A, 20B, 20C are disposed, the regions where the anode electrodes 24A, 24B, 24C are disposed are indicated by solid lines.

The FPC 40 includes a base film 41, a first wiring 42A and a second wiring 42B connected to the first OLED panel 20A, and a third wiring 43A and a fourth wiring connected to the second OLED panel 20B. The wiring 43B includes a fifth wiring 44A and a sixth wiring 44B connected to the third OLED panel 20C. In the present embodiment, as an example of the connection between the OLED panel and the wiring, the first wiring 42A is connected to the anode electrode of the first OLED panel 20A, and the second electrode is connected to the cathode electrode of the first OLED panel 20A. Description will be made assuming a configuration in which the wiring 42B is connected. Similarly, a configuration in which the third wiring 43A is connected to the anode electrode of the second OLED panel 20B, and the fourth wiring 43B is connected to the cathode electrode of the second OLED panel 20B, and the third OLED Description will be made assuming a configuration in which the fifth wiring 44A is connected to the anode electrode of the panel 20C and the sixth wiring 44B is connected to the cathode electrode of the third OLED panel 20C.

The first wiring 42A and the second wiring 42B connected to the first OLED panel 20A are laid out on both main surfaces of the base film 41 and in the through holes of the base film 41. The first wiring 42A and the second wiring 42B are connected to the anode electrode 24A or the cathode electrode of the first OLED panel 20A on the first main surface (front surface) side of the base film 41, respectively. Then, the first wiring 42A and the second wiring 42B are led out to the second main surface (back surface) side of the base film 41 through the through electrode in the region where the first OLED panel 20A is disposed. Yes.

The first wiring 42A and the second wiring 42B led out to the second main surface side of the base film 41 are within the region where the second OLED panel 20B is disposed and the touch detection of the second OLED panel 20B. The anode electrode 24B, which is an electrode, passes outside the region where the anode electrode 24B is disposed, and is led out to the external connection terminal. Further, the first wiring 42A and the second wiring 42B are in a region where the third OLED panel 20C is disposed and a region where the anode electrode 24C which is a touch detection electrode of the third OLED panel 20C is disposed. It passes outside and is pulled out to the terminal for external connection. Further, the first wiring 42A and the second wiring 42B are arranged outside the third wiring 43A and the fourth wiring 43B, and the fifth wiring 44A and the sixth wiring 44B in the planar arrangement of the FPC 40. Has been.

Further, the first wiring 42A and the second wiring 42B led to the second main surface side of the base film 41 are led out between the first OLED panel 20A and the second OLED panel 20B. In a direction (vertical direction in the drawing) perpendicular to the direction (horizontal direction in the drawing), the electrodes are led out in the opposite directions. In the first wiring 42A and the second wiring 42B, the distance between the wirings in a direction (vertical direction in the drawing) orthogonal to the direction in which the wiring is led out (horizontal direction in the drawing) is vertical in the drawing of the anode electrodes 24B and 24C. After becoming larger than the length in the direction, the wires are drawn out in parallel toward the outside of the FPC 40 in the direction in which the wiring is led out (lateral direction in the drawing).

Therefore, the first wiring 42A and the second wiring 42B are laid out on both ends of the base film 41 of the FPC 40 with the second and third OLED panels 20B and 20C interposed therebetween. Then, between the region where the second OLED panel 20B and the third OLED panel 20C are arranged and the external connection terminal, the direction in which the wiring is led out outside the anode electrodes 24B and 24C (lateral direction in the drawing) It is arranged in parallel with.

The third wiring 43A and the fourth wiring 43B connected to the second OLED panel 20B are laid out on both main surfaces of the base film 41 and in the through holes of the base film 41. The third wiring 43A and the fourth wiring 43B are connected to the anode electrode 24B or the cathode electrode of the second OLED panel 20B on the first main surface (front surface) side of the base film 41, respectively. And 3rd wiring 43A and 4th wiring 43B are derived | led-out by the 2nd main surface (back surface) side of the base film 41 via the penetration electrode in the area | region where 2nd OLED panel 20B is arrange | positioned. Yes.

Furthermore, the third wiring 43A and the fourth wiring 43B led out to the second main surface side of the base film 41 are within the region where the third OLED panel 20C is disposed and of the third OLED panel 20C. The anode electrode 24C, which is a touch detection electrode, passes outside the region where the anode electrode 24C is disposed, and is led out to the external connection terminal. Further, the third wiring 43A and the fourth wiring 43B are arranged inside the planar arrangement of the FPC 40 relative to the first wiring 42A and the second wiring 42B, and the fifth wiring 44A and the sixth wiring 44B. Rather than outside in the planar arrangement of the FPC 40.

In addition, the third wiring 43A and the fourth wiring 43B led out to the second main surface side of the base film 41 are led out between the second OLED panel 20B and the third OLED panel 20C. In the direction (vertical direction in the drawing) orthogonal to the direction (horizontal direction in the drawing), each is derived from the electrode in the same direction. The third wiring 43A and the fourth wiring 43B have a distance between wirings in a direction (vertical direction in the drawing) orthogonal to the direction in which the wiring is derived (horizontal direction in the drawing) in the vertical direction in the drawing of the anode electrode 24C. After becoming larger than the length, the wires are drawn in parallel toward the outside of the FPC 40 in the direction in which the wiring is led out (lateral direction in the drawing).

Therefore, the third wiring 43A and the fourth wiring 43B are laid out on both ends of the base film 41 of the FPC 40 with the third OLED panel 20C interposed therebetween. In the region where the third OLED panel 20C is disposed, the third OLED panel 20C is disposed outside the anode electrode 24C in parallel to the direction in which the wiring is led out (lateral direction in the drawing). In addition, in the region where the wirings of the third wiring 43A and the fourth wiring 43B are arranged in parallel to the lead-out direction (the lateral direction in the drawing), the third wiring 43A and the first wiring 42A are adjacent to each other. Thus, the fourth wiring 43B and the second wiring 42B are adjacently arranged in parallel.

The fifth wiring 44A and the sixth wiring 44B connected to the third OLED panel 20C are laid out only on the first main surface (front surface) side of the base film 41. The fifth wiring 44A and the sixth wiring 44B are connected to the anode electrode 24C or the cathode electrode of the third OLED panel 20C on the first main surface side of the base film 41, respectively. Then, the fifth wiring 44A and the sixth wiring 44B are drawn out to the external connection terminals.

Unlike the first wiring 42A and the second wiring 42B, the third wiring 43A and the fourth wiring 43B, the fifth wiring 44A and the sixth wiring 44B are OLEDs other than the third OLED panel 20C. It does not pass through the area where the panel is placed. Furthermore, the fifth wiring 44 </ b> A and the sixth wiring 44 </ b> B are not led out to the second main surface side of the base film 41. Further, the fifth wiring 44A and the sixth wiring 44B are formed from the third wiring 43A and the fourth wiring 43B, the first wiring 42A and the second wiring 42B from the both end sides of the base film 41 of the FPC 40. Is also laid out inside.

Therefore, the fifth wiring 44A and the sixth wiring 44B are laid out adjacent to each other in parallel to the direction in which the wiring is derived (lateral direction in the drawing). The fifth wiring 44A is arranged in parallel with the third wiring 43A and the first wiring 42A, and the sixth wiring 44B is arranged in parallel with the fourth wiring 43B and the second wiring 42B. Is arranged in. Therefore, in the FPC 40, in the planar arrangement, the first wiring 42A, the third wiring 43A, and the fifth wiring 44A are adjacently arranged in parallel in this order from one end side of the base film 41. It is laid out. Further, the second wiring 42B, the fourth wiring 43B, and the sixth wiring 44B are laid out adjacently in parallel from the other end side of the base film 41 in this order.

In the first to third OLED panels 20A, 20B, 20C and the FPC 40 configured as shown in FIG. 12 and FIG. 13, when the second OLED panel 20B is touched with a finger (F) as shown in FIG. In the second OLED panel 20B, a parasitic capacitance (Cf) is generated between the finger (F) and the anode electrode 24B as the detection electrode. As described above, the parasitic capacitance (Cf) is generated between the finger (F) and the anode electrode 24 serving as the detection electrode, so that the touch detection operation described in the outline of the electronic device described above causes the touch detection circuit unit 29B. Can be detected. Accordingly, a touch on the second OLED panel 20B is detected.

However, in the first to third OLED panels 20A, 20B, 20C and the FPC 40 configured as shown in FIGS. 12 and 13, the first wiring 42A overlaps the anode electrode 24B of the second OLED panel 20B in the stacking direction. Does not have a part. Therefore, unlike the configuration described in the outline of the electronic device (see FIGS. 8 to 11), no parasitic capacitance (Cp1) is generated between the first wiring 42A and the anode electrode 24B.

Accordingly, in the first to third OLED panels 20A, 20B, 20C and the FPC 40 having the configuration shown in FIGS. 12 and 13, the first OLED panel 20A connected to the anode electrode 24A that is the touch detection electrode of the first OLED panel 20A. The parasitic capacitance (Cf) exceeding the threshold value does not occur in the wiring 42A. As a result, in the touch on the second OLED panel 20B, the touch is not detected even in the touch detection circuit unit 34A of the first OLED panel 20A, and no erroneous detection occurs.

In the configuration shown in FIGS. 12 and 13, the third electrode connected to the anode electrode 24C that is the touch detection electrode of the third OLED panel 20C and the anode electrode 24B that is the touch detection electrode of the second OLED panel 20B. This wiring 43A does not have a region overlapping in the stacking direction. For this reason, similarly to the case of the first OLED panel 20A, erroneous detection in the second OLED panel 20B does not occur even when the third OLED panel 20C is touched.

That is, in an electronic device including an OLED panel having a touch sensor function configured as shown in FIGS. 12 and 13, the wiring connected to the touch detection electrode of the OLED panel is formed by the touch detection electrode of another OLED panel. The above-described erroneous detection of the touch detection does not occur by not passing through the formed region and having no overlapping portions in the stacking direction. Therefore, when an OLED panel having a specific touch sensor function is touched, an electronic device can be configured in which erroneous detection in an OLED panel having another touch sensor function is suppressed.

Furthermore, in the configuration shown in FIG. 12 and FIG. 13, the first wiring 42A and the second wiring 42B connected to the first OLED panel 20A are within the region where the second OLED panel 20B is disposed, and , And passes through the region where the third OLED panel 20C is disposed. Then, the third wiring 43A and the fourth wiring 43B connected to the second OLED panel 20B pass through the region where the third OLED panel 20C is disposed. For this reason, even in the configuration in which the wiring connected to the touch detection electrode of the above-described OLED panel does not pass through the region where the touch detection electrode of the other OLED panel is formed and does not have a portion overlapping each other in the stacking direction, There is no need to newly provide a region for wiring formation. Therefore, the wiring layout having the above-described configuration is possible without increasing the area of the FPC 40.

<3. Embodiment of Electronic Device (Second Embodiment)>
Next, a second embodiment of an electronic apparatus including an OLED panel having a touch sensor function and having a configuration capable of suppressing erroneous detection will be described. In addition, the structure of the electronic device in the following embodiment can apply the structure similar to the electronic device of the above-mentioned 1st Embodiment except the layout of the wiring provided in FPC. Therefore, in the following description, only the configuration related to the layout of the wiring provided in the FPC will be described, and detailed description of the other configuration will be omitted.

[Configuration of electronic equipment]
FIG. 14 shows a planar layout of the FPC in the embodiment and the OLED panel mounted on the FPC. The cross-sectional structure of the OLED panel mounted on the FPC shown in FIG. 14 is the same as the structure shown in FIG.

As shown in FIG. 14, first to third OLED panels 20A, 20B, and 20C for displaying three icons corresponding to the common function keys are arranged in the FPC 40. In FIG. 14, regions where the first to third OLED panels 20A, 20B, and 20C are arranged are indicated by broken lines. In addition to the regions where the first to third OLED panels 20A, 20B, 20C are disposed, the regions where the anode electrodes 24A, 24B, 24C are disposed are indicated by solid lines.

The FPC 40 includes a base film 41, a first wiring 42A and a second wiring 42B connected to the first OLED panel 20A, and a third wiring 43A and a fourth wiring connected to the second OLED panel 20B. The wiring 43B includes a fifth wiring 44A and a sixth wiring 44B connected to the third OLED panel 20C. In the present embodiment, as an example of the connection between the OLED panel and the wiring, the first wiring 42A is connected to the anode electrode of the first OLED panel 20A, and the second electrode is connected to the cathode electrode of the first OLED panel 20A. Description will be made assuming a configuration in which the wiring 42B is connected. Similarly, a configuration in which the third wiring 43A is connected to the anode electrode of the second OLED panel 20B, and the fourth wiring 43B is connected to the cathode electrode of the second OLED panel 20B, and the third OLED Description will be made assuming a configuration in which the fifth wiring 44A is connected to the anode electrode of the panel 20C and the sixth wiring 44B is connected to the cathode electrode of the third OLED panel 20C.

The first wiring 42A and the second wiring 42B connected to the first OLED panel 20A are the anode electrode 24A or the cathode electrode of the first OLED panel 20A on the first main surface (front surface) side of the base film 41. Are connected to each. Then, the first wiring 42A and the second wiring 42B are led out to the second main surface (back surface) side of the base film 41 through the through electrode in the region where the first OLED panel 20A is disposed. Yes.

Furthermore, the first wiring 42A and the second wiring 42B led out to the second main surface side of the base film 41 are within the region where the second OLED panel 20B is disposed and the second OLED panel 20B. The anode electrode 24B, which is a touch detection electrode, passes outside the region where the anode electrode 24B is disposed, and is led out to the external connection terminal. Further, the first wiring 42A and the second wiring 42B are in a region where the third OLED panel 20C is disposed and a region where the anode electrode 24C which is a touch detection electrode of the third OLED panel 20C is disposed. It passes outside and is pulled out to the terminal for external connection.

Further, the first wiring 42A and the second wiring 42B led to the second main surface side of the base film 41 are led out between the first OLED panel 20A and the second OLED panel 20B. In the direction (vertical direction in the drawing) orthogonal to the direction (horizontal direction in the drawing), each is derived from the electrode in the same direction. The first wiring 42A and the second wiring 42B are FPCs in the direction in which the wiring is derived (lateral direction in the drawing) in the vicinity of the region where the second OLED panel 20B and the third OLED panel 20C are arranged. It is pulled out in parallel toward the outside.

Therefore, the first wiring 42A and the second wiring 42B are laid out on one end side of the base film 41 of the FPC 40. Then, between the region where the second OLED panel 20B and the third OLED panel 20C are arranged and the external connection terminal, the direction in which the wiring is led out outside the anode electrodes 24B and 24C (lateral direction in the drawing) Are arranged adjacent to each other in parallel.

The third wiring 43A and the fourth wiring 43B connected to the second OLED panel 20B are the anode electrode 24B or cathode electrode of the second OLED panel 20B on the first main surface (front surface) side of the base film 41. Are connected to each. And 3rd wiring 43A and 4th wiring 43B are derived | led-out by the 2nd main surface (back surface) side of the base film 41 via the penetration electrode in the area | region where 2nd OLED panel 20B is arrange | positioned. Yes.

Furthermore, the third wiring 43A and the fourth wiring 43B led out to the second main surface side of the base film 41 are within the region where the third OLED panel 20C is disposed and of the third OLED panel 20C. The anode electrode 24C, which is a touch detection electrode, passes outside the region where the anode electrode 24C is disposed, and is led out to the external connection terminal.

In addition, the third wiring 43A and the fourth wiring 43B led out to the second main surface side of the base film 41 are led out between the second OLED panel 20B and the third OLED panel 20C. In the direction (vertical direction in the drawing) perpendicular to the direction (horizontal direction in the drawing), it is led out from the electrode in the direction opposite to the first wiring 42A and the second wiring 42B. The third wiring 43A and the fourth wiring 43B are parallel to the outside of the FPC in the direction in which the wiring is led out (the lateral direction in the drawing) in the vicinity of the region where the third OLED panel 20C is disposed. Is pulled out adjacent to

Therefore, the third wiring 43A and the fourth wiring 43B are laid out on the end side opposite to the first wiring 42A and the second wiring 42B of the base film 41 of the FPC 40. Between the region where the third OLED panel 20C is arranged and the external connection terminal, the outside of the anode electrode 24C is arranged adjacent to and parallel to the direction in which the wiring is led out (lateral direction in the drawing). Yes.

The fifth wiring 44A and the sixth wiring 44B connected to the third OLED panel 20C are laid out in the same manner as in the first embodiment. For this reason, the fifth wiring 44A and the sixth wiring 44B are laid out side by side in parallel with the direction in which the wiring is led out (the horizontal direction in the drawing). The fifth wiring 44A is arranged in parallel with the first wiring 42A and the second wiring 42B, and the sixth wiring 44B is arranged in parallel with the third wiring 43A and the fourth wiring 43B. Is arranged in.

Therefore, in the FPC 40, the first wiring 42A, the second wiring 42B, the fifth wiring 44A, the sixth wiring 44B, and the third wiring are arranged from the one end (on the drawing) side of the base film 41 in the planar arrangement. The wiring 43A and the fourth wiring 43B are laid out so as to be adjacent to each other in parallel. That is, the first wiring 42A, the third wiring 43A, and the fifth wiring 44A connected to the anode electrodes 24A, 24B, and 24C that are the touch detection electrodes of the first to third OLED panels 20A, 20B, and 20C are mutually connected. The second wiring 42B, the fourth wiring 43B, or the sixth wiring 44B that are not adjacent to each other and are connected to the cathode electrode that is not the touch detection electrode include the first wiring 42A, the third wiring 43A, and It is interposed between the fifth wirings 44A.

In the first embodiment described above, the first wiring 42A connected to the anode electrode 24A that is the touch detection electrode of the first OLED panel 20A and the anode electrode 24B that is the touch detection electrode of the second OLED panel 20B are used. The third wiring 43A to be connected and the fifth wiring 44A to be connected to the anode electrode 24C that is the touch detection electrode of the third OLED panel 20C are arranged adjacently and in parallel. For this reason, when noise (for example, parasitic capacitance between the wirings) is generated between the wirings, there is a possibility that the accuracy of touch detection in each touch detection circuit unit is lowered.

On the other hand, in the configuration shown in FIG. 14, the first wiring 42A, the third wiring 43A, which are connected to the anode electrodes 24A, 24B, 24C, which are touch detection electrodes of the first to third OLED panels 20A, 20B, 20C, The fifth wirings 44A are not arranged adjacent to each other. Then, the second wiring 42B, the fourth wiring 43B, and the sixth wiring 44B that are interposed between the first wiring 42A, the third wiring 43A, and the fifth wiring 44A and are not connected to the touch detection electrode. Is floating during the sensing period (ST) during which touch detection is performed. Therefore, the first wiring 42A, the third wiring 43A, and the fifth wiring 44A that are connected to the touch detection electrode, the second wiring 42B that is not connected to the touch detection electrode, the fourth wiring 43B, No parasitic capacitance is generated between the sixth wiring 44B and the sixth wiring 44B.

That is, since the second wiring 42B is disposed between the first wiring 42A and the fifth wiring 44A, the parasitic capacitance between the wirings between the first wiring 42A and the fifth wiring 44A. Does not occur. For this reason, in the 1st wiring 42A and the 5th wiring 44A, generation | occurrence | production of the noise in touch detection is suppressed, and it becomes possible to suppress the fall of the precision of touch detection.

Similarly, since the sixth wiring 44B is arranged between the third wiring 43A and the fifth wiring 44A, the parasitic between the wirings between the third wiring 43A and the fifth wiring 44A. There is no capacity. For this reason, in the 3rd wiring 43A and the 5th wiring 44A, generation | occurrence | production of the noise in touch detection is suppressed, and it becomes possible to suppress the fall of the precision of touch detection.

Therefore, in the configuration shown in FIG. 14, it is possible to suppress the occurrence of noise due to parasitic capacitance between the wirings connected to the anode electrode that is the touch detection electrode. It becomes possible. As a result, in an electronic apparatus including the OLED panel having the touch sensor function configured as shown in FIG. 14, it is possible to suppress a decrease in touch detection accuracy as well as the above-described erroneous detection of touch detection.

In each of the above-described embodiments, the touch detection electrode of the OLED panel is the anode electrode, and the wiring connected to the anode electrode that is the touch detection electrode is the first, third, and fifth wirings. It is not limited to. For example, the touch detection electrode may be a cathode electrode. Moreover, you may replace each wiring connected to an anode electrode or a cathode electrode.

The present invention is not limited to the configuration described in the above embodiment, and various modifications and changes can be made without departing from the configuration of the present invention.

DESCRIPTION OF SYMBOLS 10 ... Smart device, 11 ... Main display screen, 12 ... Icon display part, 13 ... Common function key, 14 ... Icon, 15 ... PCB, 16 ... Flexible printed wiring Plate (FPC), 17, 21 ... cover glass, 18 ... housing, 19 ... main display panel, 20 ... OLED panel, 20A ... first OLED panel, 20B ... 2nd OLED panel, 20C ... 3rd OLED panel, 22 ... Light emitting element drive circuit unit, 23 ... Transparent base material, 24, 24A, 24B, 24C ... Anode electrode, 25 ... Light emitting unit, 26 ... cathode electrode, 27 ... sealing resin, 28 ... sealing member, 29, 29B ... touch detection circuit unit, 30 ... organic EL element, 31 ... Con Sensor 32... Diode 33 33 light emitting element drive circuit 34, 34A, 34B touch detection circuit 35 35 anode electrode wiring 36 cathode electrode wiring 37. -Ground, 38 ... Light emission control information route, 39 ... Touch detection information route, 40 ... FPC, 41 ... Base film, 42, 43, 44 ... Wiring, 42A ... First , 42B, second wiring, 43A, third wiring, 43B, fourth wiring, 44A, fifth wiring, 44B, sixth wiring.

Claims (7)

1. A flexible printed wiring board;
   A plurality of organic electroluminescence element panels having a touch sensor function,
   The first wiring connected to the touch detection electrode of the first organic electroluminescence element panel and the touch detection electrode of the second organic electroluminescence element panel have a portion overlapping in the stacking direction of the flexible printed wiring board. No electronic equipment.
2. The electronic apparatus according to claim 1, wherein the first wiring passes through a region where the second organic electroluminescence element panel is disposed.
3. A second wiring connected to the electrode that is not the touch detection electrode of the first organic electroluminescence element panel, wherein the first wiring and the second wiring are wired on the flexible printed wiring board; The electronic device according to claim 1, wherein the electronic device is derived from the electrodes in directions opposite to each other in a direction orthogonal to a direction in which the current is derived.
4. The said 1st wiring and the said 2nd wiring are arrange | positioned in parallel with the direction where the said wiring is derived | led-in across the said touch detection electrode of a said 2nd organic electroluminescent element panel. The electronic device as described in.
5. A third wiring connected to the touch detection electrode of the second organic electroluminescence element panel and a fourth wiring connected to an electrode which is not the touch detection electrode of the second organic electroluminescence element panel. Have
   The first wiring, the second wiring, the third wiring, and the fourth wiring have a portion that is arranged in parallel to a direction in which the wiring is led out. The electronic device described.
6. A second wiring connected to the electrode that is not the touch detection electrode of the first organic electroluminescence element panel, wherein the first wiring and the second wiring are wired on the flexible printed wiring board; The electronic device according to claim 1, wherein each of the electronic devices is led out from the electrode in the same direction in a direction orthogonal to a direction from which the lead is drawn.
7. A third wiring connected to the touch detection electrode of the second organic electroluminescence element panel and a fourth wiring connected to an electrode which is not the touch detection electrode of the second organic electroluminescence element panel. Have
   The first wiring, the second wiring, the third wiring, and the fourth wiring have a portion that is arranged in parallel to a direction in which the wiring is led out,
   The electronic device according to claim 6, wherein the second wiring or the fourth wiring is interposed between the first wiring and the third wiring.

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