This application claims the priority benefit of Taiwan application serial no. 101124810, filed on Jul. 10, 2012. The entirety of the above-mentioned patent application is hereby incorporated by reference herein and made a part of this specification.
The invention relates to a touch panel, more particularly to a touch panel with an improved touch sensing quality.
In recent years, information technology, wireless mobile communication, and information household appliances have been rapidly developed and applied. In order to achieve the objective of being easily portable, more compact, and more user friendly, the inputting device in many information products has been transformed from the traditional keyboard or mouse to a touch display panel. Currently, a touch panel can be roughly categorized into a restive type, a capacitive type, an acoustic type and an optical type, etc.
In a capacitive touch panel, the design of a sensing device includes a plurality of X-sensing electrode series and a plurality of Y-sensing electrode series, wherein the Y-sensing electrode series and the X-sensing electrode series are interlacing arranged. Further, one type of capacitive touch sensing panel uses a plurality of mutually independent sensing electrodes to conduct the sensing function. In this type of design, different sensing electrodes are respectively connected to a driver circuit via a corresponding conductive line. The length differences of the conductive lines would lead to inconsistency in the signal transmission quality. Hence, this type of design would result with varying quality of signal transmission, which ultimately would lead to sensing errors.
An exemplary embodiment of the invention provides a touch panel in which the touch sensing quality is enhanced.
An exemplary embodiment of the invention provides a touch panel that includes a substrate, a plurality of sensing electrode sets, a plurality of first pads, a plurality of second pads, a plurality of first conductive lines, a plurality of second conductive lines, and a plurality of resistors. The sensing electrode sets are disposed on the substrate, wherein each sensing electrode set includes a first sensing electrode pattern and a plurality of second sensing electrode patterns. The second sensing electrode patterns are disposed beside the first sensing electrode pattern. The first pads and the second pads are disposed on the substrate. The first conductive lines connect the first sensing electrode patterns to the first pads respectively. The second conductive lines connect the second sensing patterns of the sensing electrode sets to a plurality of series, wherein the second sensing electrode patterns of a same sensing electrode set belong to different series, and two terminals of each series respectively connect to two different second pads. The two terminals of each resistor respectively connect to the two different second pads that are connected to the two terminals of each series.
According an exemplary embodiment of the disclosure, the above touch panel further comprises a circuit board. The circuit board may be connected with the first pads and the second pads, and the resistors are disposed on the circuit board. Herein, the resistors include surface mount resistors.
According to an exemplary embodiment of the disclosure, the first sensing electrode pattern of each of the above sensing electrode sets has a strip pattern that extends along a first direction, and the second electrode patterns of each sensing electrode set are arranged along the first direction. For example, the second sensing electrode patterns in two neighboring sensing electrode sets connected to the same series are located at different positions along the first direction.
According to an exemplary embodiment of the disclosure, the first conductive lines and the second conductive lines do not intersect with each other, the second conductive lines do not intersect with each other, and the first conductive lines do not intersect with each other.
According to an exemplary embodiment of the disclosure, the above resistors are disposed on the substrate, and each resistor is disposed between two different second pads connected to two terminals of a same series.
According to an exemplary embodiment of the disclosure, the above neighboring two first sensing electrode patterns are disposed with a plurality of second sensing electrode patterns therebetween.
According to an exemplary embodiment of the disclosure, the above sensing electrode sets are fabricated from a same film layer.
According to an exemplary embodiment of the disclosure, the first conductive lines and the second conductive lines are fabricated from a same film layer.
According to the touch panel of the exemplary embodiments of the disclosure, each sensing electrode set includes at strip-shaped first sensing electrode pattern and a plurality of second sensing electrode patterns configured adjacent to the first sensing electrode pattern. The second sensing electrode patterns of the different sensing electrode sets are serially connected to form a series via the second conductive lines. The two ends of each series are respectively connected to different second pads, and the plurality of second sensing electrodes is driven through the same second pads. Moreover, the two ends of each series are further connected to the two ends of a resistor for adjusting the resistances of the different series to enhance the quality of a touch panel.
The invention and certain merits provided by the invention can be better understood by way of the following exemplary embodiments and the accompanying drawings, which are not to be construed as limiting the scope of the invention.
More specifically, the first sensing electrode pattern 122 of each sensing electrode set 120 has a strip pattern that extends along a first direction D1 and the second sensing electrode patterns 124 of each sensing electrode set 120 are arranged along the first direction D1. A plurality of second sensing electrode patterns 124 are disposed at the side of each of the first sensing electrode patterns 122, and the strip shaped first sensing electrode patterns 122 and the second sensing electrode patterns 124 are alternately arranged along the second direction D2, wherein the first direction D1 can be intersected with or perpendicular to the second direction D2. The second sensing electrode patterns 124 are disposed between any two neighboring first sensing electrode patterns 122 .
In the touch panel 100, these first sensing electrode patterns 122 are sequentially scanned for the second sensing electrode patterns 124 that belong to the same sensing electrode set 120 to concurrently read the touch signal (i.e. performing the sensing operation). The plurality of second sensing electrode patterns 124 of the same sensing electrode set 120 must be electrically independent to accurately determine the touch position along the first direction D1 to achieve the touch sensing function. In other words, the chip that drives the touch panel 100 must be able to independently control the plurality of the second sensing electrode patterns 124 belonging to the same sensing electrode set 120. In the existing designs, the second sensing electrode patterns 124 are respectively connect to the chip through one second pad 140. Hence, the number of the second pads is at least equal to the number of the second sensing electrode patterns 124. However, this type of design would require the touch panel 100 to have a larger pad area. Moreover, the connection of the pads and the chip becomes more difficult due to an increasing number of the pads. Hence, in this exemplary embodiment, the second sensing electrode patterns 124 belonging to different sensing electrode sets 120 are connected as a same series S by the second conductive lines 160 to reduce the number of the second pads 140 and the area for disposing the pads. For example, the touch panel 100 in
More specifically, these sensing electrode sets 120, from left to right along the second direction D2, are respectively depicted as the first to the third sensing electrode sets 120, and the second sensing electrode patterns 124 of each set of the sensing electrode sets 120, from top the bottom along the first direction D1, are depicted as the first to the fourth ones of the second sensing electrode patterns 124. In this exemplary embodiment, the first one of the second sensing electrode patterns 124 in the first set of the sensing electrode sets 120, the fourth one of the second sensing electrode patterns 124 in the second set of the sensing electrode sets 120, the first one of the second sensing electrode patterns 124 in the third set of the sensing electrode sets 120 are serially connected as one series S via the second conductive lines 160. The second one of the second sensing electrode patterns 124 in the first set of the sensing electrode sets 120, the third one of the second sensing electrode patterns 124 in the second set of the sensing electrode sets 120, the second one of the second sensing electrode patterns 124 in the third set of the sensing electrode sets 120 are serially connected as another series S via the second conductive lines 160. The third one of the second sensing electrode patterns 124 in the first set of the sensing electrode sets 120, the second one of the second sensing electrode patterns 124 in the second set of the sensing electrode sets 120, the third one of the second sensing electrode patterns 124 in the third set of the sensing electrode sets 120 are serially connected as another series S via the second conductive lines 160. Moreover, the fourth one of the second sensing electrode patterns 124 in the first set of the sensing electrode sets 120, the first one of the second sensing electrode patterns 124 in the second set of the sensing electrode sets 120, the fourth one of the second sensing electrode patterns 124 in the third set of the sensing electrode sets 120 are serially connected as another series S via the second conductive lines 160. It is understood by a person of ordinary skill practicing the exemplary embodiment of the disclosure that the foregoing description of the ways of serially connecting the second sensing electrode patterns 124 should be regarded as illustrative rather than restrictive. Many modifications and variations, and different combinations thereof, can be implemented in accordance with the present invention. It should also be noted that different ways of the serial connection will lead to different layouts of the second conductive lines.
It should also be noted that the second sensing electrode patterns 124 are serially connected to form the plurality of the series S via the second conductive lines 160 using different methods. Further, these second conductive lines 160 do not intersect with each other and can be fabricated with a same film layer. Hence, during the fabrication of a touch panel 100, the application of multiple masks to perform multiple patterning processes for completing the layout of the second conductive lines 160 can be precluded. Moreover, in this exemplary embodiment, the first conductive lines 150 and the second conductive lines 160 do not intersect with each other, and the first conductive lines 150 do not intersect with each other. Hence, the first conductive line 150 and the second conductive line 160 can be fabricated using the same film layer. Accordingly, the number of process steps required in fabricating isolation layers for the different conductive layers may be reduced to lower the fabrication cost and the processing time. Moreover, the sensing electrode sets 120 do not intersect with each other; hence, they can be fabricated using the same film layer.
Generally speaking, a touch panel 100 may use a same conductive film layer to form these touch sensing electrode sets 120, the first conductive lines 150 and the second conductive lines 160, and even the first pads and the second pads 140. Alternatively speaking, the touch panel 100 may use only one layer of conductive layer to fabricate the required touch sensing electrodes and conductive lines; hence the manufacturing cost and the processing time can be greatly reduced. The exemplary embodiments of the disclosure are not limited as such. In other exemplary embodiments, different conductive films may be used to form these sensing electrode sets 120, the first conductive lines 150 and the second conductive lines, and even the first pads 130 and the second pads 140. For example, the sensing electrode sets 120 may be fabricated using a transparent conductive layer, while the first conductive lines 150, the second conductive lines 160, the first pads 130 and the second pads 140 may be fabricated with another type of conductive material, rather than the transparent conductive material.
Further, in the touch panel 100, the plurality of series S that are serially connected with the second conductive lines 160 have different routing lengths; hence, the plurality of series S have different resistances. Accordingly, the signals that are transmitted to the chip and read by the different second sensing electrode patterns 124 vary in different degrees due to the non-uniformity of the resistance. Therefore, an erroneous determination may be made by the chip because the received signal is different from the actual sensing signal. Ultimately, the touch sensing accuracy is lower and the quality of the touch panel 100 becomes undesirable.
However, in the touch panel 100 of the exemplary embodiment of the disclosure, different series S are parallelly connected with one of the resistors 170, and the resistors 170 of the different series S can have different resistances. Alternatively speaking, the resistors 170 have at least two or more types of resistance. In other exemplary embodiment, the resistors 170 may have the same resistance because the smaller the resistance of the resistors 170 than the resistance of each series S is, the lesser the overall resistance variation between the different resistors 170 and the corresponding series S is. This type of parallelly-connected design aids the adjustment of the equivalent resistance of each series S; hence, the signal variation of the different second sensing electrode patterns 124 owing to the transmission resistance is more consistent and the touch sensing accuracy is enhanced. Moreover, based on the equation of parallel resistors in electronic study, the equivalent resistance of each series S is lowered after each series is parallelly connected to a resistor 170. In other words, the overall resistance of each series is reduced to lower the loading of the chip.
Herein, the ways that each series S and one of the resistor 170 being parallelly connected include, for example, the two terminals S1, S2 of each series S respectively connect to different second pads 142, 144, and the two terminals of each resistor 170 are respectively connected to different second pads 142, 144 that are respectively connected to the two terminals S1, S2 of each series. It should be noted that the exemplary embodiment of the disclosure is limited as such. Moreover, in this exemplary embodiment, the resistors 170 can be configured directly on the substrate 110, for example, a meandering shape conductive pattern configured on the substrate 110 or a conductive pattern with different line widths.
In addition, in this exemplary embodiment, the resistors 170 that are parallelly connected with the different series S may have different resistances. For example, the greater the resistance of the series S itself is, the smaller the resistance of the resistor 170 that is parallelly connected with the series S is. For example, when two series respectively have resistances of 10 ohms and 5 ohms, then the series S having 10 ohms and the resistor having 5 ohms can be parallelly connected, and the series S having 5 ohms and the resistor 170 having 10 ohms can be parallelly connected. Accordingly, if the resistor 170 and the corresponding series S are viewed as a same unit, the equivalent resistance of each unit can be substantially the same. The signal transmission signal of each series is thereby maintained, and the touch sensing accuracy is enhanced.
In other exemplary embodiments, the resistors 170 may be disposed indirectly on the substrate 110. For example,
According to the above, in the touch panel of the exemplary embodiment of the disclosure, all the conductive structures do not intersect with each other; hence, a reduction of the fabrication cost can be accomplished. Further, the touch panel of the exemplary embodiment of the disclosure applies multiple conductive lines to serially connect the sensing electrode patterns of the different sensing electrode sets for the sensing electrode patterns of the different sensing electrode sets to connect with the chip via the same pads. Moreover, the multiple sensing electrode patterns are connected into series and are parallelly connected to a resistor. Accordingly, variations in the equivalent resistance of different sensing electrodes are reduced and the resistance of the sensing signal transmission route is lowered. Further, the quality of signal transmission is enhanced to accomplish a desirable touch sensing effect.
It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the present invention cover modifications and variations of this invention provided they fall within the scope of the following claims and their equivalents.
Number | Date | Country | Kind |
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101124810 A | Jul 2012 | TW | national |
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20090267916 | Hotelling | Oct 2009 | A1 |
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Number | Date | Country | |
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20140014489 A1 | Jan 2014 | US |