Abstract: Disclosed herein is a digitizer including: a driving coil supplied with current to induce a magnetic line of force; a sensing coil disposed so as to intersect the driving coil to flow induced current in one direction by the magnetic line of force; and a control unit sensing variation of voltage induced to the sensing coil to calculate coordinates of the input unit when the voltage is changed due to an approach of an input unit.

Abstract: Disclosed herein is a touch panel including: a transparent substrate; conductive patterns formed on the transparent substrate such that wavy lines thereof are spaced apart from each other and arranged in parallel with each other, each of the wavy lines having a sine wave form where first peaks and second peaks alternately continue along a length direction thereof; and connecting patterns formed on the transparent substrate, each of the connecting patterns electrically connecting between the wave lines, so that good visibility can be achieved even though electrodes and wirings are disposed in an active area of the transparent substrate, by forming uniform pattern of electrodes and wirings on the transparent substrate.

Abstract: Disclosed herein is a digitizer including: an input unit having a magnetic field shielding part embedded therein; a driving coil supplied with current to induce a magnetic line of force; a sensing coil to which voltage is induced by the magnetic line of force; and a control unit supplying current to the driving coil and measuring voltage induced to the sensing coil, wherein the control unit senses variation of voltage induced to the sensing coil to calculate coordinates of the input unit when the voltage induced to the sensing coil is changed by the magnetic field shielding part.

Abstract: Disclosed herein are a sensor for a digitizer and a method for manufacturing the same. The sensor for a digitizer includes a magnetic layer having insulation property, a first coil formed on one surface of the magnetic layer, an insulating layer formed on one surface of the magnetic layer while covering the first coil, and a second coil formed on one surface of the insulating layer. By this configuration, the coil is directly formed on the magnetic layer to simplify a structure and improve stability of a signal transmitted and received from and to a coil by the magnetic layer.

Abstract: Disclosed herein are a sensor for a digitizer and a method of manufacturing the same. The sensor includes a magnetic layer having insulation; a first coil embedded in the magnetic layer; a second coil formed on one surface of the magnetic layer; and an insulating layer formed on one surface of the magnetic layer to cover the second coil. Thus, since the first coil and the second coil are formed on the magnetic layer formed of a magnetic material, a magnetic field is stably formed between coils and stability of signals transmitted and received between a coil and an input device is increased.

Abstract: Disclosed herein is a sensor for a digitizer including a first magnetic layer, a first coil formed on one surface of the first magnetic layer, an insulating layer formed on one surface of the first magnetic layer, a second coil formed on one surface the insulating layer, and a second magnetic layer formed on one surface of the insulating layer, and a method for manufacturing the same.

Abstract: Disclosed herein is a display device having a capacitive touch screen, including: a display unit; and a capacitive touch screen that is coupled to the display unit by an adhesive layer and includes a base substrate, a plurality of first electrode patterns that are formed on an active region of the base substrate, ground patterns that are formed on the active region of the base substrate and are separated from the first electrode pattern, a transparent insulating layer that covers the first electrode patterns and the ground patterns and is formed on the base substrate, and a plurality of second electrode patterns that are formed on an active region of the transparent insulating layer.

Abstract: Disclosed herein is a back light unit integrated digitizer. The back light unit integrated digitizer includes a cover disposed on one surface of the back light unit to protect the back light unit; and a loop coil formed on the cover, wherein the loop coil is directly formed on the cover of the back light unit to integrally form the digitizer in the back light unit, thereby reducing the overall thickness to implement slimness and saving manufacturing costs to secure price competitiveness.

Abstract: Disclosed herein is a capacitive type touch panel, including: a transparent substrate; and a transparent electrode formed on the transparent substrate, wherein the transparent electrode has first, second, and third patterns sequentially formed in either a short direction or a long direction of the transparent substrate. According to the present invention, the one-layer capacitive type touch panel according to the present invention can easily recognize the coordinates of touched points by the touch and accurately recognize the coordinates. Furthermore, the transparent electrode patterns according to the present invention allow realization of multi-touch and improvement in driving reliability.

Abstract: Disclosed herein is a touch screen 100 designed to control an image displayed on image display units 140 and 150 on both-sides of the touch screen. The touch screen 100 according to the present invention may overcome an obscured screen problem caused by an input device, increase production yield while reducing a process time of the touch screen 100 by simultaneously forming transparent electrodes and electrode wires on a transparent substrate and, after forming an image display unit and an active region on the transparent substrate, folding the transparent substrate, and minimize an area of a bezel region.

Abstract: Disclosed herein is a method of manufacturing a capacitive touch screen, including: forming transparent electrodes on an upper surface of a lower transparent film; forming electrode wirings on a lower surface of an upper transparent film; and bonding the transparent electrodes to the electrodes wirings to be closely adhered to each other, whereby it prevents the transparent electrodes from being damaged or deformed due to heat, thereby making it possible to improve reliability and accuracy of the manufacturing process.

Abstract: Disclosed herein is a method of controlling driving of a touch panel. Input means inputs a first touch to a touch surface, and whether the first touch is a line touch is determined. If the first touch is a line touch, the touch surface is divided into first and second selection regions, based on the line touch. The input means inputs a second touch to the touch surface, and one of the first and second selection regions is selected. When the first selection region is selected by the second touch, if the input means inputs a third touch to the second selection region, a specific algorithm is executed in the second selection region, whereas when the second selection region is selected by the second touch, if the input means inputs the third touch to the first selection region, the specific algorithm is executed in the first selection region.

Abstract: Disclosed herein is a touch screen, including: a first transparent electrode formed on a first transparent substrate; a second transparent electrode formed on a second transparent substrate opposite to the first transparent substrate and being in contact with the first transparent electrode when a touched input is generated to sense a change in resistance or voltage; an adhesive layer bonding an outer side of the first transparent substrate to an outer side of the second transparent substrate and having an opening formed therein; and a plurality of dot spacers movably formed in the opening, whereby, it is possible to accurately measure the positions of the touched input due to the movement of the dot spacers by the touched input.

Abstract: Disclosed herein are a one-layer capacitive touch screen and a method of manufacturing the same. The one-layer capacitive touch screen includes: a base substrate; a first electrode pattern that is formed on an upper surface of the base substrate and includes a plurality of first sensing units and first connection units connecting the adjacent first sensing units; a second electrode pattern that is formed on the upper surface of the base substrate and includes a plurality of second sensing units and second connection units connecting the adjacent second sensing units, the second connection units being formed to intersect with each other on the upper side of the first connection unit, having an air gap therebetween; and an electrode wiring that is connected to the first electrode pattern and the second electrode.

Abstract: Disclosed herein is a touch screen. The touch screen includes a transparent electrode that is formed on one surface of a first transparent substrate to sense change in capacitance at the time of a touch input; an electrode that is formed on a second transparent substrate formed on the other surface of the first transparent substrate to apply voltage to the transparent electrode; and a via that penetrates through the first transparent substrate to electrically connect the transparent electrode to the electrode. The transparent electrode and the electrode are formed on the transparent substrates at different layers, thereby reducing an inactive region.

Abstract: Disclosed herein is a touch screen having an antenna, including: a first substrate that includes a first electrode pattern formed in an active region and a first electrode wiring formed in an inactive region disposed outside the active region and connected to the first electrode pattern; a second substrate that includes a second electrode pattern opposite to the first electrode pattern and a second electrode wiring connected to the second electrode pattern; a spacer that is formed between the first substrate and the second substrate to space the first electrode pattern from the second electrode pattern; and an antenna pattern that is formed in the inactive region.

Abstract: Disclosed herein is a display device having a capacitive touch screen, including: a display unit; and a capacitive touch screen that is coupled to the display unit by an adhesive layer and includes a base substrate, a plurality of first electrode patterns that are formed on an active region of the base substrate, ground patterns that are formed on the active region of the base substrate and are separated from the first electrode pattern, a transparent insulating layer that covers the first electrode patterns and the ground patterns and is formed on the base substrate, and a plurality of second electrode patterns that are formed on an active region of the transparent insulating layer.

Abstract: Disclosed herein is a method for manufacturing a one-layer type capacitive touch screen. The method for manufacturing a one-layer type capacitive touch screen includes: forming a plurality of electrode wirings made of metal in an inactive region of a base substrate; forming a plurality of first electrode patterns made of a conductive polymer and including a first sensing unit and a first connection unit in an active region of the base substrate to connect the electrode wirings; forming an insulating pattern on the plurality of first connection units of the first electrode patterns; and forming a plurality of second electrode patterns including a second sensing unit and a second connection unit and made of the conductive polymer in the active region of the base substrate to connect the electrode wirings and position the second connection unit on the insulating pattern.

Abstract: Disclosed herein is a method for recognizing a resistive touch screen. The method for recognizing the resistive touch screen includes: sensing touch generated at the resistive touch screen; calculating a difference value, a searching value by detecting voltage at two electrode wirings connected with a transparent resistive layer of the resistive touch screen; and comparing the searching value with a reference value that is a difference value between voltages detected at the two electrode wirings when the resistive touch screen is single-touched, whereby the single touch and the multi-touch can be differentiated. Further, the embodiment sets the error range in the single touch and the error range in the multi-touch and compares these error ranges, thereby making it possible to more accurately differentiate the multi-touch and the single touch and provides various input information, thereby making it possible to provide various user interfaces.

Abstract: Disclosed is a touch panel, which includes a transparent conductive film, electrodes printed at both ends of the transparent conductive film, and a substrate having a wiring connected to the electrodes and formed in a multilayer therein, and surrounding the transparent conductive film at the inner peripheral surface thereof, so that the use of the substrate having the wiring in multilayer form enables a plurality of wirings necessary for multi touch to be formed even under conditions of a thin bezel size, thus satisfying the trend which is reducing the size of electronic products.