Abstract: The invention provides a method for producing radiolabeled tyrosine derivatives with good purity and stability, by a safe method suitable for industrial production of pharmaceuticals. The invention relates to a method for producing Compound (5) and Radiolabeled Compound (6) as follows: wherein each symbol is as defined in the description.

Abstract: A position detecting method for a touchscreen panel includes the steps of (a) determining the presence or absence of contact with the touchscreen panel on a conductive film divided into multiple conductive regions; (b) measuring a time after the detection of the absence of the contact and determining whether the measured time is less than a predetermined time if step (a) determines the absence of the contact; and (c) determining the continuance of the contact if the measured time is less than the predetermined time.

Abstract: In a coordinate detection apparatus, a resistance-film is formed on a substrate made of an insulating material. A common electrode applies a voltage to the resistance-film, the common electrode extending along a plurality of a resistance-film removal areas formed by removing portions of the resistance-film. A voltage application part applies the voltage to the common electrode. The voltage is applied from the voltage application part to the resistance-film through the common electrode to generate a potential distribution in the resistance-film. A coordinate position of a contact position at which the resistance-film is contacted is detected by detecting a potential of the resistance-film at the contact position.

Abstract: A position detecting method for a touchscreen panel includes the steps of (a) determining the presence or absence of contact with the touchscreen panel on a conductive film divided into multiple conductive regions; (b) measuring a time after the detection of the absence of the contact and determining whether the measured time is less than a predetermined time if step (a) determines the absence of the contact; and (c) determining the continuance of the contact if the measured time is less than the predetermined time.

Abstract: In a coordinate detection apparatus, a resistance-film is formed on a substrate made of an insulating material. A common electrode applies a voltage to the resistance-film, the common electrode extending along a plurality of a resistance-film removal areas formed by removing portions of the resistance-film. A voltage application part applies the voltage to the common electrode. The voltage is applied from the voltage application part to the resistance-film through the common electrode to generate a potential distribution in the resistance-film. A coordinate position of a contact position at which the resistance-film is contacted is detected by detecting a potential of the resistance-film at the contact position.

Abstract: A position detecting method for a touchscreen panel includes the steps of (a) determining the presence or absence of contact with the touchscreen panel on a conductive film divided into multiple conductive regions; (b) measuring a time after the detection of the absence of the contact and determining whether the measured time is less than a predetermined time if step (a) determines the absence of the contact; and (c) determining the continuance of the contact if the measured time is less than the predetermined time.

Abstract: In a coordinate detection apparatus, a resistance-film is formed on a substrate made of an insulating material. A common electrode applies a voltage to the resistance-film, the common electrode extending along a plurality of a resistance-film removal areas formed by removing portions of the resistance-film. A voltage application part applies the voltage to the common electrode. The voltage is applied from the voltage application part to the resistance-film through the common electrode to generate a potential distribution in the resistance-film. A coordinate position of a contact position at which the resistance-film is contacted is detected by detecting a potential of the resistance-film at the contact position.

Abstract: A touch panel includes a first electrode substrate including a first substrate and a first conductive film formed on the first substrate, and a second electrode substrate including a second substrate and a second conductive film formed on the second substrate to face the first conductive film. A part or the entirety of the first conductive film is divided into plural conductive areas.

Abstract: Disclosed is a touch panel including a first electrode substrate including a first conductive layer; and a second electrode substrate including a second conductive layer and being stacked with the first electrode substrate such that the first conductive layer and the second conductive layer face each other. The first conductive layer is composed of a first line of conductive areas and a second line of conductive areas adjacent to the first line where each of the first and the second lines includes an odd number greater than or equal to three of the conductive areas aligned in a second direction, and the conductive areas positioned in the middle of the first line and the second line are respectively connected with extracting areas extending toward different edges in the second direction.

Abstract: A coordinate detecting device includes a resistive film formed on a substrate and a common electrode for applying a voltage to the resistive film, wherein a potential distribution is created in the resistive film, an electric potential of the resistive film at a contact position is detected, and a position of the contact position of the resistive film is detected. In a manufacturing apparatus, a laser light source irradiates laser light to remove a part of the resistive film to form a resistive film removed part, an optical system converges the laser light, a plurality of probes measure electric potentials of a surface of the resistive film with the common electrode providing the voltage to the resistive film, an X-Y table moves the substrate at least two-dimensionally, and a control part controls the X-Y table and the laser light source.

Abstract: A touchscreen panel includes an upper substrate having a first transparent conductor layer provided on a first base layer, and a lower substrate having a second transparent conductor layer provided on a second base layer. The first and second transparent conductor layers oppose each other via a spacer and make contact when the first base layer is pressed. The first transparent conductor layer is segmented into a plurality of conductive regions that are electrically insulated from each other.

Abstract: A touchscreen panel includes an upper substrate having a first transparent conductor layer provided on a first base layer, and a lower substrate having a second transparent conductor layer provided on a second base layer. The first and second transparent conductor layers oppose each other via a spacer and make contact when the first base layer is pressed. The first transparent conductor layer is segmented into a plurality of conductive regions that are electrically insulated from each other.

Abstract: A touchscreen panel includes an upper substrate having a first transparent conductor layer provided on a first base layer, and a lower substrate having a second transparent conductor layer provided on a second base layer. The first and second transparent conductor layers oppose each other via a spacer and make contact when the first base layer is pressed. The first transparent conductor layer is segmented into a plurality of conductive regions that are electrically insulated from each other.

Abstract: A coordinate detecting device includes a resistive film formed over a substrate; and a common electrode formed over the resistive film for applying a voltage to the resistive film. The coordinate detecting device generates potential distribution in the resistive film by applying the voltage to the resistive film from the common electrode and detects a coordinate of a contact position of the resistive film by detecting a potential of the contact position of the resistive film. The substrate is formed of an insulator in a square shape. The common electrode is formed along an edge part of the substrate. The resistive film under the common electrode has one or more areas where the resistive film does not exist. An L-shaped resistive film absent area where the resistive film does not exist is provided in one or more corners of the substrate and on the same side of the common electrode as a side where a center of the substrate is situated.

Abstract: A method of manufacturing a coordinate detector having a resistive film and a common electrode for applying a voltage to the resistive film is disclosed that includes the steps of (a) applying a photoresist onto the resistive film formed on a substrate formed of an insulator; (b) forming a resist pattern on the resistive film by exposing the applied photoresist to light through a predetermined mask and subsequently developing the applied photoresist; (c) forming a resistive film removal region by removing a portion of the resistive film without the resist pattern; (d) removing the resist pattern after step (c); and (e) forming the common electrode over the resistive film removal region after step (d).

Abstract: A touch panel includes a first electrode substrate including a first substrate and a first conductive film formed on the first substrate, and a second electrode substrate including a second substrate and a second conductive film formed on the second substrate to face the first conductive film. A part or the entirety of the first conductive film is divided into plural conductive areas.

Abstract: A touch panel that is used by being superposed on a display panel, the touch panel including: a first electrode substrate including a first substrate and a first conductive film that is formed on the first substrate, the first conductive film including plural conductive areas that are divided into three or more areas along a longitudinal direction and divided into three or more areas along a lateral direction; and a second electrode substrate including a second substrate and a second conductive film that is formed on the second substrate, the second conductive film being opposed to the first conductive film, wherein each of boundary lines of the plural conductive areas forms a predetermined angle with respect to an alignment direction of pixels of the display panel.

Abstract: A manufacturing method of a coordinate position detecting device includes the steps of forming the common electrode on the resistive film of tour sides of the substrate having a rectangular-shaped configuration; measuring the electric potential of the resistive film by plural probes contacting a surface of the resistive film where the electric potential is supplied from the common electrode to the resistive film; calculating a resistive film removing area, based on a value of a measured electric potential, by a calculating part so that the electric potential distribution of the resistive film is made uniform; and removing the resistive film in the resistive film removing area calculated by the calculating part, by a laser light.

Abstract: Disclosed is a touch panel including a first electrode substrate including a first conductive layer; and a second electrode substrate including a second conductive layer and being stacked with the first electrode substrate such that the first conductive layer and the second conductive layer face each other. The first conductive layer is composed of a first line of conductive areas and a second line of conductive areas adjacent to the first line where each of the first and the second lines includes an odd number greater than or equal to three of the conductive areas aligned in a second direction, and the conductive areas positioned in the middle of the first line and the second line are respectively connected with extracting areas extending toward different edges in the second direction.

Abstract: A method of manufacturing a coordinate detector having a resistive film and a common electrode for applying a voltage to the resistive film is disclosed that includes the steps of (a) applying a photoresist onto the resistive film formed on a substrate formed of an insulator; (b) forming a resist pattern on the resistive film by exposing the applied photoresist to light through a predetermined mask and subsequently developing the applied photoresist; (c) forming a resistive film removal region by removing a portion of the resistive film without the resist pattern; (d) removing the resist pattern after step (c); and (e) forming the common electrode over the resistive film removal region after step (d).