FR2928470A1 - Duplex touch panel for e.g. small electronic product, has capacitive touch panel unit with sensing layers having nodal points that are branched to wires, which transmit signals detected from layers to signal processing unit - Google Patents

Abstract

The panel has a resistive touch panel unit (2) connected below a thin capacitive touch panel unit (1). The unit (1) has signal output wires on which conductive paths are installed, and an X-axis sensing layer (12) and a Y-axis sensing layer (13) separated by an insulating layer (14), where the layers (12, 13) are made of indium tin oxide. Nodal points of line traces of the layers (12, 13) are respectively connected to silver conductive circuits at an edge of the panel, and are branched to the wires, which transmit signals detected from the layers (12, 13) to a signal processing unit (3).

Description

FIELD OF THE INVENTION This invention relates to a duplex touch panel, especially a device that includes both the touch sensitive interface of the capacitive touch panel and the resistive touch panel as well as the reception and processing of the detected signals.

BACKGROUND OF THE INVENTION In recent years, rapid advances in the techniques of production and manufacture of tactile devices have continuously improved both the performance of the products and the quality of the components involved, leads to a considerable reduction in prices and promoted wide application of various touch devices in a wide variety of products. In general, the touch device can simply be divided into 3 main categories: capacitive touch panel, resistive touch panel and electromagnetic touch panel. However, these touch panels have respectively their functional characteristics, quality and defect, therefore, currently, the development area of application of each panel is a little different. For example, resistive touch panels are often installed on the screen of small electronic products such as personal digital assistants (PDAs), electronic dictionaries, cell phones, MP3 digital players and satellite navigation systems (GPS - global position system) while capacitive touch panels are applied to the mouse pad of laptops and virtual touch keys etc. The resistive touch panel has two transparent conductive films that are separated by a space between them being opposite. The upper conductive film is installed on a surface of a transparent film hose and the lower conductive film is installed on a surface of a hard transparent glass substrate. Both conductive films are sealed inside a plate. The upper conductive film and the lower conductive film and the plate are all transparent material and thus adapted to be installed on a screen, which allows the user to make the input by gently touching the desired position of the panel according to the indication on the screen. It can also perform the operation on the precise contact position using a sharp object such as the tip of a pencil very easy to obtain.

As a result, it can be used when entering a smaller area of use or a higher point of accuracy, especially when entering complicated characters with many features. However, the mode of entry by the resistive touch panel may impose repetitive stress on conductive films inside the panel and cause damage, thus, the service life is limited. In addition, when finger-grasping or other tools with larger ends are used, the result is often less accurate. As a result, the input tools are also very limited.

The capacitive touch panel includes an X-axis detecting layer (X trace) and a Y-axis detecting layer (Y trace). The detector layer of the X axis and that of the Y axis are installed in isolation in a touch plate. These two layers are grounded individually and connected to a control circuit. In operation, when a finger or conductor touches the surface of the touch panel, a capacitive effect will be generated. The control circuit defines the position of contact of the finger or the conductor by following the variation of electrical capacitance. As the capacitive touch panel allows input with the finger, the input operation is very convenient. And for the input operation, there is no need for pressure. Thus, the panel is not likely to undergo any repetitive effort or deformation. In addition, the capacitive touch panel consists of few components with a simple structure. The compliance ratio is high and it is suitable for mass production to reduce the cost. Moreover, the touch panel still has the ability to multi-point detection. This means that this device has the ability to control multiple tasks and thus, it is suitable for higher order control operations. For example, in electronic games, it allows controlled subjects to act in a more flexible and diverse way. However, with this type of touch panel, the finger input mode does not have good detection accuracy, easily causes errors and causes discomfort on use. In particular, for the input of characters such as Chinese characters, the identification ratio is very low and it is not even practical. Although these problems can be overcome by using a special sensor pen, its application is still limited on a smaller surface panel or for input on points of higher accuracy. In addition, the special detector pen is not practical for users in many occasions

such as forgetting or losing the pen. Moreover, in recent years, for certain capacitive touch panels, the transparent insulating material such as PET is used as the base material, adopting the low-impedance transparent conductive material such as silver colloid and so on. as its detector layer, to form a transparent capacitive touch panel. The latter is suitable for putting on the screen electronic products, allowing users to perform the input of functions by gently touching the desired position on the panel as indicated on the screen. For this panel, the conductive material of silver colloid is not entirely transparent and the detecting layers are respectively etched in reticular traces in rhombic cells, which forms the parts of traces and the parts without traces (ie chiseled parts) with different optical transmittance on the work surface of the panel. As the difference between the trace portions and the non-trace portions is obvious, it still results that the refraction of the lights of the images on the screen below the touch panel is not equal and the images are blurry and unfaithful . In concluding from the above description, the capacitive touch panel and the resistive touch panel have their own characteristics, qualities and defects. As a result, a kind of panel that combines the functions and qualities of the two kinds of panels mentioned above is desired.

SUMMARY OF THE INVENTION The main object of this invention is to provide a kind of duplex touch panel. It combines the capacitive touch panel and the resistive touch panel into one plate, and features the faculties and qualities of two kinds of panels. In addition, its plate has an equal optical transmittance, which improves the blur and display distortion on the screen below this panel.

It is a secondary object of this invention to provide a kind of improved duplex touch panel. On all parts of nodal points crossed between the directional traces of the 1st axis and the directional traces of the 2nd axis in the capacitive touch panel unit, an extended sensing face is installed to reduce the proportion of the parts without traces (ie the chiseled parts ), increase the optical transmittance equality and trace detecting surface of the nodal parts, and enhance the sensitivity and accuracy of the detection faculty of the unit of 4

capacitive touch panel. According to the invention, this duplex touch panel contains a capacitive touch panel unit, a resistive touch panel unit and a signal processing unit. The capacitive touch panel unit and the resistive touch panel unit are combined into a plate. The latter transmits the signals detected by the two touch panel units to a signal processing unit which carries at least one signal judgment loop, can distinguish the types of signals transmitted by the two units and automatically selects the correct mode of processing signals for signal processing. And the capacitive touch panel unit comprises: an outer layer, a first axis sensing layer, an insulating layer, a second axis sensing layer, and a base layer. All of these layers are transparent material and can be superimposed in order in a transparent plate. The detection layer of the 1st axis contains the directional traces of the 1st axis and thus for the layer of the 2nd axis. These two layers are separated by the insulating layer, which makes the directional traces of the 1st axis and those of the 2nd axis to cross plumb and oppose by being separated. The nodal points of traces are installed on the directional traces of the 1st axis and those of the 2nd axis, respectively connected to the silver conductive circuits at the edge of the panel, and connected to a row of signal output wires, which allows the signals detected from this panel to be transmitted to the signal processing circuit by this row of signal output wires. Among others, the outer layer and the base layer are high transmittance optical film insulating material, such as film material such as glass, polycarbonate (PC), polyethylene terephthalate (PET), polymethyl methacrylate (PMMA) or Cyclic Olefin Copolymer. The detector layer of the 1st axis and that of the 2nd axis are etched with transparent film of ITO (indium-tin oxide) with good conductivity. The directional traces of the terax include transparent traces, most of which are arranged in parallel at the same distance, and preferably at a trace width of 0.05 ± 5 mm. And so for the directional traces of the 2nd axis. Moreover, there are parts of nodal points crossed between the directional traces of the 1st axis and the directional traces of the 2nd axis. And an extended detector face is installed on the directional tracks of the 1st axis and the directional traces of the

2nd axis of these nodal points. Now, an embodiment is taken to continue to explain and describe the features of this invention.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is the side section structural figure of this invention; Fig. 2 is the trace diagram of the sensing layer of the capacitive touch panel unit of this invention; Fig. 3 is the trace diagram of the other embodiment of the sensing layer of the capacitive touch panel unit of this invention.

DETAILED DESCRIPTION OF THE INVENTION Figure 1 and 2 show a better embodiment of this invention. It contains a capacitive touch panel unit 1, a resistive touch panel unit 2 and a signal processing unit 3. Among other things, the capacitive touch panel unit 1 comprises an outer layer 11, a detector layer 12 of the X axis, a detector layer 13 of the Y axis, an insulating layer 14 and a base layer 15 as well as a row of signal output wires 16. Layer 11 and layer 15 are optical transmittance film insulating material which may be the film material such as glass, polycarbonate (PC), polyethylene terephthalate (PET), polymethyl methacrylate (PMMA) or Cyclic Olefin Copolymer . In addition, the curing treatment was performed on the upper surface of the layer 11 to enhance the hardness of the work surface and prevent scratching and wear. And for the layer 12 and the layer 13, it is possible to select a transparent film with good conductivity and low impedance, such as the ITO film (indium-tin oxide). The layer 14 serves to isolate the layer 12 and 13. It is the film insulating material whose dielectric coefficient is 2û4 and which has a high optical transmittance, such as fatty ink or polythylene terephthalate film with high optical transmittance . For the row of signal output wires 16, a flexible printed circuit board (FPC) may be selected and some conductive circuits may be provided. And all these layers of materials can be superimposed in a transparent plate. And like FIGS. 1 and 2, the detector layer 12 of

the X axis contains the transparent traces 121, most of which are arranged in parallel at the same distance, and the detector layer 13 of the Y axis contains the transparent traces 131, most of which line up in parallel at the same distance. Usually, the trace width is 0.05-5mm. Thanks to the spacing of the insulating layer 14, the traces 121 and the traces 131 cross plumb and oppose by being separated. In addition, on one end of the traces 121, there is the nodal point 122 of traces and on one end of the traces 131, there is the nodal point 132 of traces. These nodal points 122 and 132 may be respectively connected to the silver conductor circuits 161a and 161b at the edge of the panel, and connected to the signal output lead array 6, allowing the detected signals of the detector layer 12 of the signal X axis and that 13 of the Y axis to be transmitted to the signal processing unit 3 by this row of son 6 signal output. As the arrangement of the aforesaid composition, an equivalent capacitance is formed between the detector layer 12 of the X axis and the silver conductive circuit 161a; an equivalent capacitance is also formed between the detector layer 13 of the Y axis and the silver conductive circuit 161b. As a result, when a finger or a conductor touches or slides gently on the surface of the touch panel, the signal processing circuit can judge the position of the finger or the conductor according to the variation of capacity. As the traces 121 of the X axis and the traces 131 of the Y axis of the capacitive touch panel unit cross plumb to square, not only the width of the trace wire is smaller, but also the layout traces are tidy and regular, this allows the panel to have a more equal optical transmittance and to improve the display distortion of the screen. In addition, as in FIG. 3, for the capacitive touch panel unit, the extended sensing surfaces 121a and 131a may be installed on the cross-nodal portion portions between the traces 121 of the X axis and the traces 131 of the Y axis.

This arrangement is used to reduce the proportion of streak-free parts (ie chiseled parts) on the touch panel work surface, to increase the optical transmittance equality of the touch panel work surface, to improve the display distortion of the touch panel. screen and enhance the sensitivity and accuracy of the touch panel sensing faculty by increasing the sensing area of the traces on the parts of nodal points. And the unit 2 of resistive touch panel is mainly

consisting of: an upper plate 21, an upper conductive film 22, a lower conductive film 23, a substrate 24 and the second row of signal output wires 26. In this embodiment, the top plate 21 shares the same plate with the base layer 15 of the capacitive touch panel unit while in the exceptional case the top plate 21 may not share the same plate with the 15. When the capacitive touch panel unit 1 and the resistive touch panel unit 2 superimpose a plate, this top plate 21 and the base layer 15 are glued together. For the substrate, hard transparent plates are used, such as transparent glass plate, acrylic plate and polyester plate. For the second row of signal output wires 26, the flexible printed circuit board may be selected and some conductive circuits may be installed on this row of wires. The lower conductive film 23 is also an ITO transparent film (indium and tin oxide) with electronic nodal points and is installed on the upper surface of the substrate 24. In addition, the upper film 22 and the film lower 23 are a little apart and opposed by many isolation balls 242. At the edge of the arranged area for these two conductive films 22 and 23, the insulating bonded layer is installed and combines them in a transparent board collage. The signals detected on these conductive films are collected and transmitted by the silver conductor circuits 244 at the edge of the panel to the 2nd row of signal output wires 26 and then forwarded to the next signal processing unit 3. According to the description of the above composition, the capacitive touch panel unit 1 is very thin, therefore, its installation above the resistive touch panel unit 2 is not likely to reduce the pressure sensing sensitivity of the unit. 2, but it can weaken the force shock experienced by the ITO film material (indium tin oxide) of the upper conductor wire 22 to prevent damage and prolong service life. Of course, this invention also makes it possible to superimpose the unit 2 above the unit 2 and such an arrangement also allows this invention to include the resistive-capacitive double-effect detector function.

The signal processing unit 3 carries a signal judgment loop, can distinguish the types of signals transmitted by the two units 1 and / or 2 and automatically selects the correct mode of

signal processing to perform the signal processing. For example, when a user makes finger-typing on the composite touch panel of this invention, the finger contact may create capacitive sensing signals on the X-axis sensing layer 12 and the sensing layer 13 of the present invention. Y axis of the unit 1. And as the finger does not make any pressure effort to the panel, the unit 2 can not create any signal. As a result, when the capacitive sensing signals are transmitted to the unit 3 by the 1st row of wires 16, the signal judging loop of the unit 3 will automatically judge and operate by selecting the detection signal processing mode. capacitive. In this processing mode, the unit 3 can only receive and process the detected signals of the unit 1 and isolate the detected signals from the unit 2. And still for example, when a user makes the entry with the tip the pen tip pressurizes the work area of the outer layer 11. As the unit 1 above is very thin and composed of the flexible plate, the effort the pressure of the tip can easily pass through the plate of unit 1 and will affect unit 2. When the pressure force of the tip makes conductive films 22 and 23 above and below the effect position to connect to electricity, a detection signal will be created. And since the tip does not cause a capacitive sensing signal by touching or sliding on the panel, Unit 1 will not create a signal. As a result, when the detected signals of the unit 2 are transmitted to the unit 3 by the second row of wires 26, the signal judgment loop of the unit 3 will automatically judge and operate by selecting the mode of processing of the unit. resistive detection signals. In this processing mode, the unit 3 can only receive and process the signals detected from the unit 2 and isolate the detected signals from the unit 1.

Claims (6)

A duplex touch panel characterized by containing a capacitive touch panel unit, a resistive touch panel unit and a signal processing unit, the capacitive touch panel unit and the resistive touch panel unit superposition a plate, the latter transmits the signals detected by the two units to the signal processing unit which carries at least one signal judgment loop, can distinguish the types of signals transmitted by the two units and automatically selects the correct mode signal processing apparatus for performing the signal processing characterized in that the capacitive touch panel unit contains: an outer layer which is a flexible insulating film with high optical transmittance, the first axis sensing layer which is transparent to good conductivity, this layer containing directional traces of the 1st axis, most of which line up in parallel to the same distance e, nodal points of traces being installed on the ends of these traces, an insulating layer which is a photic insulating film, the detecting layer of the second axis which is a transparent film with good conductivity, this layer containing directional traces of the second axis , the latter having transparent traces most of which are arranged in parallel at the same distance, nodal points of traces being installed on the ends of these traces, a base layer which is a flexible insulating film with high optical transmittance; and a row of signal output wires on which certain conductive circuits are installed, all these layers being superimposed in a transparent plate, the detector layer of the 1st axis and that of the second axis being separated by the insulating layer, the directional traces of the 1st axis and those of the 2nd axis crossing plumb and opposing being separated, the nodal points of the traces on the directional traces of the 1st axis and those of the 2nd axis being respectively connected to the circuits conductive silver on the edge of the panel and connected to this row of signal output wires, which allows the detected signals of the detector layers to be transmitted to the next signal processing unit by this row of signal output wires. 2. Duplex touch panel according to claim 1, characterized in that the resistive touch panel unit is superimposed below the capacitive touch panel unit and the two units form a plate. The duplex touch panel of claim 1, characterized in that the capacitive touch panel unit is superimposed over the resistive touch panel unit and the two units form a plate. 4. Duplex touch panel according to claim 1, characterized in that the detector layer of the 1st axis and that of the second axis are made of ITO film (indium tin oxide). 5. Duplex touch panel according to claim 1, characterized in that the width of the trace wire of the directional traces of the 1st axis and those of the 2nd axis is between 0.05 and 5mm. 6. Duplex touch panel according to claim 1, characterized in that it contains the extended detecting surfaces which are installed on the parts of nodal points crossed between the directional traces of the 1st axis and those of the 2nd axis.